US20090149723A1 - Automated interpretive medical care system and methodology - Google Patents

Abstract

Improved apparatus and methods for monitoring, diagnosing and treating at least one medical respiratory condition of a patient are provided, including a medical data input interface adapted to provide at least one medical parameter relating at least to the respiration of the patient, and a medical parameter interpretation functionality (104, 110) adapted to receive the at least one medical parameter relating at least to the respiration (102) of the patient and to provide at least one output indication (112) relating to a degree of severity of at least one medical condition indicated by the at least one medical parameter.

Description

REFERENCE TO CO-PENDING APPLICATIONS
• This application is a Continuation Application of U.S. patent application Ser. No. 10/433,760 filed on Jun. 10, 2004 which is a US National phase of PCT Application No. PCT/IL01/01127, filed Dec. 6, 2001 which claims priority of U.S. Provisional Application Ser. No. 60/251,828 filed Dec. 7, 2000 and U.S. Provisional Application Ser. No. 60/251,829 filed Dec. 7, 2000, all of which are hereby incorporated in their entirety by reference.
FIELD OF THE INVENTION
• The present invention relates to the use of respiratory information in automated medical status assessment.
BACKGROUND OF THE INVENTION
• The following U.S. patent and publication are believed to represent the current state of the art: U.S. Pat. No. 4,440,177 to Anderson et al, describes a respiratory analyzer system. Reference is also made to NIH publication on. 97-4051 entitled “Guidelines for the Diagnosis and Management of Asthma” pp 108-109, 1991.
• The disclosures of all references mentioned above and throughout the present specification are hereby incorporated herein by reference.
SUMMARY OF THE INVENTION
• The present invention seeks to provide improved methods and apparatus for monitoring, diagnosing and treating at least one medical respiratory condition.
• There is thus provided in accordance with a preferred embodiment of the present invention, a system employing at least one parameter relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a medical data input interface adapted to provide the at least one medical parameter relating at least to respiration of the patient, and
• a medical parameter interpretation functionality receiving the at least one medical parameter relating at least to respiration of the patient and providing the at least one output indication relating to a degree of severity of at least one medical condition indicated by the at least one medical parameter.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a system employing at least one parameter relating at least to respiration of a patient for providing at least one indication relating to at least one medical condition, the system including:
• a mobile platform, and
• a medical care facility suitable for use by an operator other than a medical doctor, the medical care facility including:
• a medical data input interface providing the at least one medical parameter regarding a patient, and
• a medical parameter interpretation functionality receiving the at least one medical parameter regarding the patient and providing the at least one output indication relating to a degree of severity of the at least one medical condition indicated by the at least one medical parameter.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a system employing at least one parameter relating at least to respiration of a patient for providing at least one indication relating to at least one medical condition, the system including:
• a medical data input interface providing the at least one medical parameter regarding a patient,
• a medical parameter interpretation functionality receiving the at least one medical parameter regarding the patient and providing the at least one output indication, and
• a treatment control functionality for controlling the provision of at least one treatment to a patient in response to the at least one output indication.
• There is thus further provided in accordance with yet another preferred embodiment of the present invention, a system employing at least one parameter relating at least to respiration of a patient for providing at least one indication relating to at least one medical condition, the system including:
• a mobile platform, and
• a medical care facility suitable for use by an operator other than a medical doctor, the medical care facility including:
• a medical data input interface providing the at least one medical parameter regarding a patient,
• a medical parameter interpretation functionality receiving the at least one medical parameter regarding the patient and providing the at least one output indication, and a treatment control functionality for controlling the provision of at least one treatment to a patient in response to the at least one output indication.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a system employing at least two parameters relating at least to respiration of a patient for providing at least one indication relating to at least one medical condition, the system including:
• a medical data input interface providing at least two medical parameters regarding a patient, and
• a medical parameter interpretation functionality receiving the at least two medical parameters regarding the patient and providing the at least one output indication relating to at least one medical condition indicated by the at least two medical parameters.
• There is thus yet further provided in accordance with another preferred embodiment of the present invention, a system employing at least two parameters relating at least to respiration of a patient for providing at least one indication relating to at least one medical condition, the system including:
• a mobile platform, and
• a medical care facility suitable for use by an operator other than a medical doctor the medical care facility including:
• a medical data input interface providing at least two medical parameters regarding a patient, and
• a medical parameter interpretation functionality receiving the at least two medical parameters regarding the patient and providing the at least one output indication relating to at least one medical condition indicated by the at least two medical parameters.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a system employing a plurality of parameters relating at least to respiration of a patient for providing a plurality of indications relating to at least one medical condition, the system including:
• a medical data input interface providing the plurality of medical parameters regarding a patient,
• a medical parameter interpretation functionality receiving the plurality of medical parameters regarding the patient and providing the plurality of output indications, and
• a medical treatment control functionality for controlling the provision of at least one treatment to a patient in response to changes in the relationship between the output indications.
• There is thus further provided in accordance with yet another preferred embodiment of the present invention, a system employing a plurality of parameters relating at least to respiration of a patient for providing a plurality of indications relating to at least one medical condition, the system including:
• a mobile platform, and
• a medical care facility suitable for use by an operator other than a medical doctor, the medical care facility including:
• a medical data input interface providing a plurality of medical parameters regarding a patient,
• a medical parameter interpretation functionality receiving the plurality of medical parameters regarding the patient and providing the plurality of output indications, and
• a medical treatment control functionality for controlling the provision of at least one treatment to a patient in response to changes in the relationship between the output indications.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a system employing a plurality of parameters relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a medical data input interface providing the plurality of medical parameters regarding a patient, and
• a medical parameter response functionality receiving the plurality of medical parameters regarding the patient and providing an output indication based on the relationship between the medical parameters.
• There is thus yet further provided in accordance with another preferred embodiment of the present invention, a system employing a plurality of parameters relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a mobile platform, and
• a medical care facility suitable for use by an operator other than a medical doctor, the medical care facility including:
• a medical data input interface providing the plurality of medical parameters regarding a patient, and
• a medical parameter response functionality receiving the plurality of medical parameters regarding the patient and providing an output indication based on the relationship between the medical parameters.
• There is thus additionally provided in accordance with another preferred embodiment of the present invention, a system employing a plurality of parameters relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a medical data input interface providing the plurality of medical parameters regarding a patient, and
• a medical treatment control functionality receiving the plurality of medical parameters regarding the patient and controlling at least one treatment based on a relationship between the medical parameters.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a system employing a plurality of parameters relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a mobile platform, and
• a medical care facility suitable for use by an operator other than a medical doctor, the medical care facility including:
• a medical data input interface providing the plurality of medical parameters regarding a patient, and
• a medical treatment control functionality receiving the plurality of medical parameters regarding the patient and controlling at least one treatment based on a relationship between the medical parameters.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a system employing a plurality of parameters relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a medical data input interface providing the plurality of medical parameters regarding a patient, and
• a medical parameter response functionality receiving the plurality of medical parameters regarding the patient and providing an output indication relating to a degree of severity of at least one medical condition indicated by the plurality of medical parameters.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a system employing a plurality of parameters relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a mobile platform, and
• a medical care facility suitable for use by an operator other than a medical doctor, the medical care facility including:
• a medical data input interface providing the plurality of medical parameters regarding a patient, and
• a medical parameter response functionality receiving the plurality of medical parameters regarding the patient and providing an output indication relating to a degree of severity of at least one medical condition indicated by the plurality of medical parameters.
• There is thus further provided in accordance with another preferred embodiment of the present invention, an emergency medical transport facility including:
• a mobile platform, and
• a medical care system suitable for use by an operator other than a medical doctor, the medical care system including:
• a medical data input interface providing at least one medical parameter regarding a patient, and
• a medical parameter interpretation functionality receiving the at least one medical parameter regarding the patient and providing an output indication relating to a degree of severity of at least one medical condition indicated by the at least one medical parameter.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a system employing at least one parameter relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a medical data input interface adapted to provide the at least one medical parameter relating at least to respiration of the patient, and
• a medical parameter interpretation functionality receiving the at least one medical parameter regarding the patient, and wherein the at least one medical parameter interpretation functionality includes:
• a medical condition diagnosis functionality for diagnosing the presence of the at least one medical condition, and
• a medical condition severity functionality indicating the degree of severity of the at least one medical condition.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a system employing at least one parameter relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a mobile platform, and
• a medical care facility suitable for use by an operator other than a medical doctor, the medical care facility including:
• a medical data input interface providing the at least one medical parameter regarding a patient, and
• a medical parameter interpretation functionality receiving the at least one medical parameter regarding the patient and wherein the at least one medical parameter interpretation functionality includes:
• a medical condition diagnosis functionality for diagnosing the presence of the at least one medical condition, and
• a medical condition severity functionality indicating the degree of severity of the at least one medical condition.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a system employing at least one parameter relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a medical data input interface adapted to provide the at least one medical parameter relating at least to respiration of the patient, and
• a medical parameter interpretation functionality receiving the at least one medical parameter regarding the patient, and wherein the at least one medical parameter interpretation functionality includes:
• a medical condition diagnosis functionality for diagnosing the presence of the at least one medical condition, and
• a medical condition severity functionality indicating the degree of severity of the at least one medical condition,
• and,
• a treatment control functionality for controlling the provision of at least one treatment to the patient in response to the degree of severity.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a system employing at least one parameter relating at least to respiration of a patient for providing an indication relating to at least one medical condition, the system including:
• a mobile platform, and
• a medical care facility suitable for use by an operator other than a medical doctor, the medical care facility including:
• a medical data input interface providing the at least one medical parameter regarding a patient, and
• a medical parameter interpretation functionality receiving the at least one medical parameter regarding the patient and wherein the at least one medical parameter interpretation functionality includes:
• a medical condition diagnosis functionality for diagnosing the presence of the at least one medical condition, and
• a medical condition severity functionality indicating the degree of severity of the at least one medical condition,
• and,
• a treatment control functionality for controlling the provision of at least one treatment to the patient in response to the degree of severity.
• There is thus also provided in accordance with another preferred embodiment of the present invention, an emergency medical transport methodology including:
• transporting a patient on a mobile platform,
• interfacing the patient with a medical data interface which provides at least one medical parameter of the patient, and
• inputting the medical parameter to a medical parameter interpretation functionality, which interprets the at least one medical parameter and provides an output indication relating to a degree of severity of the at least one medical condition.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a method of determining the degree of severity of at least one medical condition of a patient, the condition being associated with at least one medical parameter, including the steps of:
• interfacing the patient with a medical data interface which provides at least one medical parameter of the patient, and
• inputting the medical parameter to a medical parameter interpretation functionality, which interprets the at least one medical parameter and provides an output indication relating to a degree of severity of the at least one medical condition.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a method of controlling the provision of at least one treatment to a patient for at least one medical condition including the steps of:
• interfacing the patient with a medical data interface which provides at least one medical parameter of the patient,
• inputting the at least one medical parameter to a medical parameter interpretation functionality, which interprets the at least one medical parameter and provides an output indication, and
• controlling the provision of the at least one treatment in response to the output indication.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a method of providing an output indication relating to at least one medical condition indicated by at least two medical parameters, including the steps of:
• interfacing the patient with a medical data interface which provides at least two medical parameters of the patient,
• inputting the at least two medical parameters to a medical parameter interpretation functionality, which interprets the at least two medical parameters and provides an output indication of the at least one medical condition.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a method of controlling the provision of at least one treatment for at least one medical condition to a patient including the steps of:
• interfacing the patient with a medical data interface which provides a plurality of medical parameters of the patient,
• inputting the medical parameters to a medical parameter interpretation functionality, which interprets the medical parameters and provides a plurality of output indications, and
• controlling the provision of the at least one treatment in response to changes in the relationship between the output indications.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a method of providing an output indication regarding the clinical state for at least one medical condition of a patient, including the steps of:
• interfacing the patient with a medical data interface which provides a plurality of medical parameters regarding the patient, and
• inputting the plurality of medical parameters to a medical parameter interpretation functionality, which provides an output indication based on the relationship between the medical parameters.
• There is thus additionally provided in accordance with another preferred embodiment of the present invention, a method of controlling the provision of at least one treatment to a patient for at least one medical condition including the steps of;
• interfacing the patient with a medical data interface which provides a plurality of medical parameters of the patient,
• inputting the medical parameters to a medical parameter interpretation functionality,
• interpreting the medical parameters by the medical parameter interpretation functionality,
• providing a plurality of output indications by the medical parameter interpretation functionality, and
• inputting the output indications to a medical treatment control unit, which controls the at least one treatment in response to the relationship between the medical parameters.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a method of providing an output indication relating to a degree of severity of at least one medical condition of a patient including the steps of:
• interfacing the patient with a medical data interface which provides a plurality of medical parameters regarding the patient, and
• inputting the medical parameters to a medical parameter interpretation functionality,
• interpreting the medical parameters by the medical parameter interpretation functionality,
• providing a plurality of output indications by the medical parameter interpretation functionality, and
• inputting the output indications to a medical parameter response unit which provides a response relating to a degree of severity of the at least one medical condition indicated by the plurality of medical parameters.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a method of determining the degree of severity of at least one medical condition of a patient, the condition being associated with at least one medical parameter, including the steps of:
• interfacing the patient with a medical data interface which provides at least one medical parameter of the patient,
• inputting the medical parameter to a medical parameter interpretation functionality, which interprets the at least one medical parameter and provides an output indication relating to a degree of severity of the at least one medical condition, and
• medically treating the patient in accordance with the output indication.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a medical care methodology employing at least one parameter relating at least to respiration for providing an indication relating to at least one medical condition, the method including:
• (i) monitoring the at least one parameter relating at least to respiration of a patient over a period of time by means of at least one monitoring device so as to provide at least one monitoring output,
• (ii) processing the at least one monitoring output so as to provide at least one corresponding processing output by means of a processor,
• (iii) displaying a first indication of the patient on a display responsive to the at least one corresponding processing output,
• (iv) medically treating the patient in accordance with the indication,
• (v) repeating the monitoring step (i) and processing step (ii), subsequent to the treatment so as to provide a difference in the at least one monitoring parameter,
• (vi) processing the difference in the at least one at least one monitoring parameter so as to provide at least one corresponding processing output of the difference, and,
• (vii) displaying a second indication of the patient on a display responsive to the at least one corresponding processing output of the difference.
• There is thus yet further provided in accordance with another preferred embodiment of the present invention, a method of controlling the provision of at least one treatment to a patient for at least one medical condition including the steps of:
• interfacing the patient with a medical data interface which provides at least one medical parameter of the patient,
• inputting the at least one medical parameter to a medical parameter interpretation functionality, which interprets the at least one medical parameter and provides an output indication, and
• controlling the provision of the at least one treatment in response to the output indication.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a method of controlling the provision of at least one treatment for at least one medical condition to a patient including the steps of:
• interfacing the patient with a medical data interface which provides a plurality of medical parameters of the patient,
• inputting the medical parameters to a medical parameter interpretation functionality, which interprets the medical parameters and provides a plurality of output indications,
• controlling the provision of the at least one treatment in response to changes in the relationship between the output indications, and
• providing an update in a status of the patient responsive to the output indications.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a method of providing an output indication regarding the clinical state for at least one medical condition of a patient, including the steps of:
• interfacing the patient with a medical data interface which provides a plurality of medical parameters regarding the patient,
• inputting the plurality of medical parameters to a medical parameter interpretation functionality, which provides the output indication based on the relationship between the medical parameters, and
• providing a treatment recommendation by means of a treatment recommendation functionality.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a method of controlling the provision of at least one treatment to a patient for at least one medical condition including the steps of:
• interfacing the patient with a medical data interface which provides a plurality of medical parameters of the patient,
• inputting the medical parameters to a medical parameter interpretation functionality, which interprets the medical parameters and provides a plurality of output indications,
• inputting the output indications to a medical treatment control unit, which controls the at least one treatment in response to the relationship between the medical parameters, and
• providing an update in a status of the patient responsive to the relationship between the medical parameters.
• There is thus yet further provided in accordance with another preferred embodiment of the present invention, a method of providing an output indication relating to a degree of severity of at least one medical condition of a patient including the steps of:
• interfacing the patient with a medical data interface which provides a plurality of medical parameters regarding the patient, and
• inputting the medical parameters to a medical parameter interpretation functionality, which interprets the medical parameters and provides a plurality of output indications,
• inputting the output indications to a medical parameter response unit which provides a response relating to a degree of severity of the at least one medical condition indicated by the plurality of medical parameters, and
• controlling the provision of at least one treatment in response to the degree of severity.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a computer software product for determining the degree of severity of at least one medical condition of a patient, the condition being associated with at least one medical parameter, including a computer-readable medium in which program instructions are stored, which instructions, when read by a computer, cause the computer to:
• interface the patient with a medical data interface which provides at least one medical parameter of the patient, and
• input the medical parameter to a medical parameter interpretation functionality, which interprets the at least one medical parameter and provides an output indication relating to a degree of severity of the at least one medical condition.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a computer software product for controlling the provision of at least one treatment to a patient including a computer-readable medium in which program instructions are stored, which instructions, when read by a computer, cause the computer to:
• interface the patient with a medical data interface which provides at least one medical parameter of the patient,
• input the medical parameter to a medical parameter interpretation functionality, which interprets the at least one medical parameter and provides an output indication, and
• control the provision of the at least one treatment in response to the output indication.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a computer software product for providing an output indication relating to at least one medical condition of a patient indicated by at least two medical parameters, including a computer-readable medium in which program instructions are stored, which instructions, when read by a computer, cause the computer to:
• interface the patient with a medical data interface which provides at least two medical parameters of the patient,
• input the at least two medical parameters to a medical parameter interpretation functionality, which interprets the at least two medical parameters and provides an output indication of the at least one medical condition.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a computer software product for controlling the provision of at least one treatment to a patient, including a computer-readable medium in which program instructions are stored, which instructions, when read by a computer, cause the computer to:
• interface the patient with a medical data interface which provides a plurality of medical parameters of the patient,
• input the medical parameters to a medical parameter interpretation functionality, which interprets the medical parameters and provides a plurality of output indications, and
• control the provision of the at least one treatment in response to changes in the relationship between the output indications.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a computer software product for providing an output indication regarding the clinical state of a patient, including a computer-readable medium in which program instructions are stored, which instructions, when read by a computer, cause the computer to:
• interface the patient with a medical data interface which provides a plurality of medical parameters regarding the patient, and
• input the medical parameters to a medical parameter response unit, which providing the output indication based on the relationship between the medical parameters.
• There is thus further provided in accordance with another preferred embodiment of the present invention, a computer software product for controlling the provision of at least one treatment to a patient, including a computer-readable medium in which program instructions are stored, which instructions, when read by a computer, cause the computer to:
• interface the patient with a medical data interface which provides a plurality of medical parameters of the patient,
• input the medical parameters to a medical treatment control unit, which controls the at least one treatment in response to the relationship between the medical parameters.
• There is thus additionally provided in accordance with another preferred embodiment of the present invention, a computer software product for providing an output indication relating to a degree of severity of at least one medical condition of a patient including a computer-readable medium in which program instructions are stored, which instructions, when read by a computer, cause the computer to:
• interface the patient with a medical data interface which provides a plurality of medical parameters regarding the patient, and
• input the medical parameters to a medical parameter response unit which provides an output indication relating to a degree of severity of the at least one medical condition indicated by the plurality of medical parameters.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a computer software product for relating at least to respiration of a patient for providing an indication relating to at least one medical condition, including a computer-readable medium in which program instructions are stored, which instructions, when read by a computer, cause the computer to:
• provide the at least one medical parameter relating at least to respiration of the patient by means of a medical data input interface, and
• receive the at least one medical parameter regarding the patient by means of a medical parameter interpretation functionality, and,
• provide an output indication relating to a degree of severity of at least one medical condition indicated by the at least one medical parameter.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a computer software product for providing an indication relating to at least one medical condition, including a computer-readable medium in which program instructions are stored, which instructions, when read by a computer, cause the computer to:
• (i) monitor at least one parameter relating at least to respiration of a patient over a period of time by means of at least one monitoring device so as to provide at least one monitoring output,
• (ii) process the at least one monitoring output so as to provide at least one corresponding processing output by means of a processor,
• (iii) display a first indication of the patient on a display responsive to the at least one corresponding processing output,
• (iv) medical treating the patient in accordance with the indication,
• (v) repeat the monitoring step (i) and processing step (ii), subsequent to the treatment so as to provide a difference in the at least one monitoring parameter,
• (vi) process the difference in the at least one at least one monitoring parameter so as to provide at least one corresponding processing output of the difference, and,
• (vii) display a second indication of the patient on a display responsive to the at least one corresponding processing output of the difference.
• There is thus also provided in accordance with another preferred embodiment of the present invention, a computer software product for controlling the provision of at least one treatment to a patient for at least one medical condition including a computer-readable medium in which program instructions are stored, which instructions, when read by a computer, cause the computer to:
• interface the patient with a medical data interface which provides at least one medical parameter of the patient,
• input the at least one medical parameter to a medical parameter interpretation functionality, which interprets the at least one medical parameter and provides an output indication, and
• control the provision of the at least one treatment in response to the output indication.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the data input interface includes at least one monitoring device operative to continuously monitor the at least one medical parameter.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the data input interface includes at least one monitoring device operative to continuously monitor the at least two medical parameters.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the data input interface includes at least one monitoring device operative to continuously monitor the plurality of medical parameters.
• Preferably, the at least one monitoring device includes a capnograph.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least one monitoring device is operative to collect a sample of expired air from the patient.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least one monitoring device includes at least one of the following:
• an electrocardiogram (ECG) monitoring device,
• a blood pressure monitoring device,
• an electroencephalogram (EEG) monitoring device,
• an NI blood pressure monitoring device,
• a respiratory rate monitoring device,
• a heart rate monitoring device,
• a systemic perfusion monitoring device, and
• an exhaled air monitoring device.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least one monitoring device is operative to monitor at least one of:
• an expired air carbon dioxide concentration, and
• an expired air carbon dioxide profile parameter.
• Yet further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least one monitoring device is operative to monitor at least one of the following waveforms:
• a carbon dioxide waveform (capnogram),
• an EEG waveform, and
• an ECG waveform.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least one monitoring device is adapted to digitize at least one of the waveforms.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein at least one of:
• the at least one monitoring device, and
• the medical parameter interpretation functionality,
• is further operative to provide at least one of the following measurements:
• a slope of the increase in the carbon dioxide concentration,
• a run of time taken to reach 80% maximum exhaled CO₂concentration, and
• an angle of rise to 80% maximum exhaled CO₂concentration.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein at least one of:
• the at least one monitoring device, and
• the medical parameter interpretation functionality,
• is further operative to a value of CAP-FEV1.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is further operative to provide an alert responsive to a measure of CAP-FEV1 being less than 50% of an expected value.
• Moreover, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is further operative to provide an alert responsive to the run being greater than 0.3 seconds and the slope being less than 100 mm Hg/sec.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is further operative to provide an indication of at least one of:
• defective functioning of the monitoring device, and,
• defective placing of the monitoring device,
• responsive to a value of at least one of the measurements.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least one medical parameter includes at least one of:
• an expired air carbon dioxide concentration, and
• an expired air carbon dioxide profile parameter.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least one medical parameter includes at least one of:
• a visual parameter,
• a breathing parameter,
• an oxygen parameter,
• an ECG parameter,
• a heart function parameter,
• a neurological parameter,
• a blood pressure parameter, and
• an EEG parameter.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least two medical parameters include at least one of:
• a visual parameter,
• a breathing parameter,
• an oxygen parameter,
• an ECG parameter,
• a heart function parameter,
• a neurological parameter,
• a blood pressure parameter, and
• an EEG parameter.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the plurality of medical parameters includes at least one of:
• a visual parameter,
• a breathing parameter,
• an oxygen parameter,
• an ECG parameter,
• a heart function parameter,
• a neurological parameter,
• a blood pressure parameter, and
• an EEG parameter.
• Also, the visual parameter includes a visual appearance of the patient.
• Additionally, the breathing parameter includes at least one of:
• a respiratory rate of the patient,
• an FEV value, and
• an FVC value.
• Furthermore, the oxygen parameter includes at least one of:
• PO₂, and
• SPO₂
• Preferably, the ECG parameter includes at least one of:
• a QRS parameter, and
• an ST segment.
• Typically, the heart function parameter includes a heart rate parameter.
• Generally, the neurological function parameter includes a reflex parameter.
• Also, the blood pressure parameter includes at least one of:
• a blood pressure measurement, and
• a systolic:diastolic ratio.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is operative to provide an indication of the patient's status being within a normal range if at least one of the following requirements is fulfilled:
• a) the blood pressure values are within the normal range,
• b) the respiratory rate is normal,
• c) CO₂run is less than or equal to 0.3 sec,
• d) CO₂slope is more than or equal to 100 mm Hg/sec,
• e) SPO₂is greater or equal to than 95%, and
• f) ETCO₂is less than or equal to 45 mm Hg.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter response functionality is operative to provide an output indication responsive to a deviation from any one of the following requirements:
• a) the blood pressure values are within the normal range,
• b) the respiratory rate is normal,
• c) CO₂run is less than or equal to 0.3 sec,
• d) CO₂slope is more than or equal to 100 mm Hg/sec,
• e) SPO₂is greater or equal to than 95%, and
• f) ETCO₂is less than or equal to 45 mm Hg.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical treatment control functionality is operative to provide a treatment to the patient responsive to a deviation from any one of these requirements:
• a) the blood pressure values are within the normal range,
• b) the respiratory rate is normal,
• c) CO₂run is less than or equal to 0.3 sec,
• d) CO₂slope is more than or equal to 100 mm Hg/sec,
• e) SPO₂is greater or equal to than 95%, and
• f) ETCO₂is less than or equal to 45 mm Hg.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is operative to provide an indication of the patient's status being within a normal range if all of the following requirements are fulfilled:
• a) the blood pressure values are within the normal range,
• b) the respiratory rate is normal,
• c) CO₂run is less than or equal to 0.3 sec,
• d) CO₂slope is more than or equal to 100 mm Hg/sec,
• e) SPO₂is greater or equal to than 95%, and
• f) ETCO₂is less than or equal to 45 mm Hg.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality includes:
• a medical condition diagnosis functionality for diagnosing the presence of the at least one medical condition, and
• a medical condition severity indication functionality for indicating the degree of severity of the at least one medical condition.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is operative to provide an indication of the patient's status being outside the normal range if any of the requirements are not fulfilled.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical condition severity functionality is operative to provide an indication of the degree of severity of the at least one medical condition responsive to a degree of deviation of from at least one of the requirements.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical condition diagnosis functionality is operative to diagnose a respiratory disorder.
• Moreover, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical condition diagnosis functionality is further operative to provide a diagnosis of a respiratory disorder responsive to any of the requirements not being fulfilled.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical condition diagnosis functionality is further operative to provide a diagnosis of a severity of the respiratory disorder responsive to a quantitative measure of deviation of at least one parameter from at least one of the requirements.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the respiratory disorder includes at least one of:
• a restrictive lung disease,
• bronchospasm,
• asthma,
• bronchitis,
• emphysema,
• a respiratory failure,
• fibrosis, and
• an upper airway obstructive disease.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical condition diagnosis functionality is operative to provide a diagnosis of the restrictive lung disease responsive to at least one of the following cases:
• the run is greater or equal to 0.3 sec, or
• the slope is less than or equal to 100 mm Hg/sec.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical condition diagnosis functionality is operative to provide a diagnosis of the obstructive lung disease responsive to at least one of the following cases:
• the run is less than 0.3 sec, or
• the slope is more than 100 m Hg/sec.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical condition diagnosis functionality is further operative to provide a diagnosis of a heart disorder responsive to any of the requirements not being fulfilled.
• Yet further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical condition diagnosis functionality is further operative to provide a diagnosis of a heart failure if the following requirements are fulfilled:
• CAP-FEV1 is less than or equal to a 40:10 point ratio,
• a normal CAP-FEV1/FVC ratio,
• CO₂run is less than 0.3 sec, and
• CO₂slope is more than 100 mm Hg/sec.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical condition diagnosis functionality is further operative to provide a diagnosis of a severity of the heart disorder responsive to a quantitative measure of a deviation from any of the requirements.
• Moreover, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is operative to provide a recommendation to perform at least one of the following treatments responsive to the indication:
• intubation of the patient,
• hospitalization of the patient,
• treat the patient with medication, and
• transfer of the patient to an intensive care unit.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is operative to provide the at least one output indication responsive to a pattern of changes in the at least one medical parameter over time.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is further operative to provide an output indication responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Yet further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is operative to provide the plurality of output indications responsive to a pattern of changes in the plurality of medical parameters over time.
• Still further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the medical parameter interpretation functionality is further operative to provide the plurality of output indications responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system which also includes a treatment recommendation functionality.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment recommendation functionality is operative to recommend treatment responsive to the location of the patient.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment recommendation functionality is operative to recommend treatment responsive to a change in at least one of the following:
• a change in the run,
• a change in the ETCO₂,
• a change in the slope,
• a change in the angle of rise of CO₂, and
• a change in the SPO₂.
• Yet further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment recommendation functionality is responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Still further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment recommendation functionality is operative to provide an alert if at least one of the following requirements is fulfilled:
• a change in the run of more than 0.1 s,
• a change in the slope is more negative than −15 mm Hg/sec, and
• a change in the SPO₂is more negative than −5%.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment recommendation functionality is operative to provide a recommendation for at least one of the following treatments responsive to at least one of the requirements:
• intubation of the patient,
• hospitalization of the patient,
• treat the patient with intravenous medication, and
• transfer of the patient to an intensive care unit.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment recommendation functionality is operative to provide a recommendation to perform at least one of:
• continue monitoring, and
• continue treating the patient if at least one of the following conditions is fulfilled:
• a change in the run is less negative or equal to −0.1 s but less positive or equal to 0.1 s,
• a change in the slope is less negative or equal to −15 Hg/sec, but less positive or equal to +15 mm Hg/sec, and
• a change in the SPO₂is less negative or equal to −5%, but less positive or equal to +5%.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment recommendation functionality is operative to perform at least one of the following:
• provide a message indicative of an improvement in the patient's status, and
• recommend discontinuing a treatment procedure, if at least one of the following conditions is fulfilled:
• a change in the run is more negative than −0.1 s,
• a change in the slope is more positive than +15 mm Hg/sec, and
• a change in the SPO₂is more positive than 5%.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment recommendation functionality is operative to provide a recommendation to continue monitoring the patient responsive to the pattern of changes indicating at least one of:
• a deterioration in the status of the patient, and,
• a non-significant change in the status of the patient.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment recommendation functionality is operative to provide a recommendation to stop monitoring the patient responsive to a pattern of changes indicating an improvement in the status of the patient.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment recommendation functionality is additionally responsive to information regarding other treatment received by the patient.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system including a treatment control functionality for controlling the provision of at least one treatment to a patient.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least one treatment includes at least one of:
• intubation of the patient,
• hospitalization of the patient,
• treat the patient with medication, and
• transfer of the patient to an intensive care unit.
• Yet further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment control functionality is responsive to a pattern of changes in the at least one medical parameter over time.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment control functionality is responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment control functionality is additionally responsive to information regarding other treatment received by the patient.
• Still further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the treatment control functionality controls the provision of the at least one treatment to the patient in response to changes in the at least output indication over time.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least one medical parameter includes a plurality of medical parameters.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a system wherein at least two medical parameters include a plurality of medical parameters.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the plurality of medical parameters includes at least two of CO₂, ECG, SPO₂, PO₂, NIBP and spirometry parameters.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the output indication relating to a degree of severity of at least one medical condition is determined at least partially by changes in the at least one medical parameter.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a system wherein the at least one medical parameter includes a plurality of medical parameters.
• Also, the at least one medical parameter preferably includes a plurality of medical parameters.
• Yet further, in accordance with a preferred embodiment of the present invention, there is provided a system and also including a transmitter functionality adapted to convey the output indication to a remote location.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a system further operative to provide a treatment responsive to at least one of:
• the output indication, and
• the remote location.
• Further, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility and wherein the medical parameter interpretation functionality includes:
• a medical condition diagnosis functionality for diagnosing the presence of the at least one medical condition, and
• a medical condition severity functionality indicating the degree of severity of the at least one medical condition.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the medical parameter interpretation functionality provides an output indication responsive to a pattern of changes in the at least one medical parameter over time.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the medical parameter interpretation functionality provides an output indication responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility also including treatment recommendation functionality.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the treatment recommendation functionality is responsive to a pattern of changes in the at least one medical parameter over time.
• Also, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the treatment recommendation functionality is responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the treatment recommendation functionality is additionally responsive to information regarding other treatment received by the patient.
• Moreover, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility which includes a treatment control functionality for controlling the provision of at least one treatment to a patient.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the treatment control functionality is responsive to a pattern of changes in the at least one medical parameter over time.
• Further, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the treatment control functionality is responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Also, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the treatment control functionality is additionally responsive to information regarding other treatment received by the patient.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the at least one medical parameter includes a plurality of medical parameters.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the plurality of medical parameters includes at least two of CO₂, ECG, SPO₂, PO₂, NIBP, EEG and spirometry parameters.
• Further, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the output indication relating to a degree of severity of at least one medical condition is determined at least partially by changes in at least one medical parameter.
• Yet further, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility which also includes a transmitter functionality for conveying the output indication to a remote location.
• Also, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport facility wherein the treatment control functionality controls the provision of the at least one treatment to a patient in response to changes in the output indication over time.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the at least one medical parameter includes at least one of:
• an expired air carbon dioxide concentration, and
• an expired air carbon dioxide profile parameter.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the at least two medical parameters include at least one of:
• an expired air carbon dioxide concentration, and
• an expired air carbon dioxide profile parameter.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the plurality of parameters includes at least one of:
• an expired air carbon dioxide concentration, and
• an expired air carbon dioxide profile parameter.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein interfacing the patient includes monitoring the patient by means of at least one of:
• a monitoring device, and
• the medical parameter interpretation functionality.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein monitoring the patient includes monitoring by means of at least one of the following:
• an electrocardiogram (ECG) monitoring device,
• a blood pressure monitoring device,
• an electroencephalogram (EEG) monitoring device,
• an NI blood pressure monitoring device,
• a respiratory rate monitoring device,
• a heart rate monitoring device,
• a methodic perfusion monitoring device, and
• an exhaled air monitoring device.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein monitoring includes monitoring at least one of the following waveforms:
• a carbon dioxide waveform (capnogram),
• an EEG waveform, and
• an ECG waveform.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the monitoring includes analyzing a sample of expired air from the patient by a capnograph.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein analyzing the sample includes digitizing at least one of the waveforms.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a method wherein monitoring the patient includes providing at least one of the following measurements:
• a slope of the increase in the carbon dioxide concentration,
• a run of time taken to reach 80% maximum exhaled CO₂concentration, and
• an angle of rise to 80% maximum exhaled CO₂concentration.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the output includes indicating at least one of:
• defective functioning of the monitoring device, and,
• defective placing of the monitoring device,
• responsive to a value of at least one of the measurements.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein monitoring the patient includes providing a value of CAP-FEV1.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method including providing an alert responsive to a measure of CAP-FEV1 being less than 50% of an expected value.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein analyzing the sample includes providing responsive to at least one of:
• the run being greater than 0.3 seconds, or
• the slope being less than 100 mm Hg/sec.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the at least one medical parameter includes at least one of:
• a visual parameter,
• a breathing parameter,
• an oxygen parameter,
• an ECG parameter,
• a heart function parameter,
• a neurological parameter,
• a blood pressure parameter, and
• an EEG parameter.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the at least two medical parameters include at least one of:
• a visual parameter,
• a breathing parameter,
• an oxygen parameter,
• an ECG parameter,
• a heart function parameter,
• a neurological parameter,
• a blood pressure parameter, and
• an EEG parameter.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the plurality of medical parameters include at least one of:
• a visual parameter,
• a breathing parameter,
• an oxygen parameter,
• an ECG parameter,
• a heart function parameter,
• a neurological parameter,
• a blood pressure parameter, and
• an EEG parameter.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method further including providing an indication of a status of the patient as being within a normal range if at least one of the following requirements is fulfilled:
• a) the blood pressure values are within the normal range,
• b) the respiratory rate is normal,
• c) CO₂run is less than or equal to 0.3 sec,
• d) CO₂slope is more than or equal to 100 mm Hg/sec,
• e) SPO₂is greater or equal to than 95%, and
• f) ETCO₂is less than or equal to 45 mm Hg.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the indication of the patient's status being within the normal range if all of the following requirements are fulfilled:
• a) the blood pressure values are within the normal range,
• b) the respiratory rate is normal,
• c) CO₂run is less than or equal to 0.3 sec,
• d) CO₂slope is more than or equal to 100 mm Hg/sec,
• e) SPO₂is greater or equal to than 95%, and
• f) ETCO₂is less than or equal to 45 mm Hg.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a method including:
• diagnosing a presence of the at least one medical condition by a medical condition diagnosis functionality, and
• indicating a degree of severity of the at least one medical condition by a medical condition severity indication functionality
• Yet further, in accordance with a preferred embodiment of the present invention, there is provided a method including providing an indication of the patient's status being outside the normal range if any of the requirements are not fulfilled.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein including indicating the degree of severity of the at least one medical condition responsive to a degree of deviation from of any of the requirements.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein diagnosing the presence of the at least one medical condition includes diagnosing a respiratory disorder.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a method wherein diagnosing the respiratory disorder includes providing a diagnosis of a severity of the respiratory disorder responsive to a quantitative measure of deviation from at least one of the requirements.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the respiratory disorder includes at least one of:
• a restrictive lung disease,
• bronchospasm,
• asthma,
• bronchitis,
• emphysema,
• a respiratory failure,
• fibrosis, and
• an upper airway obstructive disease.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein indicating the degree of severity includes providing a diagnosis of the restrictive lung disease responsive to at least one of the following cases:
• the run is greater than 0.3 sec, or
• the slope is less than 100 mm Hg/sec.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein indicating the degree of severity includes providing a diagnosis of the obstructive lung disease responsive to at least one of the following cases:
• the run is less than or equal to 0.3 sec, or
• the slope is more than or equal to 100 mm Hg/sec.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the indication includes providing a diagnosis of a heart disorder responsive to any of the requirements not being fulfilled.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method including providing a diagnosis of a heart failure if the following conditions are fulfilled:
• CAP-FEV1 is less than or equal to a 40:10 point ratio,
• a normal CAP-FEV1/FVC ratio,
• CO₂run is less than or equal to 0.3 sec, and
• CO₂slope is more than or equal to 100 mm Hg/sec.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing an indication includes providing a diagnosis of a severity of the heart disorder.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing an output indication includes providing a plurality of output indications.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing a plurality of output indications includes providing at least one recommendation to perform at least one of the following treatments:
• intubation of the patient,
• hospitalization of the patient,
• treat the patient with medication, and
• transfer of the patient to an intensive care unit.
• Typically the visual parameter includes a visual appearance of the patient. Generally the breathing parameter includes at least one of:
• a respiratory rate of the patient,
• an FEV value, and
• an FVC value.
• Normally, the oxygen parameter includes at least one of:
• PO₂, and
• SPO₂.
• Generally, the ECG parameter includes at least one of:
• a QRS parameter, and
• an ST segment.
• Preferably, the heart function parameter includes a heart rate parameter.
• Typically, the neurological function parameter includes a reflex parameter.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the blood pressure parameter includes at least one of:
• a blood pressure measurement, and
• a systolic:diastolic ratio.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a method including providing the output indication responsive to a pattern of changes in the at least one medical parameter over time.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the output indication is responsive to a pattern of changes in the at least two medical parameters over time.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method providing the output indication responsive to a pattern of changes in the plurality of medical parameters over time.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method including providing an output indication responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a method including providing a treatment recommendation by means of a treatment recommendation functionality.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the treatment recommendation is responsive to a pattern of changes of at least one medical parameter over time.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the treatment recommendation is responsive to the location of the patient.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the pattern of changes includes a change in at least one of the following:
• a change in a run,
• a change in an ETCO₂,
• a change in a slope,
• a change in an angle of rise of CO₂, and
• a change in an SPO₂.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the treatment recommendation is responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the treatment recommendation includes providing an alert if at least one of the following conditions is fulfilled:
• a change in the run of more than 0.1 s,
• a change in the slope is more negative than −15 mm Hg/sec, and
• a change in the SPO₂is more negative than −5%.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the treatment recommendation includes providing a recommendation for at least one of the following treatments:
• intubation of the patient,
• hospitalization of the patient,
• treat the patient with intravenous medication, and
• transfer of the patient to an intensive care unit.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the treatment includes providing a recommendation to perform at least one of:
• continue monitoring the patient, and
• continue treating the patient,
• provided at least one of the following conditions is fulfilled:
• a change in the run is less negative or equal to −0.1 s but less positive or equal to 0.1 s,
• a change in the slope is less negative or equal to −15, Hg/sec, but less positive or equal to +15 mm Hg/sec, and
• a change in the SPO₂is less negative or equal to −5%, but less positive or equal to +5%.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the treatment includes at least one of the following:
• providing a message indicative of an improvement in the patient's status, and
• recommending discontinuing a treatment procedure, if at least one of the following conditions is fulfilled:
• a change in the run is more negative than −0.1 s,
• a change in the slope is more positive than +15 mm Hg/sec, and
• a change in the SPO₂is more positive than 5%.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the treatment includes providing a recommendation to continue monitoring the patient responsive to the pattern of changes indicating at least one of:
• a deterioration in the status of the patient, and,
• a non-significant change in the status of the patient.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein providing the treatment includes providing a recommendation to stop monitoring the patient responsive to the pattern of changes indicating an improvement in the status of the patient.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method including providing at least one of the following treatments to the patient:
• intubation of the patient,
• hospitalization of the patient,
• treat the patient with medication, and
• transfer of the patient to an intensive care unit.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein controlling the provision of at least one treatment includes responding to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the treatment control functionality is additionally responds to information regarding other treatment received by the patient.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the at least one medical parameter includes a plurality of parameters.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the at least two medical parameters include a plurality of parameters.
• Further, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the plurality of medical parameters includes at least two of CO₂, ECG, SPO₂, PO₂, NIBP and spirometry parameters.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the output indication relating to the degree of severity of the at least one medical condition is determined at least partially by changes in the at least one medical parameter.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided a method including conveying the output indication to a remote location by means of a transmitter functionality.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method including conveying the plurality of output indications to a remote location by means of a transmitter functionality.
• Also, in accordance with a preferred embodiment of the present invention, there is provided a method wherein the treatment control functionality controls the provision of the at least one treatment to a patient in response to changes in the output indication over time.
• Also, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein interpreting the at least one medical parameter includes:
• diagnosing the presence of at least one medical condition by means of a medical condition diagnosis functionality, and
• indicating the degree of severity of the at least one medical condition by means of a medical condition severity functionality.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology including providing an output indication responsive to a pattern of changes in the at least one medical parameter over time by means of the medical parameter interpretation functionality.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology including providing an output indication responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Also, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology including providing a treatment recommendation by means of a treatment recommendation functionality.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the treatment recommendation functionality is responsive to a pattern of changes in the at least one medical parameter over time.
• Also, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the treatment recommendation functionality is responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Further, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the treatment recommendation functionality is additionally responsive to information regarding other treatment received by the patient.
• Also, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein including treatment control functionality for controlling the provision of at least one treatment to the patient.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the treatment control functionality is responsive to a pattern of changes in the at least one medical parameter over time.
• Also, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the treatment control functionality is responsive to a pattern of changes in the degree of severity of the at least one medical condition over time.
• Furthermore, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the treatment control functionality is additionally responsive to information regarding other treatment received by the patient.
• Also, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the at least one medical parameter includes a plurality of medical parameters.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the plurality of medical parameters includes at least two of CO₂, ECG, SPO₂, PO₂, NIBP, EEG and spirometry parameters.
• Further, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the output indication relating to a degree of severity of at least one medical condition is determined at least partially by changes in at least one medical parameter.
• Yet further, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology including a transmitter functionality for conveying the output indication to a remote location.
• Also, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the treatment control functionality controls the provision of the at least one treatment to a patient in response to changes in the output indication over time.
• Additionally, in accordance with a preferred embodiment of the present invention, there is provided an emergency medical transport methodology wherein the treatment control functionality controls the provision of the at least one treatment to a patient in response to the location of the patient.
1. BRIEF DESCRIPTION OF THE DRAWINGS
• The present invention will be understood and appreciated more fully from the following detailed description, taken in conjunction with the drawings in which:
• FIGS. 1A,1B and1C are simplified pictorial illustrations showing a medical care system and methodology employing at least one parameter relating at least to respiration for automatically providing an output indication relating to at least one medical condition in accordance with a preferred embodiment of the present invention in three different types of care environments;
• FIG. 2 is a flowchart illustrating operation of the embodiments ofFIGS. 1A-1C;
• FIG. 3 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an on-scene environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of a spontaneously breathing patient;
• FIG. 4 is a flowchart illustrating operation of the embodiment ofFIG. 3;
• FIG. 5 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an on-scene environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of mechanically ventilated patients;
• FIGS. 6A and 6B are flowcharts illustrating operation of the embodiment ofFIG. 5;
• FIG. 7 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of spontaneously breathing patients;
• FIGS. 8A and 8B are flowcharts illustrating operation of the embodiment ofFIG. 7;
• FIG. 9 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of mechanically ventilated patients;
• FIGS. 10A,10B and10 C are a flowcharts illustrating operation of the embodiment ofFIG. 9;
• FIG. 11 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for detecting the severity of bronchospasm, gauging the response to treatment and recommending disposition of spontaneously breathing patients;
• FIG. 12 is a flowchart illustrating operation of the embodiment ofFIG. 11;
• FIG. 13 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of mechanically ventilated patients;
• FIGS. 14A and 14B are flowcharts illustrating operation of the embodiment ofFIG. 13;
• FIG. 15 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for distinguishing between heart failure and emphysema, where emphysema is present;
• FIGS. 16A and 16B are flowcharts illustrating operation of the embodiment ofFIG. 15;
• FIG. 17 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for monitoring intubation status of a patient;
• FIG. 18 is a flowchart illustrating operation of the embodiment ofFIG. 17;
• FIG. 19 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for monitoring respiratory status of a patient in a first clinical scenario;
• FIG. 20 is a flowchart illustrating operation of the embodiment ofFIG. 19;
• FIGS. 21A and 21B are simplified pictorial illustrations of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for monitoring intubation status of a patient in a second clinical scenario;
• FIGS. 22A,22B and22 C are flowcharts illustrating operation of the embodiment ofFIGS. 21A and 21B;
• FIGS. 23A and 23B are simplified pictorial illustrations of a diagnostic and treatment system and methodology operative in a physician's office environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of a spontaneously breathing patient in a first clinical scenario;
• FIGS. 24A and 24B are flowcharts illustrating operation of the embodiment ofFIGS. 23A and 23B;
• FIGS. 25A and 25B are simplified pictorial illustrations of an automatic medical diagnostic and treatment system and methodology operative in a physician's office environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of a spontaneously breathing patient in a second clinical scenario;
• FIGS. 26A and 26B are flowcharts illustrating operation of the embodiment ofFIGS. 25A and 25B,
• FIGS. 27A and 27B are simplified pictorial illustrations of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for detecting the presence and severity of bronchospasm from an allergic reaction, gauging the response to treatment and recommending disposition;
• FIG. 28 is a flowchart illustrating operation of the embodiment ofFIGS. 27A and 27B;
• FIG. 29 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for distinguishing between upper airway obstruction and lower airway obstruction, gauging the response to treatment and recommending disposition;
• FIG. 30 is a flowchart illustrating operation of the embodiment ofFIG. 29;
• FIG. 31 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for distinguishing between heart failure and emphysema in a scenario in which heart failure is present;
• FIGS. 32A and 32B are flowcharts illustrating operation of the embodiment ofFIG. 31;
• FIG. 33 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for treating pulmonary edema;
• FIGS. 34A and 34B are flowcharts illustrating operation of the embodiment ofFIG. 33;
• FIG. 35 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for anesthesia monitoring;
• FIG. 36 is a flowchart illustrating operation of the embodiment ofFIG. 35;
• FIG. 37 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for diagnosis and treatment of pulmonary embolism;
• FIG. 38 is a flowchart illustrating operation of the embodiment ofFIG. 37;
• FIGS. 39A and 39B are simplified pictorial illustrations of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for determination of correct nasogastric tube placement;
• FIG. 40 is a flowchart illustrating operation of the embodiment ofFIGS. 39A and 39B;
• FIG. 41 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for diagnosis and treatment of myocardial infarction;
• FIG. 42 is a flowchart illustrating operation of the embodiment ofFIG. 41;
• FIG. 43 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for diagnosis and treatment of cardiogenic shock;
• FIG. 44 is a flowchart illustrating operation of the embodiment ofFIG. 43;
• FIG. 45 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for diagnosis and treatment of cardiac arrest;
• FIG. 46 is a flowchart illustrating operation of the embodiment ofFIG. 45;
• FIG. 47 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for diagnosis and treatment of cardiac ischemia;
• FIG. 48 is a flowchart illustrating operation of the embodiment ofFIG. 47;
• FIG. 49 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for monitoring sedation; and
• FIG. 50 is a flowchart illustrating operation of the embodiment ofFIG. 49;
• FIG. 51 is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for drug titration during sedation; and
• FIG. 52 is a flowchart illustrating operation of the embodiment ofFIG. 51.
2. DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS
• Reference is now made toFIGS. 1A,1B and1 C, which are simplified pictorial illustrations showing a medical care system and methodology employing at least one parameter relating at least to respiration for automatically providing an output indication relating to at least one medical condition in accordance with a preferred embodiment of the present invention in three different types of care environments.
• Turning toFIG. 1A, it is seen that in an out of hospital environment, such as a doctor's office or other ambulatory care facility, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula100, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph102, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. electrocardiogram (ECG)), cerebral perfusion (e.g. CEREBRAL OXIMETRY), oxygenation (e.g. pulse oximetry) and systemic circulation (e.g. . . . blood pressure (NIBP)), may also be sensed and measured bysuitable instrumentation104.
• The outputs of thecapnograph102 and possibly ofadditional instrumentation104 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer110, which typically analyzes the respiration parameter output of thecapnograph102, and also typically has an associateddisplay112, the display being at least one of a visual display, such as a computer screen, a virtual display, or a printed form of a display. Optionally further physiologic activities are outputted fromcapnograph102 andinstrumentation104, and provided as outputs viacomputer110 anddisplay112, which preferably contain diagnostic statements, which preferably characterize the type and severity of a medical condition, as well as treatment recommendations.
• Turning toFIG. 1B, it is seen that in an ambulance environment, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula100, such as a such as a Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph113, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), cerebral perfusion (e.g. CEREBRAL OXIMETRY), oxygenation (e.g. pulse oximetry) and systemic circulation (e.g. NIBP), may also be sensed and measured bysuitable instrumentation114.
• The outputs of thecapnograph113 and possibly ofadditional instrumentation114 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer116, having an associateddisplay118, which typically analyzes the respiration parameter output of thecapnograph113 and possibly other parameters and provides an output which preferably contains diagnostic statements, which preferably characterize the type and severity of a medical condition, as well as treatment recommendations.
• Preferably some or all of the outputs ofcomputer116 are transmitted in a wireless manner by atransmitter119, such as via radio or a cellular telephone link, preferably to a dispatch center or patient receiving facility.
• Turning toFIG. 1C, it is seen that in a hospital environment, such as an emergency department, medical ward or intensive care unit (ICU), various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula120, such as a Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph122, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), cerebral perfusion (e.g. CEREBRAL OXIMETRY), oxygenation (e.g. pulse oximetry) and systemic circulation (e.g. NIBP), may also be sensed and measured bysuitable instrumentation124.
• The outputs of thecapnograph122 and possibly ofadditional instrumentation124 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer126 at the patient's bedside and/or at a central monitoring station, having an associateddisplay128, which typically continuously analyzes the respiration parameter output of thecapnograph122 and possibly other parameters and provides an output which preferably contains diagnostic statements, which preferably characterize the type and severity of a medical condition, as well as treatment recommendations.
• Reference is now made toFIG. 2, which is a flowchart illustrating operation of the embodiments ofFIGS. 1A-1C.
• In a sensing stage, the patient's physiologic activity preferably is monitored by collecting an expired air sample viacannula100, and conveying the sample to an analyzer, integrally part of a capnograph, such as capnograph102 (FIG. 1A),113 (FIG. 1B), and122 (FIG. 1C). Simultaneously, some of the patient's other physiological parameters may be sensed, sampled and monitored employing suitable instrumentation104 (FIG. 1A),114 (FIG. 1B), and124 (FIG. 1C). These parameters include, but are not limited to, cardiac activity, ventilation and systemic and cerebral perfusion, and oxygenation parameters.
• Data including the parameters monitored and sampled by, for example,instrumentation104 are relayed tocomputer110. The measured patient parameters are analyzed bycomputer110 and advisory statements, preferably including at least one of diagnostic statements as to the character and severity of a medical condition and therapeutic recommendations may be displayed on adisplay112, or transmitted to a remote location. Changes in the measured patient parameters are recorded over time bycomputer110 and the resulting trends may be displayed ondisplay112 or transmitted. The trends may also be employed for generating trend based advisory statements, preferably including at least one of diagnostic statements as to the character and severity of a medical condition and therapeutic recommendations.
• Typically, the exhaled carbon dioxide of the patient is measured continuously over thirty seconds bycapnograph102. Additionally or alternatively, patient may be measured for shorter or longer durations. The end tidal value of the exhaled carbon dioxide (ETCO₂) profile is digitized as a waveform and may be stored for analysis in the memory of suitably programmed automatic diagnostic andtreatment computer110. Additionally or alternatively, the waveform may be stored and analyzed by other means,
• Thereafter, in an analyzing stage, the measured patient parameters, such as the limits of inspiration and expiration are delineated and/or marked oncomputer110. The initial slope in the increase of the exhaled carbon dioxide concentration up to 80% of the maximum (henceforth designated as “slope”) and angle of rise up to 80% of the maximum carbon dioxide exhaled are measured.
• In a rule application step, the following rules defining the patient status preferably are applied bycomputer110, for example, to the CO₂profile measured by capnograph102:
• If:
• a) the time duration to reach 80% of the maximum CO₂concentration (designated henceforth as “run” or “CO₂run”) is greater than 0.3 seconds; and,
• b) the slope of the increase in concentration of CO₂is less than 100 mm Hg/sec (designated henceforth as “slope” or “CO₂slope”);
• then: an alert signal such as “ALERT: BRONCHOSPASM PRESENT” or “ALERT: ASTHMA PATIENT” is displayed ondisplay112 associated withcomputer110.
• If the patient is an asthma patient according to the definition of the previous step, then the patient receives the appropriate treatment. Thereafter, a second set of exhaled carbon dioxide profile measurements are taken bycapnograph102, and the differences between the initial measurements and these second set of measurements are computed bycomputer110. The following decision rule is preferably applied:
• If:
• a) the difference in the run is less than 0.1 sec; and
• b) the difference in the slope is less than +15 mm Hg/sec;
• then,
• a message is displayed ondisplay112 such as “ADMIT PATIENT TO HOSPITAL”. Additionally or alternatively, further tests may be performed for checking the severity of the patient's condition as are described hereinbelow.
• If the patient is not yet in hospital, as is portrayed inFIGS. 1A and 1B, then a typical message is “ADMIT TO HOSPITAL”. Whereas, if the patient is already in the hospital environment (FIG. 1C), a typical message is “PATIENT REQUIRES URGENT TREATMENT BY PHYSICIAN.” Additionally or alternatively, further tests may be performed for checking the severity of the patient's condition as are described hereinbelow.
• If the values of the difference in the run and the difference in the slope are beyond those of the decision rule, then another message may be displayed such as “PATIENT IMPROVING” ondisplay112.
• Reference is now made toFIG. 3, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an on-scene environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of the patient. As seen inFIG. 3, in an on scene environment, such as at a patient's home, after a patient calls EMS after having sensed shortness of breath, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula130, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph132, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes134, afinger sensor136, a forehead/scalp sensor138,cannula130 and a blood pressure cuff (sphygmomanometer)140 respectively, may also be sensed and measured bysuitable instrumentation154.
• The outputs of thecapnograph132 and preferably ofadditional instrumentation154 are preferably supplied to a suitably programmed automatic diagnostic and treatment computer144, having an associated display146, which typically analyzes the respiration parameter output of thecapnograph132, and preferably other physiologic activities and provides an output which preferably contains a diagnostic statement, here “ALERT: MODERATE BRONCHOSPASM PRESENT”. The severity of the patient's condition is defined by measured parameters as described hereinbelow.
• The patient is preferably given breathing treatment, such as a beta agonist nebulizer treatment and following such treatment and/or in the course thereof, the physiologic activities of the patient continue to be monitored. This monitoring is employed bycomputer160 to indicate the response to the breathing treatment and the current status of the bronchospasm condition. The patient is then transferred to an ambulance.
• Reference is now made additionally toFIG. 4, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 3. The patient previously attached to a multi-parameter monitor including acapnograph132 andsuitable instrumentation154, by means ofcannula130 and preferably also by means ofchest electrodes134,finger sensor136,forehead sensor138 andblood pressure cuff140, is monitored continuously for at least thirty seconds. Neurological status of the patient is acquired by any suitable technique, including visual and electroencephalograph (EEG) monitoring. Values of CO₂concentration, ECG, NIBP and the SPO₂(the percent saturation of the hemoglobin molecule with oxygen) in units of % saturation (designated as % SAT herein), are continuously monitored, and carbon dioxide waveforms are preferably digitized as a capnogram169 and together with other waveforms are stored in computer144.
• At least one expired air sample is collected and conveyed for analysis bycapnograph132. The following gold standards of base pulmonary function measures are as follows: FEV1 is defined as the Forced Expiratory Volume over 1 second, and is a measure of flow. FVC is the Forced Vital Capacity and is a measure of volume. The character ratio is FEV1/FVC. This is the ratio of flow to volume: markedly less than 1 in bronchospasm and close to a value of 1 in patients of normal status and those with restrictive disease.
• Severity of a pulmonary disease may preferably be defined by FEV1: Reduced flow and/or volume over the first second, as compared to normal. This applies to both obstructive and restrictive disorders.
• Forced expiratory volume (FEV) values are preferably determined employing a correlation from at least one capnographic measurement, and are denoted herein as CAP-FEY or CAP-FEV1 (measured over one second). The severity criteria is assessed from the capnogram using a measure that we refer to as Cap-FEV1, to emphasize it's relation to the gold-standard FEV1 and it's derivation from the Capnogram. The area under capnogram169 is measured over the first second. This, the CAP-FEV1 is computed as (SUM [CO₂] (First second)) or, at 40 Hz device sampling rate, (SUM (n=0:40). [CO₂]n). The units are “% of expected value”, or “%”. Additionally or alternatively, the CAP-FEV1 may be determined by standard spirometry techniques known in the art-as is FEV 1.
• The capnographic analysis preferably includes molecular correlation spectroscopy (MSC), but may also be performed employing infrared analysis. The outputs of thecapnograph132 and possibly ofadditional instrumentation154 are preferably supplied to suitably programmed automatic diagnostic and treatment computer144, having associated display146, which typically analyzes the respiration parameter output of thecapnograph132.
• In an analyzing step, computer144 marks the onset and offset limits of a capnogram169, pulse waveforms, and the QRS complex (of the ECG). The actual parameters measured include, but are not limited to heart rate (HR), BP, the systolic to diastolic ratio (SYS/DIA). SPO₂, AND ETCO₂. The slope of CO₂(mm Hg/sec), and CO₂“run”, of thecapnogram132, measured to 80% of maximum CO₂concentration, are calculated by computer144.
• Following each treatment, computer144 computes the differences between consecutive measurements of the various patient parameters. Thereafter, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters by computer144:
• 1). If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater or equal to than 95% SAT; and
• f) ETCO₂is less than or equal to. 45 mm Hg;
• then,
• display146 shows the message “VITAL SIGNS WITHIN NORMAL LIMITS.”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is more than or equal to 91% SAT but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed on display146;
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 (forced expiratory volume in one second) is less than 50%;
• b) SPO₂is less than 92% SAT; and
• c) ETCO₂(end tidal value of the exhaled carbon dioxide) is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is displayed on display146.
• It should be understood from this example that the severity of the a respiratory disorder, whether restrictive or obstructive, may be determined by CAP-FEV 1 measurements. The use of the capnographic measurements for diagnosis of whether the respiratory disorder is restrictive or obstructive is described inFIG. 30 hereinbelow. Similarly, the ratio CAP-FEV1/FVC (forced vital capacity) may be applied to diagnose whether the patient is suffering from a restrictive or obstructive breathing disorder as is described hereinabove.
• Reference is now made toFIG. 5, which is also a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an on-scene environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of the patient. As seen inFIG. 5 and similarly to that described hereinabove with reference toFIG. 3, in an on scene environment, such as at a patient's home, after a patient calls EMS after having sensed shortness of breath, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula150, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph152, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes154, afinger sensor156, a forehead/scalp sensor158 and ablood pressure cuff160 respectively, and may also be sensed and measured bysuitable instrumentation154.
• The outputs of thecapnograph152 and preferably ofadditional instrumentation154 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer160, having an associateddisplay162, which typically analyzes the respiration parameter output of thecapnograph152 and preferably other physiologic activities and provides an output which preferably contains a diagnostic statement, here “ALERT: SEVERE BRONCHOSPASM PRESENT”.
• The patient is given breathing treatment, such as a beta agonist nebulizer treatment and following such treatment and/or in the course thereof, the physiologic activities of the patient continue to be monitored. This monitoring is employed bycomputer160 to indicate the response to the breathing treatment and the current status of the bronchospasm condition. In the scenario ofFIG. 3, the patient fails to respond sufficiently to the breathing treatment and this is indicated by a status statement, here “POOR RESPONSE TO TREATMENT, CONDITION CRITICAL”. A treatment recommendation may also be provided, such as “CONSIDER INTUBATION”.
• Intubation is performed and correct intubation tube placement is confirmed by continuing monitoring of the physiologic activities of the patient. A status statement, here: “ADEQUATE CO₂WAVEFORM-TUBE IN TRACHEA” and a treatment recommendation, here “SECURE TUBE” appear.
• The patient is then transferred to an ambulance. While the physiologic activities of the patient continue to be monitored and serve to confirm continued proper placement of the intubation tube in the trachea. A status statement, here “TUBE IN TRACHEA” appears. Typically, the position of the tube is continuously monitored bycomputer160, and a status statement “MONITORING TUBE POSITION” appears ondisplay162.
• Reference is now made additionally toFIGS. 6A and 6B, which illustrate the operation of the system and methodology of the system of the present invention in the context ofFIG. 5. In a monitoring step, the patient, attached to a multi-parameter monitor including acapnograph152 andinstrumentation154, by means ofcannula150 and preferably also by means of chest electrodes164, finger sensor166, forehead/scalp sensor158 and blood pressure cuff168, is monitored. Neurological status of the patient is acquired by any suitable technique.
• At least one expired air sample is collected and conveyed tocapnograph152. Further measurements of ECG and blood pressure are monitored by standard techniques, employing chest electrodes164 and blood pressure cuff168 respectively. The actual parameters measured include, but are not limited to heart rate, blood pressure ETCO₂and SPO₂(SYS/DIA). SPO₂, NIBP, and cerebral oximetry values, and these parameters are measured and/or determined continuously by techniques as detailed hereinabove. These parameter values are typically digitized as waveforms and are further stored for analysis bycomputer160.
• In an analyzing step, the onset and offset limits ofcapnograph152, pulse waveforms, and the QRS complex (ECG) measured byadditional instrumentation154, are delineated and marked bycomputer160. The limits of the capnogram, the pulse waveform and QRS onset and offset are determined and recorded incomputer160. The slope of the capnogram (mm Hg/sec), and the run and thereof is measured to 80% of maximum CO₂concentration are calculated bycomputer160.
• Thereafter, in a diagnostic rule application step, the following diagnostic rules are applied to the measured parameters by computer160:
• 1. if:
• a) the blood pressure values are within the normal range;
• b) respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm Hg;
• then,
• computer160 displays a message “NO BRONCHOSPASM PRESENT” ondisplay162.
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 see;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is more than or equal to 91% SAT, but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• computer160 provides the message “MODERATE BRONCHOSPASM PRESENT” ondisplay162.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is more than or equal to 90% SAT, but is less than 91% SAT; and
• c) ETCO₂is greater than 45 mm Hg, but less than or equal to 60 mm Hg;
• then,
• computer160 provides a message “SEVERE BRONCHOSPASM PRESENT” ondisplay162.
• 4. If the parameters measured are still yet further removed from the acceptable range, such as if:
• a) SPO₂is less than 90% SAT;
• b) the respiratory rate is less than 8 per minute;
• c) ETCO₂is greater than 60 mm Hg; and
• d) the neurological parameters are poor;
• then,
• computer160 issues a message ondisplay162 stating “RESPIRATORY FAILURE; CONDITION CRITICAL; CONSIDER INTUBATION”.
• Subsequently, in an intubation stage, a standard intubation procedure is followed, as is described hereinabove inFIG. 5. Thereafter, an operator, typically a physician or paramedic, confirms that the intubation monitoring mode has been activated, and the patient is monitored for a successful outcome of the intubation. Thereafter,computer160 displays a message stating “MONITORING FOR INTUBATION” ondisplay162.
• The next step entails a checking procedure, wherein the ETCO₂value is measured bycapnograph152.
• The following checking rule is preferably applied.
• 1) If:
• a) the ETCO₂value is more than 15;
• then,
• a display is provided bycomputer160 stating “GOOD WAVEFORM, TUBE IN TRACHEA, CONFIRM AND SECURE TUBE” ondisplay162.
• Thereafter, the ETCO₂value is measured again bycapnograph152, and recorded bycomputer160. The following monitoring rules are preferably applied.
• 1). If:
• a) the ETCO₂value is more than 15 mm Hg;
• then,
• a message is displayed bycomputer160 ondisplay162 stating “MONITORING TUBE IN POSITION: NO DISLODGEMENT.”
• 2) Whereas, if:
• a) the ETCO₂value is less than or equal to 15 mm Hg; or
• b) there is a loss in the tracking of the waveform bycapnograph152;
• then,
• a message is displayed bycomputer160 stating “ALERT: CHECK FOR TUBE DISLODGEMENT” ondisplay162.
• Reference is now madeFIG. 7, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of spontaneously breathing patients. As seen inFIG. 7, in an ambulance environment, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula170, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph172, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes174, afinger sensor176, a forehead/scalp sensor178 and ablood pressure cuff180 respectively, may be received and analyzed by additional instrumentation182.
• The outputs of thecapnograph172 and possibly of additional instrumentation182 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer184, having an associateddisplay186, which typically analyzes the respiration parameter output of thecapnograph172 and possibly other parameters and provides an output which preferably contains a diagnostic statement, here “ALERT: MODERATE BRONCHOSPASM PRESENT”. A breathing treatment is administered after which a diagnostic statement which indicates the patient status and the severity of the respiratory condition is preferably presented, here “GOOD RESPONSE TO TREATMENT, CONDITION IMPROVING”. Additional breathing treatment is typically administered after which a diagnostic statement which indicates the current patient status and the severity of the respiratory condition is preferably presented, here “NO BRONCHOSPASM PRESENT, CONDITION STABLE”.
• Preferably, response to treatment statements as well as disposition recommendations may be appended to patient status statements, here “RAPID RESPONSE TO TREATMENT, CONDITION REMAINS STABLE, DISCHARGE TO HOME LIKELY”.
• Preferably some or all of the outputs ofcomputer184 are transmitted in a wireless manner by atransmitter188, such as via radio or a cellular telephone link, preferably to a dispatch center or patient receiving facility.
• Reference is now made additionally toFIGS. 8A and 8B, which illustrate the operation of the system and methodology of the system of the present invention in the context ofFIG. 7. In a monitoring step, the patient in an ambulance environment, attached to a multi-parametermonitor including capnograph172, by means ofcannula170 and preferably also by means ofchest electrodes174,finger sensor176, scalp/forehead sensor178 andblood pressure cuff178, is monitored continuously. Neurological status of the patient is acquired by any suitable technique. Values of the CO₂concentration monitored bycapnograph172, and ECG, NIBP, cerebral oximetry and SPO₂values, monitored by additional instrumentation182 are supplied tocomputer184, and are typically measured continuously over a period of 30 seconds, by techniques as detailed hereinabove. The parameter data may be digitized as waveforms and are further stored for analysis bycomputer184. Thereafter, the limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer184. The heart rate, blood pressure ETCO₂and SPO₂values are measured. The initial slope of the capnogram and the run, monitored bycapnograph172, are calculated bycomputer184. Additionally, neurological findings, monitored by means of an EEG are inputted tocomputer184.
• In an analyzing step, the onset and offset limits of the capnogram, pulse waveforms, and the QRS complex (ECG) are marked bycomputer184.
• Following each treatment, the differences between consecutive measurements of the various patient parameters are evaluated bycomputer184. After each treatment, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters by computer184:
• I) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm Hg;
• then,
• display162 shows the message “NO BRONCHOSPASM PRESENT”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is more than or equal to 91% SAT less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed ondisplay186.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is less than 92% SAT; and
• c) ETCO₂is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is displayed ondisplay186.
• The findings of the last stage are stored bycomputer184 and/or transmitted to a dispatch/receiving center, typically located at a hospital or medical center [ref. no]. A connection is established with the dispatch/receiving center [ref. no], and the data is forwarded thereto. A medical supervisor typically watches display of the received data, and consequentially transmits the recommended treatment and/or transport recommendations back to the ambulance.
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer184: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer184.
• 1) If:
• a) the difference in the run values is greater than +0.1 sec; and
• b) the difference in the slope is more negative than −15 mm Hg/sec;
• then,
• computer184 displays ondisplay186 “BRONCHOSPASM WORSENING”.
• 2) If:
• a) the difference in the run values is more negative than −0.1 sec; and
• b) the difference in the slope is more than +15 mm Hg/sec;
• then,
• computer184 displays ondisplay186 “BRONCHOSPASM IMPROVING”.
• 3) If:
• a) the difference in the slope is more than or equal to −15 mm Hg/sec and less than or equal to +15 mm Hg/sec;
• then,
• computer184 displays ondisplay186 “UNCHANGED”.
• The change in patient's vital functional activities, including SPO₂and ETCO₂, over the time interval are calculated bycomputer184,
• 4) If:
• a) the decrease in SPO₂is more than −5% SAT; or
• b) the increase in the ETCO₂is more than +5 mm Hg;
• then,
• computer184 displays ondisplay186 “VITAL SIGNS DETERIORATING.”
• 5) If:
• a) the increase in SPO₂is greater than +5% SAT; or
• b) the decrease in the ETCO₂is less than −5 mm Hg;
• then,
• computer184 displays ondisplay186 “VITAL SIGNS IMPROVING”.
• 6) If:
• a) the change in SPO₂is greater than or equal to −5% SAT, but less than or equal to +5%; or
• b) the change in the ETCO₂is more than or equal to −5 mm Hg, or less than or equal to +5 mm Hg;
• then.
• computer184 displays ondisplay186 “VITAL SIGNS UNCHANGED.”
• Computer184 preferably combines the results of these monitoring rules to display anintegrated display186 such as ““BRONCHOSPASM WORSENING; VITAL SIGNS UNCHANGED.”
• Thereafter, in a transmission stage, the connection with the receiving center is maintained. The receiving center periodically receives updates of the patient's condition, who is in the ambulance en route to the hospital, in order to prepare in the most fitting and efficient transfer of the patient upon arrival to the hospital.
• Following the transmission stage, the following exit rules are preferably applied to the measured parameters by computer184:
• 1) If
• a) the blood pressure values are within normal limits;
• b) the respiratory rate is within normal limits;
• c) the value of the CO₂run is less than 0.3 seconds; and
• d) the CO₂slope is greater than 100 mm Hg/sec;
• then,
• Computer184 preferably displays ondisplay186 “NO BRONCHOSPASM PRESENT”.
• If the patient's record complies with this exit rule, then a copy of the patient's record is handed off fromcomputer184 to the receiving center, for example, in the form of a chart. Typically, the receiving center stores this chart, so that it may be used as a baseline for continued monitoring of the patient.
• Reference is now made toFIG. 9, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of mechanically ventilated patients. As seen inFIG. 9 and similarly to that described hereinabove with reference toFIG. 5, in an ambulance environment various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula200, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with a capnograph202, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes204, afinger sensor206, a forehead/scalp sensor208 and ablood pressure cuff209 respectively, may also be sensed and measured by suitable instrumentation210. Other patient physiologic activities relating to cardiac function (e.g. ECG), cerebral perfusion (e.g. CEREBRAL OXIMETRY), oxygenation (e.g. pulse oximetry) and systemic circulation (e.g. NIBP), may also be sensed and measured bysuitable instrumentation212
• The outputs of the capnograph202 and preferably ofadditional instrumentation212 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer214 having an associateddisplay216, which typically analyzes the respiration parameter output of the capnograph202 and preferably other physiologic activities and provides an output which preferably contains a diagnostic statement, here “ALERT: SEVERE BRONCHOSPASM PRESENT”.
• The patient is given breathing treatment, such as a beta agonist nebulizer treatment and following such treatment and/or in the course thereof, the physiologic activities of the patient continue to be monitored. This monitoring is employed bycomputer214 to indicate the response to the breathing treatment and the current status of the patient condition. In the scenario ofFIG. 9, the patient fails to respond sufficiently to the breathing treatment and this is indicated by a status change statement, here “POOR RESPONSE TO TREATMENT, CONDITION WORSENING”. A treatment recommendation may also be provided, such as “CONSIDER INTUBATION”.
• Intubation is performed and correct initial tube placement is confirmed followed by continuous monitoring of the physiologic activities of the patient, which indicate current tube position. Where intubation is successful, a status statement, here: “ADEQUATE CO2 WAVEFORM-TUBE IN TRACHEA” and a treatment recommendation, here “SECURE TUBE” appear. Where intubation is not successful, a status statement, here: “NO CO2 WAVEFORM-TUBE IN ESOPHAGUS” and a treatment recommendation, here “REINTUBATE” appear.
• Following successful intubation, continuous monitoring may provide a status statement such as “ADEQUATE CO2 WAVEFORM-TUBE IN TRACHEA-NO DISLOGEMENT” may appear. If tube dislodgment occurs at any time following intubation, a status statement appears, here “CO2 WAVEFORM ABSENT” preferably accompanied by a treatment recommendation, here “CHECK FOR TUBE DISLOGEMENT”.
• Preferably some or all of the outputs ofcomputer214 are transmitted in a wireless manner by atransmitter218, such as via radio or a cellular telephone link, preferably to a dispatch center or patient receiving facility.
• Reference is now made additionally toFIGS. 10A-10C, which illustrate the operation of the system and methodology of the system of the present invention in the context ofFIG. 9.
• In a monitoring step, the patient in an ambulance environment, attached to a multi-parameter monitor including capnograph202 andinstrumentation212, by means ofcannula200 and preferably also by means ofchest electrodes204,finger sensor206, scalp/forehead sensor208 andblood pressure cuff209, is monitored continuously. Neurological status of the patient is acquired by any suitable technique. Values of the CO₂concentration monitored by capnograph202, and ECG, NIBP, cerebral oximetry and SPO₂values, monitored byadditional instrumentation212 are supplied tocomputer214, and are typically measured continuously over a period of 30 seconds, by techniques as detailed hereinabove. The parameter data may be digitized as waveforms and are further stored for analysis bycomputer214. Thereafter, the onset and offset limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer214. The heart rate, blood pressure ETCO₂and SPO₂values are measured. The initial slope of the capnogram and the run, monitored by capnograph202, are calculated bycomputer214. Additionally, neurological findings, monitored by means of an EEG are inputted tocomputer214.
• Following each treatment, the differences between consecutive measurements of the various patient parameters are evaluated bycomputer214. After each treatment, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters by computer214:
• 1) If;
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm Hg;
• then,
• display216 shows the message “NO BRONCHOSPASM PRESENT.”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is more than or equal to 91% SAT but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed ondisplay216.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is less than 91% SAT; and
• c) ETCO₂is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is preferably displayed ondisplay216.
• The findings of the last stage are stored bycomputer214 and/or transmitted to a dispatch/receiving center, typically located at a hospital or medical center]. A connection is established with the dispatch/receiving center, and the data is forwarded thereto. A medical supervisor typically watches display of the received data, and consequentially transmits the recommended treatment and/or transport recommendations back to the ambulance.
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer214: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer214.
• 1) If:
• a) the difference in the run values is greater than 0.1 sec; and
• b) the difference in the slope is more negative than −15 mm Hg/sec;
• then,
• computer214 displays ondisplay216 “BRONCHOSPASM WORSENING”.
• 2) If:
• a) the difference in the run values is more negative than −0.1 sec; and
• b) the difference in the slope is more positive than +15 mm Hg/sec;
• then,
• computer214 displays ondisplay216 “BRONCHOSPASM IMPROVING”.
• 3) If:
• a) the difference in the slope is more than or equal to −15 mm Hg/sec and less than or equal to +15 mm Hg/sec;
• then,
• computer214 displays ondisplay216 “BRONCHOSPASM UNCHANGED”.
• The change in patient's vital functional activities, including SPO₂and ETCO₂, over the time interval are calculated bycomputer214.
• 4) If:
• a) the decrease in SPO₂is more negative than −5% SAT; or
• b) the increase in the ETCO₂is more positive than +5 mm Hg;
• then,
• computer214 displays ondisplay216 “VITAL SIGNS DETERIORATING.”
• 5) If:
• a) the change in SPO₂is greater than +5% SAT; or
• b) the change in the ETCO₂is more negative than −5 mm Hg;
• then,
• computer214 displays ondisplay216 “VITAL SIGNS IMPROVING”.
• 6) If:
• a) the change in SPO₂is greater than or equal to −5% SAT, but less than or equal to +5% SAT; or
• b) the change in the ETCO₂is more than or equal to −5 mm Hg, but less than or equal to +5 mm Hg;
• then,
• computer214 displays ondisplay216 “VITAL SIGNS UNCHANGED.”
• Computer214 preferably combines the results of these monitoring rules to display an integrated display such as “BRONCHOSPASM WORSENING; VITAL SIGNS UNCHANGED.”
• In a checking rule step, the following rule is preferably applied:
• 1) A patient appears to be entering respiratory failure phase if:
• a) the SPO₂is less than 90% SAT;
• b) the respiratory rate is less than 8/min;
• c) ETCO₂is greater than 60 mm Hg; and
• d) the patient's neurological symptoms are qualified as being “bad”;
• then,
• computer214 displays “RESPIRATORY FAILURE; CONDITION CRITICAL; CONSIDER INTUBATION.” ondisplay216.
• Following this, in an alert data transmission stage, a high priority update is transmitted viatransmitter218 fromcomputer214 to notify the dispatch/receiving centers of the significant deterioration and change in the patient's condition.
• Once these changes in the patient's condition have been confirmed by an operator, the patient is consequentially intubated according to standard techniques and capnograph202 is activated in intubation monitoring mode bycomputer214. Once the successful intubation of the patient is verified by data comparison of the patient's capnogram and standardized capnograms for incubation incomputer214, the computer displays “MONITORING FOR INTUBATION”.
• Thereafter, the following check rule is preferably applied to the patient's capnogram:
• 1. If:
• a) ETCO₂is greater than 15 mm Hg;
• then,
• computer214 displays “GOOD WAVEFORM, TUBE IN TRACHEA. CONFIRM AND SECURE TUBE.”
• In the next step, the following monitoring rules are preferably applied to the patient's capnogram:
• 1) If:
• a) the value of ETCO₂is greater than 15 mm Hg;
• then,
• computer214 displays “MONITORING TUBE POSITION: NO DISLODGEMENT” ondisplay216.
• 2) If:
• a) the value of ETCO₂is less than or equal to 15 mm Hg; or
• b) there is a loss of the waveform;
• then,
• computer214 displays “ALERT: CHECK FOR TUBE DISLODGEMENT” ondisplay216.
• Computer214 transmits the data monitored viatransmitter218 to the receiving center. The receiving center periodically receives updates of the patient's condition, who is in the ambulance en route to the hospital, in order to prepare in the most fitting and efficient transfer of the patient upon arrival to the hospital.
• A copy of the patient's record is handed off fromcomputer184 viatransmitter218 to the receiving center, for example, in the form of a chart. Typically, the receiving center stores this chart, so that it may be used as a baseline for continued monitoring of the patient.
• Reference is now made toFIG. 11, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in a hospital environment, such as a medical ward, emergency department or ICU, for detecting the presence and indicating the severity of bronchospasm, gauging the response to treatment and recommending treatment and disposition of spontaneously breathing patients. As seen inFIG. 11, in a hospital environment, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula220, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph222, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes224, afinger sensor226, a forehead/scalp sensor228 and ablood pressure cuff230 respectively.
• The outputs of thecapnograph222 and possibly ofadditional instrumentation230 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer232, having an associateddisplay234 which typically analyzes the respiration parameter output of thecapnograph222 and possibly other parameters and provides an output which preferably contains a diagnostic statement, here “ALERT: MODERATE BRONCHOSPASM PRESENT”. A breathing treatment is administered after which a diagnostic statement which indicates the patient status and the severity of the respiratory condition is preferably presented, here “GOOD RESPONSE TO TREATMENT, CONDITION IMPROVING”. Additional breathing treatment is typically administered after which a diagnostic statement which indicates the current patient status and the severity of the respiratory condition is preferably presented, here NO BRONCHOSPASM PRESENT, CONDITION STABLE”.
• Preferably, response to treatment statements as well as disposition recommendations may be appended to patient status statements, here “RAPID RESPONSE TO TREATMENT, CONDITION REMAINS STABLE, DISCHARGE TO HOME LIKELY”.
• Reference is now made additionally toFIG. 12, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 11. The patient in the hospital environment, preferably attached to a multi-parametermonitor including capnograph222 andinstrumentation230, by means ofcannula220 and preferably also by means ofchest electrodes230,finger sensor226, scalp/forehead sensor228 and blood pressure cuff236, is monitored continuously. The neurological status of the patient is acquired by any suitable technique. Values of CO₂concentration, ECG, NIBP and SPO₂are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram and other waveforms and stored.
• The parameter data may be digitized as waveforms and are further stored for analysis bycomputer232. Thereafter, the onset and offset limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer232. The heart rate, blood pressure ETCO₂and SPO₂values are measured. The initial slope of the capnogram and the run, monitored bycapnograph222, are calculated bycomputer232. Additionally, neurological findings, monitored by means of an EEG are inputted tocomputer232.
• Following each treatment, the differences between consecutive measurements of the various patient parameters are evaluated bycomputer232. After each treatment, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters by computer234:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm Hg;
• then,
• display234 shows the message “VITAL SIGNS WITHIN NORMAL LIMITS.”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is more than or equal to 91% SAT, but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed ondisplay234.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is less than 92% SAT; and
• c) ETCO₂is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is displayed ondisplay234.
• The findings of the last stage are stored bycomputer232 and/or transmitted to a dispatch/receiving center, typically located at a hospital or medical center. A connection is established with the dispatch/receiving center, and the data is forwarded thereto. A medical supervisor typically watches display of the received data, and consequentially transmits the recommended treatment and/or transport recommendations back to the hospital.
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer232: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer232.
• 1) If:
• a) the difference in the run values is greater than 0.1 sec; and
• b) the difference in the slope is less than −15 mm Hg/sec;
• then,
• computer232 displays ondisplay234 “BRONCHOSPASM WORSENING”.
• 2) If:
• a) the difference in the run values is more negative than −0.1 sec; and
• b) the difference in the slope is more than +15 mm Hg/sec;
• then,
• computer232 displays ondisplay234 “BRONCHOSPASM IMPROVING”.
• 3) If:
• a) the difference in the slope is greater than or equal to −15 mm Hg/sec, but less than or equal to +15 mm Hg/sec; and
• a) the difference in the run values is greater or equal to −0.1 sec; but less than or equal to +0.1 sec;
• then,
• computer232 displays ondisplay234 “BRONCHOSPASM UNCHANGED”.
• The change in patient's vital functional activities, including SPO₂and ETCO₂, over the time interval are calculated bycomputer232.
• 4) If:
• a) the change in SPO₂is greater than −5% SAT; or
• b) the change in the ETCO₂is more than +5 mm Hg;
• then,
• computer232 displays ondisplay234 “VITAL SIGNS DETERIORATING.”
• 5) If:
• a) the change in SPO₂is greater than +5% SAT; or
• b) the change in the ETCO₂is less than −5 mm Hg;
• then,
• computer232 displays ondisplay234 “VITAL SIGNS IMPROVING”.
• 6) If:
• a) the change in SPO₂is greater than or equal to −5% SAT, and less than or equal to +5% SAT; or
• b) the change in the ETCO₂is more than or equal to −5 mm Hg, but less than or equal to +5 mm Hg;
• then,
• computer232 displays ondisplay234 “VITAL SIGNS UNCHANGED.”
• Computer232 preferably combines the results of these monitoring rules to display anintegrated display234 such as “BRONCHOSPASM WORSENING; VITAL SIGNS UNCHANGED.”
• Following the monitoring stage, the following exit rules are preferably applied to the measured parameters of the patient by computer232:
• 1) If:
• a) the blood pressure values are within normal limits;
• b) the respiratory rate is within normal limits;
• c) the value of the CO₂run is less than 0.3 seconds;
• d) the CO₂slope is greater than 100 mm Hg/sec; and
• e) ETCO₂is less than 45 mm Hg;
• then,
• Computer232 preferably displays ondisplay234 “NO BRONCHOSPASM PRESENT”
• (If the patient's record complies with this exit rule, then a copy of the patient's record is handed off fromcomputer232 to the receiving center, for example, in the form of a chart. Typically, the receiving center stores this chart, so that it may be used as a baseline for continued monitoring of the patient).
• Reference is now made toFIG. 13, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of mechanically ventilated patients. As seen inFIG. 13 and similarly to that described hereinabove with reference toFIGS. 5 and 9, in a hospital environment, such as a medical ward, emergency department or ICU, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula250, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph252, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes254, afinger sensor256, a forehead/scalp sensor258 and ablood pressure cuff260 respectively, may also be sensed and measured bysuitable instrumentation262.
• The outputs of thecapnograph252 and preferably ofadditional instrumentation262 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer264 having an associateddisplay266, which typically analyzes the respiration parameter output of thecapnograph252 and preferably other physiologic activities and provides an output which preferably contains a diagnostic statement, here “ALERT: SEVERE BRONCHOSPASM PRESENT”.
• The patient is given breathing treatment, such as a beta agonist nebulizer treatment and following such treatment and/or in the course thereof, the physiologic activities of the patient continue to be monitored. This monitoring is employed bycomputer264 to indicate the response to the breathing treatment and the current status of the patient condition. In the scenario ofFIG. 13, the patient fails to respond sufficiently to the breathing treatment and this is indicated by a status change statement, here “POOR RESPONSE TO TREATMENT, CONDITION WORSENING”. A treatment recommendation may also be provided, such as “CONSIDER INTUBATION”.
• Intubation is performed and correct initial tube placement is confirmed followed by continuous monitoring of the physiologic activities of the patient, which indicate current tube position. Where intubation is successful, a status statement, here: “ADEQUATE CO2 WAVEFORM-TUBE IN TRACHEA” and a treatment recommendation, here “SECURE TUBE” appear. Where intubation is not successful, a status statement, here: “NO CO2 WAVEFORM-TUBE IN ESOPHAGUS” and a treatment recommendation, here “REINTUBATE” appear.
• Following successful intubation, continuous monitoring may provide a status statement such as “ADEQUATE CO2 WAVEFORM-TUBE IN TRACHEA-NO DISLOGEMENT” may appear. If tube dislodgment occurs at any time following intubation, a status statement appears, here “CO2 WAVEFORM ABSENT” preferably accompanied by a treatment recommendation, here “CHECK FOR TUBE DISLOGEMENT”.
• Preferably some or all of the outputs ofcomputer262 are transmitted in a wireless manner by a transmitter268, such as via radio or a cellular telephone link, preferably to a dispatch center or patient receiving facility.
• Reference is now made additionally toFIGS. 14A and 14B, which illustrate the operation of the system and methodology of the system of the present invention in the context ofFIG. 13.
• The patient in the hospital environment, preferably attached to a multi-parametermonitor including capnograph252 andinstrumentation262, by means ofcannula250 and preferably also by means ofchest electrodes254,finger sensor256, scalp/forehead sensor258 andblood pressure cuff260, is monitored continuously. The neurological status of the patient is acquired by any suitable technique. Values of CO₂concentration, ECG, NIBP and SPO₂are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram and other waveforms and stored bycomputer264.
• Thereafter, the onset and offset limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer264. The heart rate, blood pressure ETCO₂and SPO₂values are measured. The initial slope of the capnogram and the run, monitored bycapnograph252, are calculated bycomputer264. Additionally, neurological findings, monitored by means of an EEG are inputted tocomputer264.
• Following each treatment, the differences between consecutive measurements of the various patient parameters are evaluated bycomputer264. After each treatment, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters by computer264:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm, Hg;
• then,
• display266 shows the message “VITAL SIGNS WITHIN NORMAL LIMITS.”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is greater than or equal to 91% SAT, but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed ondisplay266.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is less than 91% SAT; and
• c) ETCO₂is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is displayed ondisplay266.
• The findings of the last stage are stored bycomputer264 and/or transmitted by transmitter268 to a dispatch/receiving center, typically located at a hospital or medical center. A connection is established with the dispatch/receiving center [ref. no], and the data is forwarded thereto. A medical supervisor typically watches display of the received data, and consequentially transmits the recommended treatment and/or transport recommendations back to the hospital.
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer264: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer264.
• 1) If:
• a) the difference in the run values is greater than +0.1 sec; and
• b) the difference in the slope is more negative than −15 mm Hg/sec;
• then,
• computer264 displays ondisplay266 “BRONCHOSPASM WORSENING”.
• 2) If:
• a) the difference in the run values is more negative than −0.1 sec; and
• b) the difference in the slope is more positive than +15 mm Hg/sec;
• then,
• computer264 displays ondisplay266 “BRONCHOSPASM IMPROVING”.
• 3) If:
• a) the difference in the run values is greater or equal to −0.1 sec but less than or equal to +0.1 sec; or
• b) the difference in the slope is more than or equal to −15 mm Hg/sec but less than or equal to +15 mm Hg/sec;
• then,
• computer264 displays ondisplay266 “BRONCHOSPASM UNCHANGED”.
• The change in patient's vital functional activities, including SPO₂and ETCO₂, over the time interval are calculated bycomputer264.
• 4) If:
• a) the change in SPO₂is greater than −5% SAT; or
• b) the change in the ETCO₂is more than +5 mm Hg;
• then,
• computer264 displays ondisplay266 “VITAL SIGNS DETERIORATING.”
• 5) If:
• a) the change in SPO₂is greater than +5% SAT; or
• b) the change in the ETCO₂is less than −5 mm Hg;
• then,
• computer264 displays ondisplay266 “VITAL SIGNS IMPROVING”.
• 6) If:
• a) the change in SPO₂is greater than or equal to −5% SAT, but less than or equal to +5% SAT; or
• b) the change in the ETCO₂is more than or equal to −5 mm Hg, but less than or equal to +5 mm Hg;
• then,
• computer264 displays ondisplay266 “VITAL SIGNS UNCHANGED.”
• Computer264 preferably combines the results of these monitoring rules to display anintegrated display266 such as “BRONCHOSPASM WORSENING; VITAL SIGNS UNCHANGED.”
• In a checking rule step, the following rule is preferably applied:
• 1) A patient appears to be entering respiratory failure phase if:
• a) the SPO₂is less than 90% SAT;
• b) the respiratory rate is less than 8/min;
• c) ETCO₂is greater than 60 mm Hg; and
• d) the patient's neurological symptoms are qualified as being “bad”;
• then,
• computer264 displays “RESPIRATORY FAILURE; CONDITION CRITICAL; CONSIDER INTUBATION.” ondisplay266.
• Once these changes in the patient's condition have been confirmed by an operator, the patient is consequentially intubated according to standard techniques andcapnograph252 is activated in intubation monitoring mode bycomputer264. Once the successful intubation of the patient is verified by data comparison of the patient's capnogram and standardized capnograms for intubation incomputer264, the computer displays “MONITORING FOR INTUBATION”.
• Thereafter, the following check rule is preferably applied to the patient's capnogram:
• 1. If:
• a) ETCO₂is greater than 15 mm Hg;
• then,
• computer264 displays “GOOD WAVEFORM, TUBE IN TRACHEA. CONFIRM AND SECURE TUBE.”
• In the next step, the following monitoring rules are preferably applied to the patient's capnogram:
• 1) If:
• a) the value of ETCO₂is greater than 15 mm Hg;
• then,
• computer266 displays “MONITORING TUBE POSITION: NO DISLODGEMENT” on display268.
• 2) If:
• a) the value of ETCO₂is less than or equal to 15 mm Hg; or
• b) there is a loss of the waveform;
• then,
• computer264 displays “ALERT: CHECK FOR TUBE DISLODGEMENT” ondisplay266.
• Reference is now made toFIG. 15, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in a hospital environment operative for distinguishing between heart failure and emphysema in a situation where a hospital patient becomes short of breath. As seen inFIG. 15, in a hospital environment, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula270, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph272, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes274, afinger sensor276, a forehead/scalp sensor278 and ablood pressure cuff280 respectively, may also be sensed and measured bysuitable instrumentation282.
• The outputs of thecapnograph272 and possibly ofadditional instrumentation282 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer284, having an associateddisplay286 which typically analyzes the respiration parameter output of thecapnograph272 and possibly other parameters and provides an output which preferably contains a diagnostic statement, here “SEVERE BRONCHOSPASM PRESENT”. This diagnostic statement would suggest treatment for emphysema rather than for heart failure. Breathing treatment is administered after which a diagnostic statement which indicates the patient status and the severity of the respiratory condition is preferably presented, here “MODERATE BRONCHOSPASM, CONDITION IMPROVING”
• Reference is now made additionally toFIGS. 16A and 16B, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 15.FIGS. 16A and 16B illustrate the utility of using the capnograph in both diagnostic and monitoring modes as an aid to diagnosis and monitoring respectively.
• The patient in the hospital environment, preferably attached to a multi-parametermonitor including capnograph272 and the suitable instrumentation, by means ofcannula270 and preferably also by means ofchest electrodes274,finger sensor276, forehead/scalp sensor278 andblood pressure cuff280, is monitored continuously. The neurological status of the patient is acquired by any suitable technique. Values of CO₂concentration, ECG, NIBP and SPO₂are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram and other waveforms and stored oncomputer284
• In the above exemplified scenario (FIG. 15), the medical team initially do not know whether the patient's symptoms are indicative of a breathing-related medical problem, such as emphysema, or from a heart related medical problem, such as heart failure. The following methodology assists and enables the medical team to reach the correct diagnosis. In contrast, inFIG. 11 above, there were no indications that the patient's diagnosis could include a heart-related episode.
• Thereafter, the onset and offset limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer284. The initial slope of the capnogram and the run are determined and stored incomputer284;
• At a startup stage,computer284 checks to verify that a valid signal is received fromcapnograph272. In a case where the signal is indicative of there being obstructive lung disease, due to the sluggish run time for example or an acute angled initial slope, then the mode of monitoring oncapnograph272 is shifted to its bronchospastic monitoring mode.
• In a monitoring rule stage, the following rule is preferably applied to the values of the end tidal value of exhaled carbon dioxide:
• 1) If:
• a) ETCO₂is greater than 15 mm Hg;
• then,
• computer284 displays ondisplay286 “GOOD WAVEFORM QUALITY; CRITERIA FOR BRONCHOSPASM MET: STARTING MONITORING”.
• Thereafter a cycle of alternating I) sampling step (data collection and measurement) and II) diagnostic rule application to the previous sample step I) is initiated.
• I) Sampling Step
• a) A sample of expired air is taken and conveyed fromcannula270 tocapnograph272.
• b) The carbon dioxide concentration is measured continuously bycapnograph272 as a capnogram.
• c) The capnogram is digitized as waveform and store for analysis bycomputer284.
• d)Computer284 marks onset and offset limits of the capnogram.
• e) The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• f) The slope and the run are determined bycomputer284.
• II) Diagnostic Rule Application Step
• In a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters of I) Sampling step by computer284:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm Hg;
• then,
• display286 shows the message “NO BROCHOSPASM PRESENT.”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is greater than or equal to 91% SAT, but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed ondisplay286.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is less than 91% SAT; and
• c) ETCO₂is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is displayed ondisplay286.
• At any one of the diagnostic rule application steps, it may be verified that the patient is suffering from bronchospasm. Once bronchospasm is verified, the operator switches capnograph272 to a serial comparison mode. The medical team applies the appropriate interventions to the patient to treat the bronchospasm.
• Thereafter, a cycle of alternating I) sampling step (data collection and measurement) and II) monitoring rule application step to the previous sample step I) is initiated.
• I) Sampling Step
• a) A sample of expired air is taken and conveyed fromcannula270 tocapnograph272.
• b) The carbon dioxide concentration is measured continuously bycapnograph272 as a capnogram.
• c) The capnogram is digitized as waveform and store for analysis bycomputer284.
• d)Computer284 marks onset and offset limits of the capnogram.
• e) The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• f) The slope and the run are determined bycomputer284.
• II) Monitoring Rule Application Step
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer284: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer284.
• 1) If:
• a) the difference in the run values is greater than 0.1 sec; and
• b) the difference in the slope is less than −15 mm Hg/sec;
• then,
• computer284 displays ondisplay286 “BRONCHOSPASM WORSENING”.
• 2) If:
• a) the difference in the run values is more negative than −0.1 sec; and
• b) the difference in the slope is more than +15 mm Hg/sec;
• then,
• computer284 displays ondisplay286 “BRONCHOSPASM IMPROVING”
• If:
• a) the difference in the run is more than or equal to −0.1 sec, but is less than or equal to 0.1 sec; or
• b) the difference in the slope is more than or equal to −15 mm Hg/sec and less than or equal to +15 mm Hg/sec;
• then,
• computer284 displays ondisplay286 “BRONCHOSPASM UNCHANGED”.
• The change in patient's vital functional activities, including SPO₂and ETCO₂, over the time interval are calculated bycomputer284.
• 4) If:
• a) the change in SPO₂is more negative than −5% SAT; or
• b) the change in the ETCO₂is more than +5 mm Hg;
• then,
• computer284 displays ondisplay286 “VITAL SIGNS DETERIORATING.”
• 5) If:
• a) the change in SPO₂is greater than +5% SAT; or
• b) the change in the ETCO₂is less than −5 mm Hg;
• then,
• computer284 displays ondisplay286 “VITAL SIGNS IMPROVING”.
• 6) If:
• a) the change in SPO₂is greater than or equal to −5% SAT, but less than or equal to +5% SAT; or
• b) the change in the ETCO₂is more than or equal to −5 mm Hg, but less than or equal to +5 mm Hg;
• then,
• computer284 displays ondisplay286 “VITAL SIGNS UNCHANGED.”
• Computer284 preferably combines the results of these monitoring rules to display anintegrated display286 such as “BRONCHOSPASM WORSENING; VITAL SIGNS UNCHANGED.”
• Once the medical interventions have concluded and the patient's disposition has been determined, the operator switches the capnograph back to its diagnostic mode.
• Reference is now made toFIG. 17, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in a hospital environment, operative for continuously monitoring correct tube position in an intubated patient. As seen inFIG. 17, in a hospital environment, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula300, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph302, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes304, afinger sensor306, a forehead/scalp sensor308 and ablood pressure cuff310 respectively, may also be sensed and measured bysuitable instrumentation312.
• The outputs of thecapnograph302 and possibly ofadditional instrumentation312 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer314, having an associateddisplay316 which typically analyzes the respiration parameter output of thecapnograph302 and possibly other parameters and provides an output which preferably contains a diagnostic statement, here “ALERT !!! LOSS OF CO₂WAVEFORM” preferably accompanied by a treatment recommendation, here CHECK FOR TUBE DISLODGEMENT”. Following re-intubation, a revised diagnostic statement, here “CO₂WAVEFORM RESTORED, TUBE IN TRACHEA”, preferably accompanied by a treatment recommendation, here “SECURE TUBE” appears.
• Reference is now made additionally toFIG. 18, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 17.
• The patient in the hospital environment, preferably attached to a multi-parametermonitor including capnograph302 andinstrumentation312, by means ofcannula200 and preferably also by means ofchest electrodes304,finger sensor306, forehead/scalp sensor308 andblood pressure cuff310, is monitored continuously. The neurological status of the patient is acquired by any suitable technique. Expired air is collected viacannula300 and is conveyed to thecapnograph302.
• Values of CO₂concentration, ECG, NIBP and SPO₂are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram and together with other waveforms are stored oncomputer314.
• The onset and offset limits of the patient's capnogram fromcapnograph302 are delineated bycomputer314.
• The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 1 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• If the quality is unacceptable, further samples are collected until a sample of acceptable quality, according to the above two criteria, is taken.
• The next step entails a checking procedure, wherein the ETCO₂value is measured bycapnograph302.
• The following checking rule is preferably applied.
• 1) If:
• a) the ETCO₂value is more than 15 mm Hg;
• then,
• a display is provided bycomputer314 stating “GOOD WAVEFORM, TUBE IN TRACHEA, CONFIRM AND SECURE TUBE” ondisplay316.
• If the intubation is successful, the operator confirms this, by for example, entering the relevant code intocomputer314, andcapnograph302 is then entered into an intubation monitoring mode. The patient is monitored continuously. Thus,computer314 displays “MONITORING INTUBATION” ondisplay316.
• If there is a loss of the signal fromcapnograph302, it may be indicative that thecannula tube300 has slipped away from the patient's trachea In such a case, the computer preferably displays “ALERT: CHECK FOR TUBE DISLODGEMENT”.
• Thereafter a cycle of alternating I) sampling step (data collection and measurement) and II) diagnostic rule application to the previous sample step I) is initiated.
• I) Sampling Step
• In this sampling step, an exhaled air sample fromcannula300 is periodically collected, conveyed and measured bycapnograph302. The carbon dioxide concentration value is determined continuously bycapnograph302.Computer314 digitizes the capnograph signals as a waveform and store the waveform for analysis.
• Thereafter, the ETCO₂value is determined.
• II) Diagnostic Rule Application Step.
• The following diagnostic rules are applied to each sample:
• 1) If:
• a) The value of ETCO₂is greater or equal to 15 mm Hg; and
• b) There is no loss in the waveform fromcapnograph302; then,
• computer314 displays “MONITORING TUBE POSITION: NO DISLODGMENT” ondisplay316.
• 2) If:
• a) The value of ETCO₂is less than or equal to 15 mm Hg; or
• b) There is a loss in the waveform fromcapnograph302,
• then,
• computer314 displays “ALERT: CHECK FOR TUBE DISLODGMENT” ondisplay316.
• This cycle typically proceeds until the patient monitoring is halted by the medical team or operator.
• Reference is now made toFIG. 19, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology, operative in a hospital environment, for continuously monitoring the respiratory status of a spontaneously breathing patient in first operational scenario. As seen inFIG. 19, in a hospital environment, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula330, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph332, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes334, afinger sensor336, a forehead/scalp sensor338 and ablood pressure cuff340 respectively, may also be sensed and measured bysuitable instrumentation342.
• The outputs of thecapnograph332 and possibly ofadditional instrumentation342 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer344, having an associateddisplay346 which typically analyzes the respiration parameter output of thecapnograph332 and possibly other parameters and provides an output which preferably contains a diagnostic statement, here “PATIENT STABLE-NO CHANGE IN CLINICAL PARAMETERS. If a change occurs in the patient respiratory status, a diagnostic statement, here “ALERT: MILD BRONCHOSPASM PRESENT” appears on thedisplay346, indicating to medical personnel that a bronchospastic condition is present. Following administration of breathing treatment, an updated diagnostic statement appears, here “GOOD RESPONSE TO TREATMENT, NO BRONCHOSPASM PRESENT”.
• Reference is now made additionally toFIG. 20, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 19.
• The patient in the hospital environment, preferably attached to a multi-parametermonitor including capnograph332 andinstrumentation342, by means of cannula330 and preferably also by means ofchest electrodes334,finger sensor336, forehead/scalp sensor338 andblood pressure cuff340, is monitored continuously. The neurological status of the patient is acquired by any suitable technique. Expired air is collected viacannula300 and is conveyed to thecapnograph332.
• Values of CO₂concentration, ECG, NIBP and SPO₂are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram and together with other waveforms are stored oncomputer344.
• The onset and offset limits of the patient's capnogram fromcapnograph332 are delineated bycomputer344.
• The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• If the quality is unacceptable, further samples are collected until a sample of acceptable quality, according to the above two criteria, is taken.
• The next step entails a checking procedure, wherein the ETCO₂value is measured bycapnograph332. The slope and run values of the capnogram fromcapnograph332 are determined bycomputer344.
• At startup, the following checking rule is preferably applied.
• 1) If
• a) the ETCO₂value is more than 15 mm Hg;
• then,
• a display is provided bycomputer344 stating “GOOD WAVEFORM, QUALITY: MONITORING FOR BRONCHOSPASM”.
• If the monitoring is successful, the operator confirms this, by for example, entering the relevant code intocomputer344, andcapnograph332 is then entered into a diagnostic monitoring mode. The patient is monitored continuously bycapnograph332.
• Thereafter a cycle of alternating I) sampling step (data collection and measurement) and II) diagnostic rule application to the previous sample step I) is initiated.
• I) Sampling Step
• a) A sample of expired air is taken and conveyed from cannula330 tocapnograph332.
• b) The carbon dioxide concentration is measured continuously bycapnograph332 as a capnogram.
• c) The capnogram is digitized as waveform and store for analysis bycomputer344.
• d)Computer344 marks onset and offset limits of the capnogram.
• e) The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• 1) The slope and the run are determined bycomputer344.
• II) Diagnostic Rule Application Step
• In a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters of I) Sampling step by computer344:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm Hg; then,
• display346 shows the message “NO BRONCHOSPASM PRESENT.”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is greater or equal to 91% SAT, but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed ondisplay346. The patient then receives suitable breathing treatment as is shown inFIG. 19 hereinabove.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is less than 91% SAT; and
• c) ETCO₂is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is displayed ondisplay346.
• Reference is now made toFIGS. 21A and 21B, which are simplified pictorial illustrations of an automatic medical diagnostic and treatment system and methodology, operative in a hospital environment, for continuously monitoring the respiratory status of a spontaneously breathing patient in a second clinical scenario. As seen inFIGS. 21A and 21B, in a hospital environment, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula350, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph352, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g.; pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes354, afinger sensor356, a forehead/scalp sensor358 and ablood pressure cuff360 respectively, may also be sensed and measured bysuitable instrumentation362.
• The outputs of thecapnograph352 and possibly ofadditional instrumentation362 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer364, having an associateddisplay366 which typically analyzes the respiration parameter output of thecapnograph352 and possibly other parameters and provides an output which preferably contains a diagnostic statement, here “PATIENT STABLE-NO CHANGE IN CLINICAL PARAMETERS. If a change occurs in the patient respiratory status, a diagnostic statement, here “ALERT: MILD BRONCHOSPASM PRESENT” appears on thedisplay346, indicating to medical personnel that a bronchospastic condition is present. Following administration of breathing treatment, an updated diagnostic statement appears, here “NO RESPONSE TO TREATMENT, MODERATE BRONCHOSPASM PRESENT”. Additional breathing treatment is administered and thereafter an updated diagnostic statement appears, here “NO RESPONSE TO TREATMENT, SEVERE BRONCHOSPASM PRESENT”, which may prompt the physician to transfer the patient to the ICU.
• Reference is now made additionally toFIGS. 22A-22C, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIGS. 21A and 21B.
• The patient in the hospital environment, preferably attached to a multi-parametermonitor including capnograph352, is monitored continuously for at least 30 seconds. Expired air is collected viacannula350 and is conveyed to thecapnograph352.
• Values of the CO₂concentration is continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram and together with other waveforms are stored oncomputer364.
• The onset and offset limits of the patient's capnogram fromcapnograph352 are delineated bycomputer364.
• The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• If the quality is unacceptable, further samples are collected until a sample of acceptable quality, according to the above two criteria, is taken.
• The next step entails a checking procedure, wherein the ETCO₂value is measured bycapnograph352. The slope and run values of the capnogram fromcapnograph352 are determined bycomputer364.
• At startup, the following checking rule is preferably applied.
• 1) If:
• a) the ETCO₂value is more than 15 mm Hg;
• then,
• a display is provided bycomputer364 stating “GOOD WAVEFORM, QUALITY: MONITORING FOR BRONCHOSPASM”.
• If the monitoring is successful, the operator confirms this, by for example, entering the relevant code intocomputer364, andcapnograph352 is then entered into a diagnostic monitoring mode. The patient is monitored continuously bycapnograph352.
• Thereafter a cycle of alternating I) sampling step (data collection and measurement) and II) diagnostic rule application to the previous sample step I) is initiated.
• I) Sampling Step
• a) A sample of expired air is taken and conveyed fromcannula350 tocapnograph352.
• b) The carbon dioxide concentration is measured continuously bycapnograph352 as a capnogram.
• c) The capnogram is digitized as waveform and store for analysis bycomputer364.
• d)Computer364 marks onset and offset limits of the capnogram.
• e) The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• f) The slope and the run are determined bycomputer364.
• II) Diagnostic Rule Application Step
• In a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters of I) Sampling step by computer364:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than 45 mm Hg;
• then,
• display366 shows the message “NO BRONCHOSPASM PRESENT.”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is greater than or equal to 91% SAT, but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed ondisplay366.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is less than 91% SAT; and
• c) ETCO₂is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is displayed ondisplay366.
• At any one of the diagnostic rule application steps, it may be verified that the patient is suffering from bronchospasm. Once bronchospasm is verified, the operator switches capnograph352 to a serial comparison mode. The medical team applies the appropriate interventions to the patient to treat the bronchospasm.
• The patient is attached multi-parameter monitor leads andinstrumentation362, by means ofcannula350 and preferably also by means ofchest electrodes354,finger sensor356, forehead/scalp sensor358 andblood pressure cuff360, is monitored continuously. The neurological status of the patient is acquired by any suitable technique.
• Values of the CO₂concentration monitored bycapnograph352, and ECG, NIBP, cerebral oximetry and SPO₂values, monitored byadditional instrumentation362 are supplied tocomputer364, and are typically measured continuously over a period of 30 seconds, by techniques as detailed hereinabove. The parameter data may be digitized as waveforms and are further stored for analysis bycomputer364. Thereafter, the limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer364.
• The next step entails a checking procedure, wherein the ETCO₂value is measured bycapnograph352. The initial slope of the capnogram and the run, monitored bycapnograph352, are calculated bycomputer364.
• At startup, the following checking rule is preferably applied.
• 1) If:
• a) the ETCO₂value is more than 15 mm Hg;
• then,
• a display is provided bycomputer344 stating “GOOD WAVEFORM, QUALITY: MONITORING FOR BRONCHOSPASM”.
• If the monitoring is successful, the operator confirms this, by for example, entering the relevant code intocomputer364, andcapnograph352 is then entered into a diagnostic monitoring mode. The patient is monitored continuously bycapnograph352.
• Thereafter, a cycle of alternating I) sampling step (data collection and measurement) and II) monitoring rule application step to the previous sample step I) is initiated.
• I) Sampling Step
• a) A sample of expired air is taken and conveyed fromcannula350 tocapnograph352.
• b) The carbon dioxide concentration is measured continuously bycapnograph352 as a capnogram.
• c) The capnogram is digitized as waveform and store for analysis bycomputer364.
• d)Computer364 marks onset and offset limits of the capnogram.
• e) The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• f) The slope and the run are determined bycomputer364.
• II) Monitoring Rule Application Step
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer364: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer364.
• 1) If:
• a) the difference in the run values is greater than +0.1 sec; and
• b) the difference in the slope is more negative than −15 mm Hg/sec;
• then,
• computer364 displays ondisplay366 “BRONCHOSPASM WORSENING”.
• 2) If:
• a) the difference in the run values is more negative than −0.1 sec; and
• b) the difference in the slope is more than +15 mm Hg/sec;
• then,
• computer364 displays ondisplay366 “BRONCHOSPASM IMPROVING”.
• 3) If:
• a) the difference in the run values is equal to or greater than −0.1 sec, but less than or equal to +0.1 sec; or
• b) the difference in the slope is more than or equal to −15 mm Hg but less than or equal to +15 mm Hg/sec;
• then,
• computer364 displays ondisplay366 “BRONCHOSPASM UNCHANGED”.
• The change in patient's vital functional activities, including SPO₂and ETCO₂, over the time interval are calculated bycomputer364.
• 4 If:
• a) the decrease in SPO₂is more than −5% SAT; or
• b) the increase in the ETCO₂is more than 5 mm Hg;
• then,
• computer364 displays ondisplay366 “VITAL SIGNS DETERIORATING.”
• 5) If:
• a) the increase in SPO₂is more than 5% SAT; or
• b) the decrease in the ETCO₂is greater than −5 mm Hg;
• then,
• computer364 displays ondisplay366 “VITAL SIGNS IMPROVING”.
• 6) If:
• a) the change in SPO₂is greater than or equal to −5% SAT but less than or equal to +5% SAT; or
• b) the change in the ETCO₂is more than or equal to −5 mm Hg or less than or equal to +5 mm Hg;
• then,
• computer364 displays ondisplay366 “VITAL SIGNS UNCHANGED”.
• Computer364 preferably combines the results of these monitoring rules to display anintegrated display366 such as “BRONCHOSPASM WORSENING; VITAL SIGNS UNCHANGED.”
• Once the medical interventions have concluded and the patient's disposition has been determined, the operator switches the capnograph back to its diagnostic mode.
• Reference is now made toFIGS. 23A and 23B, which are simplified pictorial illustrations of an automatic medical diagnostic and treatment system and methodology operative in a physician's office environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of a spontaneously breathing patient in a first clinical scenario. As seen inFIGS. 23A and 23B, a child having an asthma attack is brought to a physician's office. Various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula400, such as a Model NasalFilterLine Adult XS 04461, 02/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph402, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes404, afinger sensor406, a forehead/scalp sensor408 and ablood pressure cuff410 respectively, may also be sensed and measured bysuitable instrumentation412.
• The outputs of thecapnograph402 and preferably ofadditional instrumentation404 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer416 having an associateddisplay418, which typically analyzes the respiration parameter output of thecapnograph402 and preferably other physiologic activities and provides an output which preferably contains a diagnostic statement, here “MODERATE BRONCHOSPASM PRESENT”.
• The patient is given breathing treatments, such as beta agonist nebulizer treatments and following such treatments and/or in the course thereof, the physiologic activities of the patient continue to be monitored. This monitoring is employed bycomputer160 to indicate the response to the breathing treatments and the current status of the bronchospasm condition. When the breathing treatments are successful, a status message, here “GOOD RESPONSE TO TREATMENT”, is presented accompanied by a disposition recommendation, here “CONSIDER DISCHARGE TO HOME” and the physician may allow the child to return home after the treatment.
• Reference is now made additionally toFIGS. 24A and 24B, which illustrate the operation of the system and methodology of the system of the present invention in the context ofFIGS. 23A and 23B.
• The patient in the clinical environment, preferably attached to a multi-parametermonitor including capnograph402, is monitored continuously for at least 30 seconds. Expired air is collected viacannula400 and is conveyed to thecapnograph402.
• Values of the CO₂concentration is continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram and together with other waveforms are stored oncomputer416.
• The onset and offset limits of the patient's capnogram fromcapnograph402 are delineated bycomputer416.
• The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• If the quality is unacceptable, further samples are collected until a sample of acceptable quality, according to the above two criteria, is taken.
• The next step entails a checking procedure, wherein the ETCO₂value is measured bycapnograph402. The slope and run values of the capnogram fromcapnograph402 are determined bycomputer416.
• At startup, the following checking rule is preferably applied.
• 1) If:
• a) the ETCO₂value is more than 15 mm Hg;
• then,
• a display is provided bycomputer416 stating “GOOD WAVEFORM, QUALITY: MONITORING FOR BRONCHOSPASM”.
• If the monitoring is successful, the operator confirms this, by for example, entering the relevant code intocomputer416, andcapnograph402 is then entered into a diagnostic monitoring mode. The patient is monitored continuously bycapnograph402.
• Thereafter a cycle of alternating I) sampling step (data collection and measurement) and II) diagnostic rule application to the previous sample step I) is initiated. The sampling step is typically performed every 15 minutes for one hour after the treatment.
• I) Sampling Step
• a) A sample of expired air is taken and conveyed from cannula.400 tocapnograph402.
• b) The carbon dioxide concentration is measured continuously bycapnograph402 as a capnogram417.
• c) The capnogram is digitized as waveform and store for analysis bycomputer416.
• d)Computer416 marks onset and offset limits of the capnogram.
• e) The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• f) The slope and the run are determined bycomputer416.
• II) Diagnostic Rule Application Step
• In a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters of I) Sampling step by computer416:
• I) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm Hg;
• then,
• display418 shows the message “NO BRONCHOSPASM PRESENT.”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is more than or equal to 91% SAT, but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed ondisplay418.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is less than 91% SAT; and
• c) ETCO₂is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is displayed ondisplay418.
• At any one of the diagnostic rule application steps, it may be verified that the patient is suffering from bronchospasm. Once bronchospasm is verified, the operator switches capnograph402 to a serial comparison mode. The medical team applies the appropriate interventions to the patient to treat the bronchospasm.
• The following rule is preferably applied to the capnogram by computer416:
• i) If:
• a) the value of CAP-FEV1 is greater than 50%; and
• b) the slope is greater or equal to 100 mm Hg/sec; and,
• c) the angle of rise of the carbon dioxide concentration is greater than a predetermined value in degrees
• then,
• computer416 displays a message on display418: “GOOD RESPONSE TO TREATMENT: CONSIDER DISCHARGE HOME.”
• Reference is now made toFIGS. 25A and 25B, which are simplified pictorial illustrations of an automatic medical diagnostic and treatment system and methodology operative in a physician's office environment for detecting the presence and severity of bronchospasm, gauging the response to treatment and recommending disposition of a spontaneously breathing patient in a second clinical scenario. As seen inFIGS. 25A and 25B, a child having an asthma attack is brought to a physician's office. Various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula420, such as a Model NasalFilterLine Adult XS 04461, 02/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414′, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph422, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiological activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes424, afinger sensor426, a forehead/scalp sensor428 and ablood pressure cuff430 respectively, may also be sensed and measured bysuitable instrumentation432.
• The outputs of thecapnograph422 and preferably ofadditional instrumentation424 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer426 having an associateddisplay428, which typically analyzes the respiration parameter output of thecapnograph422 and preferably other physiologic activities and provides an output which preferably contains a diagnostic statement, here “MODERATE BRONCHOSPASM PRESENT”.
• The patient is given breathing treatments, such as beta agonist nebulizer treatments and following such treatments and/or in the course thereof, the physiologic activities of the patient continue to be monitored. This monitoring is employed bycomputer426 to indicate the response to the breathing treatments and the current status of the bronchospasm condition. When the breathing treatments are not successful, a status message, here “POOR RESPONSE TO TREATMENT”, is presented accompanied by a disposition recommendation, here “CONSIDER ADMISSION TO HOSPITAL” and the physician may send the child to the hospital.
• Reference is now made additionally toFIGS. 26A and 26B, which illustrate the operation of the system and methodology of the system of the present invention in the context ofFIGS. 25A and 25B.
• The patient in the clinical environment, preferably attached to a multi-parametermonitor including capnograph422, is monitored continuously for at least 30 seconds. Expired air is collected viacannula420 and is conveyed to thecapnograph422.
• Values of the CO₂concentration is continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram and together with other waveforms are stored oncomputer426.
• The onset and offset limits of the patient's capnogram fromcapnograph422 are delineated bycomputer426.
• The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• If the quality is unacceptable, further samples are collected until a sample of acceptable quality, according to the above two criteria, is taken.
• The next step entails a checking procedure, wherein the ETCO₂value is measured bycapnograph422. The slope and run values of the capnogram fromcapnograph422 are determined bycomputer426.
• At startup, the following checking rule is preferably applied.
• 1) If:
• a) the ETCO₂value is more than 15 mm Hg;
• then,
• a display is provided bycomputer426 stating “GOOD WAVEFORM, QUALITY: MONITORING FOR BRONCHOSPASM”.
• If the monitoring is successful, the operator confirms this, by for example, entering the relevant code intocomputer426, andcapnograph422 is then entered into a diagnostic monitoring mode. The patient is monitored continuously bycapnograph422.
• Thereafter a cycle of alternating I) sampling step (data collection and measurement) and II) diagnostic rule application to the previous sample step I) is initiated. The sampling step is typically performed every 15 minutes for one hour after the treatment.
• I) Sampling Step
• a) A sample of expired air is taken and conveyed fromcannula420 tocapnograph422.
• b) The carbon dioxide concentration is measured continuously bycapnograph422 as a capnogram.
• c) The capnogram is digitized as waveform and store for analysis bycomputer426.
• d)Computer426 marks onset and offset limits of the capnogram.
• e) The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• f) The slope and the run are determined bycomputer426.
• II) Diagnostic Rule Application Step
• In a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters of I) Sampling step by computer426:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm Hg;
• then,
• display428 shows the message “NO BRONCHOSPASM PRESENT.”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• C) SPO₂is greater than or equal to 91% SAT, but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed ondisplay428.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is less than 91% SAT; and
• c) ETCO₂is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is displayed ondisplay428.
• At any one of the diagnostic rule application steps, it may be verified that the patient is suffering from bronchospasm. Once bronchospasm is verified, the operator switches capnograph422 to a serial comparison mode. The medical team applies the appropriate interventions to the patient to treat the bronchospasm.
• The following rule is preferably applied to the capnogram by computer426:
• 1) If:
• a) the value of CAP-FEV 1 is less than 50%; and
• b) the slope is less than 100 mm Hg/sec; and,
• c) the angle of rise of the carbon dioxide concentration is less than a predetermined value in degrees;
• then,
• computer426 displays a message on display428: “POOR RESPONSE TO TREATMENT: CONSIDER ADMISSION TO HOSPITAL INTENSIVE CARE.”
• Reference is now made toFIGS. 27A and 27B, which are simplified pictorial illustrations of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for detecting the presence and severity of bronchospasm from an allergic reaction, gauging the response to treatment and recommending disposition. As seen inFIGS. 27A and 27B, a child complains of difficulty breathing. The parent summons an ambulance and similarly to that described hereinabove with reference toFIG. 9, in an ambulance environment various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula450, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph452, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes454, afinger sensor456, a forehead/scalp sensor458 and ablood pressure cuff460 respectively, may also be sensed and measured by suitable instrumentation462. Other patient physiologic activities relating to cardiac function (e.g. ECG), cerebral perfusion (e.g. CEREBRAL OXIMETRY), oxygenation (e.g. pulse oximetry) and systemic circulation (e.g. NIBP), may also be sensed and measured by suitable instrumentation462.
• The outputs of thecapnograph452 and preferably of additional instrumentation462 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer464 having an associateddisplay466, which typically analyzes the respiration parameter output of thecapnograph452 and preferably other physiologic activities and provides an output which preferably contains a diagnostic statement indicating the presence of lower airway obstruction, here “ALERT: MODERATE BRONCHOSPASM PRESENT”. The presence of bronchospasm definitively indicates lower airway obstruction.
• The patient is given breathing treatment, such as a beta agonist nebulizer treatment and following such treatment and/or in the course thereof, the physiologic activities of the patient continue to be monitored. This monitoring is employed bycomputer464 to indicate the response to the breathing treatment and the current status of the patient condition. In the scenario ofFIGS. 14A and 14B, the patient fails to respond sufficiently to the breathing treatment and this is indicated by a status change statement, here “POOR RESPONSE TO TREATMENT, CONDITION CRITICAL”. A treatment recommendation may also be provided, such as “CONSIDER INTUBATION”.
• Intubation is performed and correct initial tube placement is confirmed followed by continuous monitoring of the physiologic activities of the patient, which indicate current tube position. In this scenario, where intubation is successful, a status statement, here: “ADEQUATE CO₂WAVEFORM-TUBE IN TRACHEA” and a treatment recommendation, here “SECURE TUBE” appear.
• Following successful intubation, continuous monitoring may provide a status statement such as “ADEQUATE CO₂WAVEFORM-TUBE IN TRACHEA-NO DISLOGEMENT”. If tube dislodgment occurs at any time following intubation, a status statement would appear, such as “CO₂WAVEFORM ABSENT” preferably accompanied by a treatment recommendation, such as “CHECK FOR TUBE DISLOGEMENT”.
• Preferably some or all of the outputs ofcomputer464 are transmitted in a wireless manner by a transmitter468, such as via radio or a cellular telephone link, preferably to a dispatch center or patient receiving facility.
• Reference is now made additionally toFIG. 28, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIGS. 27A and 27B.FIG. 28 illustrates an example of the system and methodology applied to assessing whether a patient has an upper or lower airway obstruction, in the duration of the patient being transferred by ambulance.
• In the scenario described inFIGS. 27A and 27B hereinabove, it is presumed that the patient may be having an allergic reaction. The operator switchescapnograph452 into an assessing mode so as to enable an assessment to be made whether and if the patient has an upper or a lower airway disorder.
• The patient previously attached to a multi-parameter monitor including acapnograph452 and suitable instrumentation462, by means ofcannula450 and preferably also by means ofchest electrodes454,finger sensor456,forehead sensor458 andblood pressure cuff460, is monitored continuously for at least thirty seconds. Neurological status of the patient is acquired by any suitable technique, including visual and electroencephalograph (EEG) monitoring. Values of CO₂concentration, ECG, NIBP and (the percent saturation of the hemoglobin molecule with oxygen) SPO₂are continuously monitored, and carbon dioxide waveforms are preferably digitized as acapnogram452 and together with other waveforms are stored incomputer464.
• At least one expired air sample is collected and conveyed for analysis bycapnograph452. The outputs of thecapnograph452 and possibly of additional instrumentation462 are preferably supplied to suitably programmed automatic diagnostic andtreatment computer464, having associateddisplay466, which typically analyzes the respiration parameter output of thecapnograph452.
• In an analyzing step, the onset and offset limits of a capnogram469, pulse waveforms, and the QRS complex (of the ECG) are marked bycomputer464. The actual parameters measured include, but are not limited to heart rate (HR), BP, the systolic to diastolic ratio (SYS/DIA). SPO₂, AND ETCO₂. The slope of CO₂(mm Hg/sec), and CO₂“run”, of the capnogram469, measured to 80% of maximum CO₂concentration, are calculated bycomputer464.
• Following each treatment, the differences between consecutive measurements of the various patient parameters are computed bycomputer464. Thereafter, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters by computer464:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal; and
• c) ETCO₂is less than 45 mm Hg;
• then,
• display466 shows the message “VITAL SIGNS STABLE”.
• 2) In contrast, if:
• 1) If:
• a) the blood pressure values are not within the normal range;
• b) the respiratory rate is not normal; and
• c) ETCO₂is more than or equal to 45 mm Hg;
• then,
• display466 shows the message “RESPIRATORY IMPAIRMENT”.
• Additionally, the following rules may also be applied:
• 3) If:
• a) CO₂run is less than or equal to 0.3 sec; and
• b) CO₂slope is more than or equal to 100 mm Hg/sec;
• then,
• display466 shows the message “NO BRONCHOSPASM PRESENT: CONSIDER UPPER AIRWAY OBSTRUCTION”.
• 4) If:
• a) CO₂run is more than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• then,
• display466 shows the message “BRONCHOSPASM PRESENT: CONSIDER LOWER AIRWAY OBSTRUCTION”.
• The findings of the last stage are stored bycomputer464 and/or transmitted via transmitter468 to a dispatch/receiving center, typically located at a hospital or medical center. A connection is established with the dispatch/receiving center, and the data is forwarded thereto. A medical supervisor typically watches display of the received data, and consequentially transmits the recommended treatment and/or transport recommendations back to the ambulance.
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer464: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer464.
• 1) If:
• a) the difference in the run values is greater than +0.1 sec; and
• b) the difference in the slope is more negative than −15 mm Hg/sec; then,
• computer464 displays ondisplay466 “BRONCHOSPASM WORSENING”.
• 2) If:
• a) the difference in the run values is more negative than −0.1 sec; and
• b) the difference in the slope is more positive than +15 mm Hg/sec;
• then,
• computer464 displays ondisplay466 “BRONCHOSPASM IMPROVING”.
• 3) If:
• a) the difference in the run is greater or equal to −0.1 sec, but less than or equal to +0.1 Sec; or
• b) the difference in the slope is more than or equal to −15 mm Hg/sec and less than or equal to +15 mm Hg/sec;
• then,
• computer464 displays ondisplay466 “BRONCHOSPASM UNCHANGED”.
• The change in patient's vital functional activities, including SPO₂and ETCO₂, over the time interval are calculated bycomputer464.
• 4) If:
• a) the decrease in SPO₂is more negative than −5% SAT; or
• b) the increase in the ETCO₂is more than +5 mm Hg;
• then,
• computer184 displays ondisplay186 “VITAL SIGNS DETERIORATING.”
• 5) If:
• a) the increase in SPO₂is more than +5% SAT; or
• b) the decrease in the ETCO₂is more than −5 nm Hg;
• then,
• computer464 displays ondisplay466 “VITAL SIGNS IMPROVING”.
• 6) If:
• a) the change in SPO₂is greater than or equal to −5% SAT, but less than or equal to +5% SAT, or
• b) the change in the ETCO₂is more than or equal to −5 mm Hg, but less than or equal to +5 mm Hg;
• then,
• computer464 displays ondisplay466 “VITAL SIGNS UNCHANGED.”
• Computer464 preferably combines the results of these monitoring rules to display anintegrated display466 such as “BRONCHOSPASM WORSENING; VITAL SIGNS UNCHANGED.”
• In a checking rule step, the following rule is preferably applied:
• 1) A patient appears to be entering respiratory failure phase if:
• a) the SPO₂is less than 90% SAT;
• b) the respiratory rate is less than 8/min;
• c) ETCO₂is greater than 60 mm Hg; and
• d) the patient's neurological symptoms are qualified as being “bad”;
• then,
• computer464 displays “RESPIRATORY FAILURE; CONDITION CRITICAL; CONSIDER INTUBATION.” ondisplay466.
• Following this, in an alert data transmission stage, a high priority update is transmitted via transmitter468 fromcomputer464 to notify the dispatch/receiving centers of the significant deterioration and change in the patient's condition.
• Once these changes in the patient's condition have been confirmed by an operator, the patient is consequentially intubated according to standard techniques andcapnograph452 is activated in intubation monitoring mode bycomputer464. Once the successful intubation of the patient is verified by data comparison of the patient's capnogram and standardized capnograms for intubation incomputer464, the computer displays “MONITORING FOR INTUBATION”.
• Thereafter, the following check rule is preferably applied to the patient's capnogram:
• 1. If:
• a) ETCO₂is greater than 15 mm Hg;
• then
• computer464 displays “GOOD WAVEFORM, TUBE IN TRACHEA. CONFIRM AND SECURE TUBE.”
• In the next step, the following monitoring rules are preferably applied to the patient's capnogram:
• 1) If:
• a) the value of ETCO₂is greater than 15 mm Hg;
• then,
• computer214 displays “MONITORING TUBE POSITION: NO DISLODGEMENT” ondisplay216.
• 2) If:
• a) the value of ETCO₂is less than or equal to 15 mm Hg; or
• b) there is a loss of the waveform;
• then,
• computer464 displays “ALERT: CHECK FOR TUBE DISLODGEMENT” ondisplay466.
• Computer464 transmits the data monitored via transmitter468 to the receiving center. The receiving center periodically receives updates of the patient's condition, who is in the ambulance en route to the hospital, in order to prepare in the most fitting and efficient transfer of the patient upon arrival to the hospital.
• A copy of the patient's record is handed off fromcomputer464 via transmitter468 to the receiving center, for example, in the form of a chart. Typically, the receiving center stores this chart, so that it may be used as a baseline for continued monitoring of the patient.
• Reference is now made toFIG. 29, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology in an ambulance environment for distinguishing between upper airway obstruction and lower airway obstruction, such as distinguishing between asthma and croup, bronchiolitis and croup, and allergic reactions affecting the upper or lower airways. As seen inFIG. 29, a person complains of difficulty breathing. An ambulance is summoned and similarly to that described hereinabove with reference toFIG. 17, in an ambulance environment various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula470, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph472, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes474, afinger sensor476, a forehead/scalp sensor478 and ablood pressure cuff480 respectively, may also be sensed and measured bysuitable instrumentation482. Other patient physiologic activities relating to cardiac function (e.g. ECG), cerebral perfusion (e.g. CEREBRAL OXIMETRY), oxygenation (e.g. pulse oximetry) and systemic circulation (e.g. NIBP), may also be sensed and measured bysuitable instrumentation482.
• The outputs of thecapnograph472 and preferably ofadditional instrumentation482 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer484 having an associateddisplay486, which typically analyzes the respiration parameter output of thecapnograph472 and preferably other physiologic activities and provides an output which preferably contains a diagnostic statement differentiating upper airway obstruction from lower airway obstruction, here “ELEVATED RESPIRATORY RATE. NO BRONCHOSPASM PRESENT”. The absence of bronchospasm in this scenario strongly suggests upper airway obstruction.
• The patient is given an intravenous or intramuscular medication, such as adrenaline, and following such treatment and/or in the course thereof, the physiologic activities of the patient continue to be monitored. This monitoring is employed bycomputer484 to indicate the response to the treatment and the current status of the patient condition. In the scenario ofFIG. 29, the patient responds to the treatment and this is indicated by a status change statement, here “CONDITION STABLE”. Preferably some or all of the outputs ofcomputer484 are transmitted in a wireless manner by atransmitter488, such as via radio or a cellular telephone link, preferably to a dispatch center or patient receiving facility.
• Reference is now made additionally toFIG. 30, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 29. The patient is treated in an ambulance environment as is described hereinabove inFIG. 29, and the patient is being assessed to see whether his/her upper or lower airway is obstructed. The methodology illustrates the case where an upper obstruction is found.
• In the scenario described inFIG. 29 hereinabove, it is presumed that the patient may be having an allergic reaction. The operator switchescapnograph452 into an assessing mode so as to enable an assessment to be made whether and if the patient has an upper or a lower airway disorder.
• The patient previously attached to a multi-parameter monitor including acapnograph472 andsuitable instrumentation482, by means ofcannula470 and preferably also by means ofchest electrodes474,finger sensor476,forehead sensor478 andblood pressure cuff480, is monitored continuously for at least thirty seconds. Neurological status of the patient is acquired by any suitable technique, including visual and electroencephalograph (EEG) monitoring. Values of CO₂concentration, ECG, NIBP and SPO₂are continuously monitored, and carbon dioxide waveforms are preferably digitized as acapnogram472 and together with other waveforms are stored incomputer484.
• At least one expired air sample is collected and conveyed for analysis bycapnograph472. The outputs of thecapnograph472 and possibly ofadditional instrumentation482 are preferably supplied to suitably programmed automatic diagnostic andtreatment computer484, having associateddisplay486, which typically analyzes the respiration parameter output of thecapnograph472.
• In an analyzing step, the onset and offset limits of a capnogram489, pulse waveforms, and the QRS complex (of the ECG) are marked bycomputer484. The actual parameters measured include, but are not limited to heart rate (HR), BP, the systolic to diastolic ratio (SYS/DIA). SPO₂, AND ETCO₂. The slope of CO₂(mm Hg/sec), and CO₂“run”, of the capnogram489, measured to 80% of maximum CO₂concentration, are calculated bycomputer484.
• Following each treatment, the differences between consecutive measurements of the various patient parameters are computed bycomputer484. Thereafter, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters by computer484:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal; and
• c) ETCO₂is less than 45 mm Hg;
• then,
• display486 shows the message “VITAL SIGNS STABLE”.
• 2) In contrast, if:
• 1) If:
• a) the blood pressure values are not within the normal range;
• b) the respiratory rate is not normal; and
• c) ETCO₂is more than or equal to 45 mm Hg;
• then,
• display486 shows the message “RESPIRATORY IMPAIRMENT”.
• Additionally, the following rules may also be applied:
• 3) If:
• a) CO₂run is less than 0.3 sec;
• b) CO₂slope is more than 100 mm Hg/sec;
• then,
• display486 shows the message “NO BRONCHOSPASM PRESENT”.
• 4) If:
• a) CO₂run is more than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• then,
• display486 shows the message “BRONCHOSPASM PRESENT: CONSIDER LOWER AIRWAY OBSTRUCTION”.
• The findings of the last stage are stored bycomputer484 and/or transmitted viatransmitter488 to a dispatch/receiving center, typically located at a hospital or medical center. A connection is established with the dispatch/receiving center, and the data is forwarded thereto. A medical supervisor typically watches display of the received data, and consequentially transmits the recommended treatment and/or transport recommendations back to the ambulance.
• A copy of the patient's record is handed off fromcomputer464 viatransmitter488 to the receiving center, for example, in the form of a chart. Typically, the receiving center stores this chart, so that it may be used as a baseline for continued monitoring of the patient.
• Reference is now made toFIG. 31, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology for distinguishing between heart failure and emphysema in a scenario in which heart failure is present. As seen inFIG. 31, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula500, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal. FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph502, such as a Microcap®, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes504, afinger sensor506, a forehead/scalp sensor508 and ablood pressure cuff510 respectively, may also be sensed and measured bysuitable instrumentation512.
• The outputs of thecapnograph502 and possibly ofadditional instrumentation512 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer514, having an associateddisplay516 which typically analyzes the respiration parameter output of thecapnograph517 and possibly other parameters and provides an output which preferably contains a diagnostic statement differentiating heart failure from emphysema, here “ABNORMAL CO₂WAVEFORM CONSISTENT WITH MODERATE CONGESTIVE HEART FAILURE”.
• This diagnostic statement indicates that treatment is required for heart failure rather than for emphysema. Intravenous and/or sublingual medications such as nitroglycerin, morphine and LASIX^Rare administered after which a diagnostic statement which indicates the patient status and the severity of the cardio-respiratory condition is preferably presented, here “MILD CONGESTIVE HEART FAILURE, CONDITION IMPROVING”
• Reference is now made additionally toFIGS. 32A and 32B, which illustrate the operation of the system and methodology of the system of the present invention in the context ofFIG. 31. The patient is treated in an ambulance environment as is described hereinabove inFIG. 15, and the patient is being assessed to see whether his/her upper or lower airway is obstructed. The methodology illustrates the case where an upper obstruction is found.
• In the scenario described inFIG. 31 hereinabove, it is presumed that the patient may be suffering from either emphysema or a heart failure in an ambulance. It is shown hereinbelow how the patient is diagnosed as having a heart failure.
• The patient, previously attached to a multi-parameter monitor including acapnograph502 andsuitable instrumentation512, by means ofcannula500 and preferably also by means ofchest electrodes504,finger sensor506,forehead sensor508 andblood pressure cuff510, is monitored continuously for at least thirty seconds. Neurological status of the patient is acquired by any suitable technique, including visual and electroencephalograph (EEG) monitoring. Values of CO₂concentration, ECG, NIBP and SPO₂are continuously monitored, and carbon dioxide waveforms are preferably digitized as acapnogram517 and together with other waveforms are stored incomputer514.
• At least one expired air sample is collected and conveyed for analysis bycapnograph472. The outputs of thecapnograph502 and possibly ofadditional instrumentation512 are preferably supplied to suitably programmed automatic diagnostic andtreatment computer514, having associateddisplay516, which typically analyzes the respiration parameter output of thecapnograph502.
• In an analyzing step, the onset and offset limits of acapnogram517, pulse waveforms, and the QRS complex (of the ECG) are marked bycomputer514. The actual parameters measured include, but are not limited to heart rate (HR), BP, the systolic to diastolic ratio (SYS/DIA). SPO₂, AND ETCO₂. The slope of CO₂(mm Hg/sec), and CO₂“run”, of thecapnogram517, measured to 80% of maximum CO₂concentration, are calculated bycomputer514.
• Following each treatment, the differences between consecutive measurements of the various patient parameters are computed bycomputer514. Thereafter, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters by computer514:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal; and
• c) ETCO₂is less than 45 mm Hg;
• then, display516 shows the message “VITAL SIGNS WITHIN NORMAL LIMITS”.
• 2) In contrast, if:
• a) the value of Diminished CAP-FEV1 is a 40:10 point ratio; and,
• b) Normal CAP-FEV1/FVC (FORCED VITAL CAPACITY);
• c) CO₂run is less than 0.3 sec;
• d) CO₂slope is more than 100 mm Hg/sec;
• then,
• display516 shows the message “HEART FAILURE PRESENT”.
• Additionally, if a heart failure is present then the following rules may also be applied:
• 3) If:
• a) the value of CAP-FEV1 is less than 80%;
• then
• display516 shows the message “MODERATE HEART FAILURE PRESENT”.
• 4) If:
• a) the value of CAP-FEV1 is less than 80%,
• b) the value of SPO₂is less than 91% SAT; and
• c) the value of ETCO₂is less than 45 mm Hg;
• then,
• display516 shows the message “SEVERE HEART FAILURE PRESENT”.
• Thereafter a cycle of alternating I) sampling step (data collection and measurement) and II) diagnostic rule application to the previous sample step I) is initiated.
• I) Sampling Step
• a) A sample of expired air is taken and conveyed fromcannula500 tocapnograph502.
• b) The carbon dioxide concentration is measured continuously bycapnograph502 ascapnogram517.
• c) The capnogram is digitized as waveform and store for analysis bycomputer514.
• d)Computer514 marks onset and offset limits of the capnogram.
• e) The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• f) The slope and the run are determined bycomputer514.
• II) Diagnostic Rule Application Step
• In a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters of I) Sampling step by computer514:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm Hg;
• then,
• display516 shows the message “NO HEART FAILURE PRESENT.”
• 2) If:
• a) the value of CAP-FEV1 is more than 50%, but less than or equal to 80%; and
• b) the value of SPO₂is greater or equal to 91% SAT but less than 95% SAT;
• then
• display516 shows the message “. MODERATE HEART FAILURE PRESENT”.
• 3) If:
• a) the value of CAP-FEV1 is less than 80%;
• b) the value of SPO₂is less than 91% SAT; and
• c) the value of ETCO₂is less than 45 mm Hg;
• then,
• display516 shows the message “SEVERE HEART FAILURE PRESENT”.
• Reference is now made toFIG. 33, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in an ambulance environment for treating pulmonary edema. As seen inFIG. 33, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula550, such as a Model NasalFilterLine Adult XS 04461, 02/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with a capnograph552, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes554, afinger sensor556, a forehead/scalp sensor558 and ablood pressure cuff560 respectively, may also be sensed and measured bysuitable instrumentation562.
• The outputs of the capnograph552 and possibly ofadditional instrumentation562 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer564, having an associateddisplay566 which typically analyzes the respiration parameter output of the capnograph552 and possibly other parameters and provides an output which preferably contains a diagnostic statement indicating the presence and severity of congestive heart failure, here “ABNORMAL CO₂WAVEFORM CONSISTENT WITH SEVERE CONGESTIVE HEART FAILURE”.
• This diagnostic statement indicates that treatment is required for heart failure. Intravenous and/or sublingual medications such as nitroglycerin, morphine and LASIX R are administered after which a diagnostic statement which indicates the patient status and the severity of the cardio-respiratory condition is preferably presented, here “MODERATE CONGESTIVE HEART FAILURE, CONDITION IMPROVING”.
• Reference is now made additionally toFIGS. 34A and 34B, which illustrate the operation of the system and methodology of the system of the present invention in the context ofFIG. 33.
• The patient previously attached to a multi-parameter monitor including a capnograph552 andsuitable instrumentation562, by means ofcannula550 and preferably also by means ofchest electrodes554,finger sensor556,forehead sensor558 andblood pressure cuff560, is monitored continuously for at least thirty seconds. Neurological status of the patient is acquired by any suitable technique, including visual and electroencephalograph (EEG) monitoring. Values of CO₂concentration, ECG, NIBP, SPO₂, and cerebral oximetry are continuously monitored, and carbon dioxide waveforms are preferably digitized as a capnogram567 and together with other waveforms are stored incomputer564.
• At least one expired air sample is collected and conveyed for analysis by capnograph552. The outputs of the capnograph552 and possibly ofadditional instrumentation562 are preferably supplied to suitably programmed automatic diagnostic andtreatment computer564, having associateddisplay566, which typically analyzes the respiration parameter output of the capnograph552.
• In an analyzing step, the onset and offset limits of a capnogram567, pulse waveforms, and the QRS complex (of the ECG) are marked bycomputer564. The actual parameters measured include, but are not limited to heart rate (HR), BP, the systolic to diastolic ratio (SYS/DIA). SPO₂, AND ETCO₂. The slope of CO₂(mm Hg/sec), and CO₂“run”, of the capnogram567, measured to 80% of maximum CO₂concentration, are calculated bycomputer564.
• Following each treatment, the differences between consecutive measurements of the various patient parameters are computed bycomputer564. Thereafter, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters by computer564:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal; and
• c) ETCO₂is less than 45 mm Hg;
• then,
• display566 shows the message “VITAL SIGNS WITHIN NORMAL LIMITS”.
• 2) In contrast, if:
• a) the value of Diminished CAP-FEV1 is a 40:10 point ratio;
• b) Normal CAP-FEV/FVC;
• c) CO₂run is less than 0.3 sec; and,
• d) CO₂slope is more than 100 mm Hg/sec;
• then,
• display566 shows the message “BRONCHOSPASM IS PRESENT”.
• Additionally, if bronchospasm is present then the following rules may also be applied:
• 3) If:
• a) the value of CAP-FEV1 is less than 80%;
• then
• display566 shows the message “MODERATE BRONCHOSPASM IS PRESENT”.
• 4) If:
• a) the value of CAP-FEV1 is less than 80%;
• b) the value of SPO₂is less than 91% SAT; and
• c) the value of ETCO₂is less than 45 mm Hg;
• then,
• display566 shows the message “SEVERE BRONCHOSPASM PRESENT”.
• Thereafter a cycle of alternating. I) sampling step (data collection and measurement) and II) diagnostic rule application to the previous sample step I) is initiated:
• I) Sampling Step
• a) A sample of expired air is taken and conveyed fromcannula550 to capnograph552.
• b) The carbon dioxide concentration is measured continuously by capnograph552 as capnogram567.
• c) The capnogram is digitized as waveform and store for analysis bycomputer564.
• d)Computer564 marks onset and offset limits of the capnogram.
• e) The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• f) The slope and the run are determined bycomputer564.
• II) Diagnostic Rule Application Step
• In a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters of I) Sampling step by computer564:
• 1) If:
• a) the blood pressure values are within the normal range;
• b) the respiratory rate is normal;
• c) CO₂run is less than or equal to 0.3 sec;
• d) CO₂slope is more than or equal to 100 mm Hg/sec;
• e) SPO₂is greater than or equal to 95% SAT; and
• f) ETCO₂is less than or equal to 45 mm Hg;
• then,
• display566 shows the message “NO BRONCHOSPASM PRESENT.”
• 2) In contrast, if:
• a) CO₂run is greater than 0.3 sec;
• b) CO₂slope is less than 100 mm Hg/sec;
• c) SPO₂is more than or equal to 91% SAT, but less than 95% SAT; and
• d) ETCO₂is less than 45 mm Hg;
• then,
• the message “MODERATE BRONCHOSPASM PRESENT” is displayed ondisplay566.
• 3) If the parameters measured are yet further removed from the acceptable range, such as if:
• a) CAP-FEV1 is less than 50%;
• b) SPO₂is less than 91% SAT; and
• c) ETCO₂is greater than 45 mm Hg;
• then,
• a message such as “SEVERE BRONCHOSPASM PRESENT” is displayed ondisplay566.
• At any one of the diagnostic rule application steps, it may be verified that the patient is suffering from bronchospasm. Once bronchospasm is verified, the operator switches capnograph552 to a serial comparison mode. The medical team applies the appropriate interventions to the patient to treat the bronchospasm.
• Reference is now made toFIG. 35, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital or EMS environment for diagnosing and treating respiratory failure. As seen inFIG. 35, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula570, such as a Model NasalFilterLine Adult XS 04461, 02/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph572, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes574, afinger sensor576, a forehead/scalp sensor578 and ablood pressure cuff580 respectively, may also be sensed and measured bysuitable instrumentation582.
• Following intubation of the patient and prior to securing the tube, the outputs of thecapnograph572 and possibly ofadditional instrumentation582 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer584, having an associateddisplay586 which typically analyzes the respiration parameter output of thecapnograph572 and possibly other parameters and provides an output which preferably contains a diagnostic statement indicating proper intubation, here “TUBE IN TRACHEA”.
• The system determines whether characteristics of the capnograph waveform amplitude are normal. If the CO₂levels as indicated by the capnograph waveform amplitude are below normal a diagnostic statement indicating right mainstem bronchus intubation is presented, here “ABNORMAL WAVEFORM, CHECK FOR RIGHT MAINSTEM BRONCHUS INTUBATION”.
• Following repositioning of the tube, the system provides a patient status statement, here “WAVEFORM NORMALIZED, TUBE IN TRACHEA.
• Reference is now made additionally toFIG. 36, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 35.
• The patient in an ambulance, preferably attached to a multi-parametermonitor including capnograph572, is monitored continuously for at least 30 seconds. Expired air is collected viacannula570 and is conveyed to thecapnograph572.
• Values of the CO₂concentration is continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram and together with other waveforms are stored oncomputer584.
• The onset and offset limits of the patient's capnogram fromcapnograph572 are delineated bycomputer584.
• The waveform quality of the capnogram587 is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 1 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• If the quality is unacceptable, further samples are collected until a sample of acceptable quality, according to the above two criteria, is taken.
• The next step entails a checking procedure, wherein the ETCO₂value is measured bycapnograph572. The slope and run values of the capnogram fromcapnograph572 are determined bycomputer584.
• At startup, the following checking rule is preferably applied.
• 1) If:
• a) the ETCO₂value is more than 15 mm Hg;
• then,
• a display is provided bycomputer584 stating “GOOD WAVEFORM, TUBE IN TRACHEA”.
• In a checking step, repeated checks for abnormal waveform shape of capnogram587. The following rules are preferably applied to the capnogram shape:
• 1) if:
• a) an abnormal waveform shape is observed;
• then,
• computer584 displays “TUBE IMPROPERLY POSITIONED: CHECK FOR RIGHT MAINSTEM INTUBATION” ondisplay586.
• 2) If:
• a) a normal waveform shape is observed;
• then,
• computer584 displays “TUBE PROPERLY POSITIONED: CONFIRM BREATH SOUNDS AND SECURE TUBE” ondisplay586.
• When tube is secure as is confirmed by an operator, the operator typically inputs a code intocomputer584 to activate an intubation monitoring mode incapnograph572. The capnogram is monitored continuously for loss of signal. Loss of signal fromcapnograph572 is indicative of the tube having slipped away from the trachea. As long as there is a regular signal,computer584 displays “MONITORING INTUBATION” ondisplay586.
• Reference is now made toFIG. 37, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for diagnosing and treating pulmonary embolism. As seen inFIG. 37, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula600, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with a capnograph602, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes604, afinger sensor606, a forehead/scalp sensor608 and ablood pressure cuff610 respectively, may also be sensed and measured bysuitable instrumentation612.
• The outputs of the capnograph602 and possibly ofadditional instrumentation612 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer614, having an associateddisplay616 which typically analyzes the respiration parameter output of the capnograph602 and possibly other parameters and provides an output which preferably contains a diagnostic statement alerting hospital staff to the possible presence of pulmonary embolism. A typical such statement is “ALERT: ABNORMAL WAVEFORM CONSISTENT WITH PULMONARY EMBOLISM”. Following intravenous medication for dissolving blood clots in the lungs, the system determines whether characteristics of the CO₂waveform amplitude and shape are approaching normal and preferably provides a patient status statement, here “WAVEFORM NORMALIZING, GOOD RESPONSE TO TREATMENT”.
• Reference is now made additionally toFIG. 38, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 37.
• The patient, preferably attached to a multi-parameter monitor including capnograph602 andinstrumentation612, by means ofcannula600 and preferably also by means ofchest electrodes604,finger sensor606, scalp/forehead sensor608 andblood pressure cuff610, is monitored continuously. The neurological status of the patient is acquired by any suitable technique. Values of CO₂concentration, ECG, NIBP and SPO₂are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram617 and other waveforms and stored bycomputer614.
• Thereafter, the onset and offset limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer614. The heart rate, blood pressure ETCO₂and SPO₂values are measured. The initial slope of the capnogram and the run, monitored by capnograph602, are calculated bycomputer614. Additionally, neurological findings, monitored by means of an EEG are inputted tocomputer614.
• At various intervals, the differences between consecutive measurements of the various patient parameters are evaluated bycomputer614. After each treatment, in a diagnostic rule application step, the following diagnostic rule is preferably applied to the measured parameters by computer614:
• 1) If:
• a) the heart rate is greater than 100/min;
• b) the SPO₂is less than 90% SAT;
• c) the EtCO₂is less than 35 mm Hg;
• d) the amplitude (area under curve) of the CO₂waveform is less than a predetermined value;
• e) the ECG is normal; and
• f) the respiratory rate is greater than 15/min;
• display616 shows the message “ALERT: VITAL SIGNS CONSISTENT WITH ACUTE PULMONARY EMBOLISM”.
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer614: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer614.
• 1) If:
• a) the decrease in the SPO₂values is greater than −5% SAT; or
• b) the difference in the ETCO₂slope is greater than +5 mm Hg;
• then,
• computer614 displays ondisplay616 “PATIENT STATUS: DETERIORATING”.
• 2) If:
• a) the increase in the SPO₂values is greater than +5% SAT; or
• b) the difference in the ETCO₂slope is more than −5 mm Hg;
• then,
• computer614 displays ondisplay616 “PATIENT STATUS:IMPROVING”.
• 3) If:
• a) the difference in the SPO₂values is more positive than or equal to −5% SAT, but less than or equal to +5%; or
• b) the difference in the ETCO₂slope greater than or equal to −5 mm Hg, but less than or equal to +5 mm Hg;
• then,
• computer614 displays ondisplay616 “PATIENT STATUS:UNCHANGED”.
• Following the monitoring stage, the following exit rules are preferably applied to the measured parameters of the patient by computer232:
• I) If:
• a) the ECG values are within normal limits;
• b) the respiratory rate is within normal limits;
• c) the heart rate is within normal limits;
• d) the SPO₂value is greater than 95% SAT; and
• e) the ETCO₂value is less than 45 mm Hg;
• then,
• Computer614 preferably displays ondisplay616 “VITAL SIGNS STABLE”.
• (If the patient's record complies with this exit rule, then a copy of the patient's record is handed-off fromcomputer616 to the receiving center, for example, in the form of a chart. Typically, the receiving center stores this chart, so that it may be used as a baseline for continued monitoring of the patient).
• Reference is now made toFIGS. 39A and 39B, which are simplified pictorial illustrations of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for determining correct placement of a nasogastric tube in a patient. As seen inFIGS. 39A and 39B, following insertion of a nasogastric tube in a patient, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula630, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph632, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes634, afinger sensor636, a forehead/scalp sensor638 and ablood pressure cuff640 respectively, may also be sensed and measured bysuitable instrumentation642.
• The outputs of thecapnograph632 and possibly ofadditional instrumentation642 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer644, having an associateddisplay646 which typically analyzes the respiration parameter output of thecapnograph632 and possibly other parameters and provides an output which preferably contains a status statement alerting hospital staff to the possible misplacement of the nasogastric tube. A typical such statement is, “NASOGASTRIC (NG) TUBE IN LUNG”. This status statement is preferably accompanied by a treatment recommendation: here “REPOSITION NASOGASTRIC TUBE”. Following repositioning of the nasogastric tube, a status statement confirming proper placement is preferably provided, here “NASOGASTRIC TUBE 1 N STOMACH”. This statement is preferably accompanied by a treatment recommendation, here “SECURE TUBE”.
• Reference is now made additionally toFIG. 40, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIGS. 39A and 39B.
• The patient, preferably attached to a multi-parameter monitor including capnograph-632, is monitored continuously for at least 30 seconds. Expired air is collected via cannula630 and is conveyed to thecapnograph632.
• Values of the CO₂concentration is continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram647 and, together with other waveforms, is stored oncomputer644.
• The onset and offset limits of the patient's capnogram fromcapnograph632 are delineated bycomputer644.
• The waveform quality of the capnogram647 is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 1 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• If the quality is unacceptable, further samples are collected until a sample of acceptable quality, according to the above two criteria, is taken.
• The next step entails a checking procedure, wherein the ETCO₂value is measured bycapnograph632. The slope and run values of the capnogram fromcapnograph632 are determined bycomputer644.
• The following checking rules are preferably applied.
• 1) If:
• a) the ETCO₂value is less than or equal to 15 mm Hg; or
• b) there is a loss of the waveform of capnogram647;
• then,
• a display is provided bycomputer644 stating “NO WAVEFORM PRESENT, NG TUBE NOT IN TRACHEA”.
• 2) If:
• a) the ETCO₂value is more than or equal to 15 mm Hg; or
• b) profile of exhaled gas is detected as a waveform of capnogram647;
• then,
• a display is provided bycomputer644 stating “CO₂DETECTED, NG TUBE IN TRACHEA.”
• Reference is now made toFIG. 41, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for determining the presence of acute myocardial infarction in a patient. As seen inFIG. 41, following a patient complaint of chest pains, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula650, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal-FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph652, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes654, afinger sensor656, a forehead/scalp sensor658 and ablood pressure cuff660 respectively, may also be sensed and measured bysuitable instrumentation662.
• The outputs of thecapnograph652 and possibly ofadditional instrumentation662 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer664, having an associateddisplay666 which typically analyzes the respiration parameter output of thecapnograph652 and possibly other parameters and provides an output which preferably contains a diagnostic statement alerting hospital staff to the possibility of occurrence of acute myocardial infarction. A typical such statement is “VITAL SIGNS CONSISTENT WITH HEART ATTACK. CONDITION CRITICAL”. Following sublingual and/or intravenous administration of a medicament such as nitroglycerin and morphine, a patient status statement is preferably provided, here “GOOD RESPONSE TO TREATMENT. CONDITION IMPROVING”.
• Reference is now made additionally toFIG. 42, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 41.
• The patient, preferably attached to a multi-parametermonitor including capnograph652 andsuitable instrumentation662, by means ofcannula650 and preferably also by means ofchest electrodes654,finger sensor656, forehead/scalp sensor658, andblood pressure cuff660, is monitored continuously. The neurological status of the patient is acquired by any suitable technique. Values ofCO2 concentration, HR, BP (SYS/DIA) ECG, NIBP and SPO₂are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram667 and other waveforms and stored oncomputer664.
• Thereafter, the onset and offset limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer664. The initial slope of the capnogram and the run are determined and stored incomputer664.
• At various intervals, the differences between consecutive measurements of the various patient parameters are evaluated bycomputer664. After each treatment, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters by computer664:
• 1) If:
• a) there is a localized elevation in the ST segment in the ECG; and
• b) the ETCO₂is declining at least by 2 mm Hg/min over five minutes;
• then,
• display666 shows the message “ACUTE MYOCARDIAL INFARCTION (MI) SUSPECTED”.
• 2) If:
• a) the SPO₂value is less than 91% SAT; and
• b) the ETCO₂value is less than 30 mm Hg;
• then,
• display666 shows the message “VITAL SIGNS CRITICAL”.
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer664: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer664.
• 1) If:
• a) the difference in the ST elevation in the ECG is greater than 0.1 mm and
• b) the difference in the ETCO₂slope is less than −1 mm Hg/min;
• then,
• computer664 displays ondisplay666 “PATIENT STATUS: WORSENING”.
• 2) If:
• a) the difference in the ST elevation in the ECG is less than −0.1 mm and
• b) the difference in the ETCO₂is more than 1 mm Hg/min;
• then,
• computer664 displays ondisplay666 “PATIENT STATUS: IMPROVING”.
• 3) If:
• a) the difference in the ST elevation in the ECG is more than or equal to −0.1 mm but less than or equal to 0.1 mm; or
• b) the difference in the ETCO₂is more than or equal to −1 mm Hg/min and is less than or equal to 1 mm Hg/min;
• then,
• computer664 displays ondisplay666 “PATIENT STATUS: UNCHANGED”.
• Reference is now made toFIG. 43, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for determining the presence of cardiogenic shock in a patient. As seen inFIG. 43, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula670, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal. FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph672, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means of chest-electrodes674, afinger sensor676, a forehead/scalp sensor678 and ablood pressure cuff680 respectively, may also be sensed and measured bysuitable instrumentation682.
• The outputs of thecapnograph672 and possibly ofadditional instrumentation682 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer684, having an associateddisplay686 which typically analyzes the respiration parameter output of thecapnograph672 and possibly other parameters and provides an output which preferably contains a diagnostic statement alerting hospital staff to the possibility of occurrence of cardiogenic shock. A typical such statement is “VITAL SIGNS CONSISTENT WITH CARDIOGENIC SHOCK. CONDITION CRITICAL”. Following intravenous administration of a medicament such as dopamine dobutamine, a patient status statement is preferably provided, here “CONDITION IMPROVING”.
• Reference is now made additionally toFIG. 44, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 43.
• The patient, preferably attached to a multi-parametermonitor including capnograph672 andsuitable instrumentation682, by means ofcannula670 and preferably also by means ofchest electrodes674,finger sensor676, forehead/scalp sensor678 andblood pressure cuff680, is monitored continuously. The neurological status of the patient is acquired by any suitable technique. Values of CO₂concentration, HR, BP (SYS/DIA) ECG, NIBP and SPO₂are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram667 and other waveforms and stored oncomputer684.
• Thereafter, the onset and offset limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer684. The initial slope of the capnogram and the run are determined and stored incomputer684.
• At various intervals, the differences between consecutive measurements of the various patient parameters are evaluated bycomputer684.
• After each interval, in a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters bycomputer684;
• 1) If:
• a) the systolic blood pressure is less than 90 mm Hg;
• b) the heart rate is more than 100/min;
• c) the respiratory rate is more than 15/min; and
• d) and the ETCO₂is less than 35 mm Hg;
• then,
• display686 shows the message “ALERT: CONSIDER CARDIOGENIC SHOCK”.
• 2) If:
• a) the SPO₂value is less than 91% SAT; and
• b) the ETCO₂value is less than 30 mm Hg;
• then,
• display686 shows the message “VITAL SIGNS CRITICAL”.
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer684: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer684.
• 1) If:
• a) the difference in the systolic blood pressure is less than −5 mm Hg; and
• b) the difference in the ETCO₂is less than −1 mm Hg/min;
• then,
• computer664 displays ondisplay666 “PATIENT STATUS:WORSENING”.
• 2) If:
• a) the difference in the systolic blood pressure is more than 5 mm Hg; and
• b) the difference in the ETCO₂is more than 1 mm Hg/min;
• then,
• computer664 displays ondisplay666 “PATIENT STATUS:IMPROVING”.
• 3) If:
• a) the difference in the systolic blood pressure is more than or equal to −5 mm Hg and less than or equal to +5 mm Hg; and/or
• b) the difference in the ETCO₂is more than or equal to −1 mm Hg/min and is less than or equal to 1 mm Hg/min;
• then,
• computer684 displays ondisplay686 “PATIENT STATUS:UNCHANGED”.
• Reference is now made toFIG. 45, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital environment for determining the presence of cardiac arrest in a patient. As seen inFIG. 45, a patient who is found to be unconscious and unresponsive is subsequently connected to the system of the present invention. Various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula700, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph702, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes704, afinger sensor706, a forehead/scalp sensor708 and ablood pressure cuff710 respectively, may also be sensed and measured bysuitable instrumentation712.
• The outputs of thecapnograph702 and possibly ofadditional instrumentation712 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer714, having an associated display716 which typically analyzes the respiration parameter output of thecapnograph702 and possibly other parameters and provides an output which preferably contains a diagnostic statement alerting hospital staff to the possibility of occurrence of cardiac arrest. A typical such statement is “ALERT: CARDIAC ARREST”. Following treatment, typically including intubation and intravenous administration of a medicament such as adrenaline, during external cardiac massage, a patient status statement, indicating the effectiveness of the treatment is preferably provided, here “EFFECTIVE CARDIAC COMPRESSIONS.” The system also preferably diagnoses the return of spontaneous circulation and prompts the caregiver to check for the presence of a pulse, here by means of a diagnostic statement and a treatment recommendation such as “RETURN OF SPONTANEOUS CIRCULATION. CHECK FOR PULSE”.
• Reference is now made additionally toFIG. 46, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 45.
• The patient, preferably attached to a multi-parametermonitor including capnograph702 andsuitable instrumentation712, by means ofcannula700 and preferably also by means ofchest electrodes704,finger sensor706, forehead/scalp sensor708′ andblood pressure cuff710, is monitored continuously. The neurological status of the patient is acquired by any suitable technique. Values ofCO2 concentration, HR, BP (SYS/DIA) ECG, NIBP and SPO₂are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram717, and is stored oncomputer714 together with other waveforms.
• Thereafter, the onset and offset limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer714. The initial slope of the capnogram and the run are determined and stored incomputer714.
• At various intervals, the differences between consecutive measurements of the various patient parameters are evaluated bycomputer714.
• After each time interval, the difference between consecutive measures of each parameter are calculated by computer714: Thereafter, the following monitoring rules are preferably applied to the measured parameters bycomputer714.
• 1) If:
• a) the heart rate is less than 30/min; and
• b) the ETCO₂value is less than 15 mm Hg;
• then,
• computer714 displays on display716 “NO RETURN OF CIRCULATION”.
• 2) If:
• a) the heart rate is more than or equal to 30/min; and
• b) the ETCO₂value is more than or equal to 15 mm Hg;
• then,
• computer714 displays on display716 “RETURN OF CIRCULATION”.
• Reference is now made toFIG. 47, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a out of hospital environment for determining the presence of acute cardiac ischemia in a patient.
• As seen inFIG. 47, while a patient, undergoes treadmill testing in a doctor's office, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula730, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph732, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes734, afinger sensor736, a forehead/scalp sensor738 and ablood pressure cuff740 respectively, may also be sensed and measured bysuitable instrumentation742.
• The outputs of thecapnograph732 and possibly ofadditional instrumentation742 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer744, having an associateddisplay746 which typically analyzes the respiration parameter output of thecapnograph732 and possibly other parameters and provides an output which preferably contains a diagnostic statement, here “VITAL SIGNS NORMAL”, which indicates normal patient condition. At some point thereafter, a further diagnostic statement appears, here, “ALERT: ACUTE CARDIAC ISCHEMIA”. Upon noticing this statement, the physician causes the patient to lie down and administers oxygen treatment to the patient. The system assesses the patient's response to the treatment and provides a patient status message, here “VITAL SIGNS NORMAL”.
• Reference is now made additionally toFIG. 48, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 47.
• The patient, preferably attached to a multi-parametermonitor including capnograph732 andsuitable instrumentation742, by means ofcannula730 and preferably also by means ofchest electrodes734,finger sensor736, forehead/scalp sensor738 andblood pressure cuff740, is monitored continuously. The neurological status of the patient is acquired by any suitable technique. Values of CO₂concentration, HR, BP (SYS/DIA) ECG, NIBP and SPO₂are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram747, and is stored oncomputer744 together with other waveforms.
• Thereafter, the onset and offset limits of the capnogram, the pulse waveform and QRS onset and offset are determined bycomputer744. The initial slope of the capnogram and the run are determined and stored incomputer744.
• In the next step, when the monitoring has been verified by the operator, that it is functioning correctly, the baseline cardiorespiratory pattern is stored incomputer744.
• Thereafter,computer744 and/or the operator activatescapnograph732 in a monitoring mode. The patient is monitored continuously bycapnograph732 for any significant change in the cardiorespiratory pattern.
• The following monitoring rule is preferably applied to capnogram747 bycomputer744.
• 1) If:
• a) a significant change in the cardiorespiratory pattern is apparent;
• then,
• computer744 displays “MONITORING STRESS RESPONSE” ondisplay746.
• Thereafter, a cycle of alternating I) sampling step (data collection and measurement) and II) diagnostic rule application to the previous sample step I) is initiated.
• I) Sampling Step
• a) A sample of expired air is taken and conveyed fromcannula400 tocapnograph732.
• b) The carbon dioxide concentration is measured continuously bycapnograph744 as a capnogram747.
• c) The capnogram is digitized as waveform and store for analysis bycomputer744.
• d)Computer744 marks onset and offset limits of the capnogram.
• e) The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• f) The slope and the run are determined bycomputer744.
• II) Diagnostic Rule Application Step
• In a diagnostic rule application step, the following diagnostic rules are preferably applied to the measured parameters of each sample in I) Sampling step by computer744:
• 1) If:
• a) there are no signs of ischemia (no elevation from baseline in the ECG ST segment; and no changes from baseline in the T-waves;
• b) there are no changes towards ischemia (rising ST-segment values on ECG from baseline, and dropping ETCO₂values >5 mm Hg from baseline);
• then,
• Computer744 displays ondisplay746 “NO SIGNS OF ACUTE CARDIAC ISCHEMIA”.
• 2) If:
• a) a) there are signs of ischemia; or
• b) there are changes towards ischemia; then,
• Computer744 displays ondisplay746 “ALERT: SIGNS OF ACUTE CARDIAC ISCHEMIA”.
• Reference is now made toFIG. 49, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital or outpatient environment for sedation and/or anesthesia monitoring. As seen inFIG. 49, while a patient is under sedation and/or anesthesia, typically in the course of a medical procedure, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula800, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph802, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes804, afinger sensor806, a forehead/scalp sensor808 and a blood pressure cuff810 respectively, may also be sensed and measured bysuitable instrumentation812.
• The outputs of thecapnograph802 and possibly ofadditional instrumentation812 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer814, having an associateddisplay816 which typically analyzes the respiration parameter output of thecapnograph802 and possibly other parameters and provides an output which preferably contains a diagnostic statement confirming proper respiration, here “NORMAL WAVEFORM RHYTHM”.
• If at a later stage during the medical procedure, a deviation from the patient's normal CO₂waveform rhythm is sensed, a further diagnostic statement is provided, here “ALERT: SIGNIFICANT DEVIATION IN WAVEFORM RHYTHM”. This statement is preferably accompanied by a treatment recommendation, here “REDUCE SEDATION LEVEL”. Following reduction in the sedation level, a diagnostic statement which indicates the patient status is preferably presented, here “NORMAL WAVEFORM RHYTHM RESTORED”.
• Reference is now made additionally toFIG. 50, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 49.
• The patient, preferably attached to a multi-parametermonitor including capnograph802, is typically monitored continuously for at least 30 seconds. Additionally or alternatively, the patient may be monitored for shorter or longer durations. Expired air is collected viacannula800 and is conveyed to thecapnograph802.
• Values of the CO₂concentration are continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram817 and, together with other waveforms, is stored oncomputer814.
• The onset and offset limits of the patient's capnogram fromcapnograph802 are delineated bycomputer814.
• The waveform quality of the capnogram817 is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 1 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• If the quality is unacceptable, further samples are collected until a sample of acceptable quality, according to the above two criteria, is taken.
• The next step entails a checking procedure, wherein the ETCO₂value is measured bycapnograph632. The slope and run values of the capnogram fromcapnograph632 are determined bycomputer644.
• The following checking rule is preferably applied.
• 1) If
• a) the ETCO₂value is more than 15 mm Hg;
• then,
• a display is provided bycomputer814 stating NORMAL WAVEFORM RHYTHM”.
• After the waveform rhythm has been confirmed by an operator, the capnograph is entered into its monitoring mode, either by the operator or bycomputer814.Capnograph802 then monitors for any changes in the breathing pattern of the patient.
• Thereafter,computer814 displays “MONITORING SEDATION” ondisplay646.
• The next step entails a cycle of alternating I) sampling step (data collection and measurement) and II) diagnostic rule application to the previous sample step I) is initiated.
• I) Sampling Step
• In this sampling step, an exhaled air sample fromcannula800 is periodically collected, conveyed and measured bycapnograph802. The carbon dioxide concentration value is determined continuously bycapnograph802.Computer814 digitizes the capnograph signals as a waveform and store the waveform for analysis.
• Thereafter, the ETCO₂value is determined.
• II) Diagnostic Rule Application Step.
• The following diagnostic rules are applied to each sample:
• 1) If:
• a) The value of ETCO₂is greater than or equal to 15 mm Hg; and
• b) There is no loss in the waveform fromcapnograph802; and
• c) The respiratory rate is greater than or equal to 12/min;
• then,
• computer814 displays “NORMAL VENTILATORY WAVEFORM AND RHYTHM” ondisplay816.
• 2) If:
• a) The value of ETCO₂is less than 15 mm Hg; or
• b) There is a loss in the waveform fromcapnograph802; or
• c) The respiratory rate is less than 10/min; or
• d) There is a decline in ETCO₂of 50%; or
• e) There is a 50% increase in the pattern variability; or
• f) There is a 50% decrease in the pattern similarity;
• then,
• computer814 displays “ALERT: DIMINISHED VENTILATORY WAVEFORM” ondisplay816.
• This cycle typically proceeds until the patient monitoring is halted by the medical team or operator.
• Reference is now made toFIG. 51, which is a simplified pictorial illustration of an automatic medical diagnostic and treatment system and methodology operative in a hospital or outpatient environment for sedation and/or anesthesia titration. As seen inFIG. 51, when a patient is being sedated prior to carrying out of a medical procedure, various patient physiologic activities are sensed and measured, including respiratory physiologic activities, preferably via an oral airway adapter and/or a nasal or nasal/oral cannula900, such as a Model Nasal FilterLine Adult XS 04461, O₂/CO₂Nasal FilterLine Adult 007141, or Smart CapnoLine Adult (Oral/nasal FilterLine) 007414, commercially available from Oridion Ltd., of Jerusalem Israel, typically coupled with acapnograph902, such as a Microcap, commercially available from Oridion Ltd., of Jerusalem Israel. Other patient physiologic activities relating to cardiac function (e.g. ECG), systemic oxygenation (e.g. pulse oximetry), cerebral oxygenation (e.g. cerebral oximetry) and systemic circulation (e.g. NIBP), typically sensed by means ofchest electrodes904, afinger sensor906, a forehead/scalp sensor908 and ablood pressure cuff910 respectively, may also be sensed and measured bysuitable instrumentation912.
• The outputs of thecapnograph902 and possibly ofadditional instrumentation912 are preferably supplied to a suitably programmed automatic diagnostic andtreatment computer914, having an associateddisplay916 which typically analyzes the respiration parameter output of thecapnograph902 and possibly other parameters and provides an output which preferably contains a patient status statement confirming proper respiration, here “NORMAL RESPIRATORY PATTERN”. Following the administration of additional medication, a deviation from the patient's normal CO₂waveform shape, amplitude or periodicity is sensed, a further status statement is provided, here “ALERT: MILD HYPOVENTILATION PRESENT”. Following the administration of additional medication which increases the sedation level, an additional diagnostic statement which indicates the patient status is preferably presented, here “ALERT MODERATE HYPOVENTILATION PRESENT”. This alert indicates that at this point, titration of medication is complete and the medical procedure may be commenced. Following completion of the medical procedure, monitoring continues until a further status statement, here “NORMAL RESPIRATORY PATTERN RESTORED” indicates normal respiration and that the patient may be safely discharged.
• Reference is now made additionally toFIG. 52, which illustrates the operation of the system and methodology of the system of the present invention in the context ofFIG. 51.
• The patient, preferably attached to a multi-parametermonitor including capnograph902, is monitored continuously for at least 30 seconds. Expired air is collected viacannula900 and is conveyed to thecapnograph902.
• Values of the CO₂concentration is continuously measured, typically over a period of 30 seconds, and carbon dioxide waveforms are preferably digitized as a capnogram917 and, together with other waveforms, is stored oncomputer914.
• The onset and offset limits of the patient's capnogram fromcapnograph902 are delineated bycomputer914.
• The waveform quality of the capnogram917 is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• If the quality is unacceptable, further samples are collected until a sample of acceptable quality, according to the above two criteria, is taken.
• Thereafter, the ETCO₂value and the respiratory rate are determined.
• At startup a checking procedure is performed, wherein the ETCO₂value is measured bycapnograph902. The slope and run values of the capnogram fromcapnograph902 are determined bycomputer914.
• The following checking rule is preferably applied.
• 1) If:
• a) the ETCO₂value is more than 15 mm Hg;
• then,
• a display is provided bycomputer914 stating “GOOD WAVEFORM QUALITY; MONITORING LEVEL OF SEDATION.
• After the waveform rhythm has been confirmed by an operator, the baseline breathing pattern is stored incomputer914.Capnograph902 is entered into its monitoring mode, either by the operator or bycomputer914.Capnograph902 then monitors for any changes in the breathing pattern of the patient.
• The next step entails a cycle of alternating I) sampling step (data collection and measurement) twice per minute and II) diagnostic rule application to the previous sample step I) is initiated.
• I) Sampling Step
• In this sampling step, an exhaled air sample fromcannula900 is periodically collected, conveyed and measured bycapnograph902. The carbon dioxide concentration value is determined continuously bycapnograph902.Computer914 digitizes the capnograph signals as a waveform andcomputer914 stores the waveform for analysis.Computer914 marks onset and offset limits of the capnogram.
• The waveform quality of the capnogram is assessed by employing the criteria that an acceptable quality is defined by:
• i) the root mean square (rms) of the noise of the waveform must be less than 2 mm Hg; and
• ii) the breath-to-breath correlation must be greater than 0.85.
• Thereafter ETCO₂and the respiratory rate are measured, and the results stored oncomputer914.
• II) Diagnostic Rule Application Step.
• The following diagnostic rules are applied to each sample:
• 1) If:
• a) The value of ETCO₂is greater than or equal to 15 mm Hg, but less than 50 mm Hg;
• b) There is no loss in the waveform fromcapnograph902 and
• c) The respiratory rate is greater than 12/min;
• then,
• computer914 displays “NORMAL RESPIRATORY PATTERN” ondisplay916.
• 2) If:
• a) The respiratory rate is more than or equal to 10/min, but less than 12/min;
• then,
• computer914 displays “MILD HYPOVENTILATION” ondisplay916.
• 3) If:
• a) The value of ETCO₂is greater than or equal to 50 mm Hg, but less than 60 mm Hg; and
• b) The respiratory rate is more than or equal to 6/min, but less than 10/min; then,computer914 displays “MODERATE HYPOVENTILATION” ondisplay916.
• 4) If:
• The value of ETCO₂is greater or equal to 60 mm Hg; or
• b) There is a loss in the waveform; or
• c) The respiratory rate is less than 6/min;
• then,
• computer914 displays “ALERT: SEVERE HYPOVENTILATION OR APNEA” ondisplay916.
• It should be understood that the rules, such as monitoring- and diagnostic rules exemplified hereinabove are not meant to be limiting only to those and the numerical values therein that have been shown herein, and that these rules could be applied using similar or different numerical values and could incorporate further rules applied to other parameters. The rules provided herein may be provided as continuous or discontinuous rules, and may additionally or alternatively be applied in other combinations of continuity or discontinuity. Furthermore, it should be understood that the term “time interval” may include the time required for a treatment to be effective in a patient, and the word “treatment” may also be used to denote the time required for the treatment to be effective, such as in the phrase “after each treatment”.
• It will be appreciated by persons skilled in the art that the present invention is not limited by what has been particularly shown and described hereinabove. Rather the scope of the present invention includes both combinations and subcombinations of the features described hereinabove as well as modifications and variations thereof which would occur to a person of skill in the art upon reading the foregoing description and which are not in the prior art.

Claims (54)

1. A system for providing output related to at least one medical condition of a patient, the system comprising:

a first sensing unit adapted to provide a first signal indicative of a first medical parameter;

a second sensing unit adapted to provide a second signal indicative of a second medical parameter; and

a processing unit adapted to provide an output indication related to at least one medical condition of the patient, based at least on the first medical parameter and the second medical parameter.

2. The system according toclaim 1, further comprising a plurality of sensing units.

3. The system according toclaim 1, wherein the first medical parameter comprises a respiratory related parameter.

4. The system according toclaim 1, wherein the first medical parameter comprises a carbon dioxide (CO₂) related parameter.

5. The system according toclaim 4, wherein the CO₂related parameter comprises a CO₂waveform related parameter, an expired air CO₂concentration, respiratory rate or any combination thereof.

6. The system according toclaim 5, wherein the CO₂waveform related parameter comprises ETCO₂, changes in ETCO₂, a slope of the increase in the CO₂concentration, a change in a slope of the increase in the CO₂concentration, time to rise to a predetermined percentage of a maximum value of CO₂concentration, an angle of rise to a predetermined percentage of a maximum value of CO₂concentration, breath to breath correlation, CAP-FEV1, CAP-FEV1/FVC ratio or any combination thereof.

7. The system according toclaim 1, wherein the second medical parameter comprises a breathing related parameter, a heart function related parameter, a neurological parameter, a systemic perfusion related parameter, a visual parameter, FEV1, FVC or any combination thereof.

8. The system according toclaim 7, wherein the heart function related parameter comprises blood pressure, NI blood pressure, systolic to diastolic ratio, a related parameter or any combination thereof.

9. The system according toclaim 7, wherein the breathing related parameter comprises a respiratory rate.

10. The system according toclaim 7, wherein the neurological parameter comprises an electroencephalogram (EEG) related parameter.

11. The system according toclaim 1, wherein the processing unit is further adapted to compute a change in the first medical parameter, in the second medical parameter, in the output indication or in any combination thereof.

12. The system according toclaim 11, further comprising a medical treatment control functionality for controlling the provision of at least one treatment to the patient in response to a change in one or more output indications.

13. The system according toclaim 11, further comprising a medical treatment control functionality for controlling the provision of at least one treatment to the patient in response to a change in the relationship between one or more output indications.

14. The system according toclaim 1, further comprising monitoring the first medical parameter, the second medical parameter, the one or more output indications or any combination thereof.

15. A display device adapted to

receive a first signal indicative of a first medical parameter;

receive a second signal indicative of a second medical parameter; and

display an output indication related to at least one medical condition of the patient, based at least on the first medical parameter and the second medical parameter.

16. The display device according toclaim 15, further receiving a plurality of medical parameters.

17. The display device according toclaim 15, further comprising a processing unit adapted to provide the output indication related to the at least one medical condition of the patient.

18. The display device according toclaim 15, wherein the first medical parameter comprises a respiratory related parameter.

19. The display device according toclaim 18, wherein the first medical parameter comprises a CO₂waveform related parameter, an expired air CO₂concentration, a respiratory rate or any combination thereof.

20. The display device according toclaim 19, wherein the CO₂waveform related parameter comprises ETCO₂, changes in ETCO₂, a slope of the increase in the CO₂concentration, a change in a slope of the increase in the CO₂concentration, time to rise to a predetermined percentage of a maximum value of CO₂concentration, an angle of rise to a predetermined percentage of a maximum value of CO₂concentration, breath to breath correlation, CAP-FEV1, CAP-FEV1/FVC ratio or any combination thereof.

21. The display device according toclaim 15, wherein the second medical parameter comprises a breathing related parameter, a heart function related parameter, a neurological parameter, a systemic perfusion related parameter, a visual parameter, FEV1, FVC or any combination thereof.

22. The display device according toclaim 21, wherein the heart function related parameter comprises blood pressure, NI blood pressure, a systolic to diastolic ratio, a related parameter or any combination thereof.

23. The display device according toclaim 21, wherein the breathing related parameter comprises a respiratory rate.

24. The display device according toclaim 21, wherein the neurological parameter comprises an electroencephalogram (EEG) related parameter.

25. The display device according toclaim 17, wherein the processing unit is further adapted to compute a change in the first medical parameter, in the second medical parameter, in the output indication or in any combination thereof.

26. A method for providing output related to at least one medical condition of a patient, the method comprising:

obtaining a first medical parameter;

obtaining a second medical parameter; and

computing an output indication related to at least one medical condition of the patient, based at least on the first medical parameter and the second medical parameter.

27. The method according toclaim 26, further comprising obtaining a plurality of medical parameters.

28. The method according toclaim 26, wherein the first medical parameter comprises a respiratory related parameter.

29. The method according toclaim 26, wherein the first medical parameter comprises a carbon dioxide (CO₂) related parameter.

30. The method according toclaim 29, wherein the CO₂related parameter comprises a CO₂waveform related parameter, an expired air CO₂concentration, a respiratory rate or any combination thereof.

31. The method according toclaim 30, wherein the CO₂waveform related parameter comprises ETCO₂, changes in ETCO₂, a slope of the increase in the CO₂concentration, a change in a slope of the increase in the CO₂concentration, time to rise to a predetermined percentage of a maximum value of CO₂concentration, an angle of rise to a predetermined percentage of a maximum value of CO₂concentration, breath to breath correlation, CAP-FEV1, CAP-FEV1/FVC ratio or any combination thereof.

32. The method according toclaim 26, wherein the second medical parameter comprises a breathing related parameter, a heart function related parameter, a neurological parameter, a systemic perfusion related parameter, a visual parameter, FEV1, FVC or any combination thereof.

33. The method according toclaim 32, wherein the heart function related parameter comprises blood pressure, NI blood pressure, a systolic to diastolic ratio, a related parameter or any combination thereof.

34. The method according toclaim 32, wherein the breathing related parameter comprises a respiratory rate.

35. The method according toclaim 32, wherein the neurological parameter comprises an electroencephalogram (EEG) related parameter.

36. The method according toclaim 26, further comprising computing a change in the first medical parameter, in the second medical parameter, in the output indication or in any combination thereof.

37. The method according toclaim 36, further comprising controlling the provision of at least one treatment to the patient in response to a change in one or more output indications.

38. The method according toclaim 36, further comprising controlling the provision of at least one treatment to the patient in response to a change in the relationship between one or more output indications.

39. The method according toclaim 36, further comprising monitoring the first medical parameter, the second medical parameter, the one or more output indications or any combination thereof.

40. A method of treating a patient, the method comprising;

obtaining a first signal indicative of a first medical parameter;

obtaining a second signal indicative of a second medical parameter;

providing an output indication related to at least one medical condition of the patient, based at least on the first medical parameter and the second medical parameter; and

treating a patient based on the output indication.

41. The method according toclaim 40, further comprising obtaining a plurality of medical parameters.

42. The method according toclaim 40, wherein the first medical parameter comprises a respiratory related parameter.

43. The method according toclaim 40, wherein the first medical parameter comprises a carbon dioxide (CO₂) related parameter.

44. The method according toclaim 40, wherein the first medical parameter comprises a CO₂waveform related parameter, an expired air CO₂concentration, a respiratory rate or any combination thereof.

45. The method according toclaim 44, wherein the CO₂waveform related parameter comprises ETCO₂, changes in ETCO₂, a slope of the increase in the CO₂concentration, a change in a slope of the increase in the CO₂concentration, time to rise to a predetermined percentage of a maximum value of CO₂concentration, an angle of rise to a predetermined percentage of a maximum value of CO₂concentration, breath to breath correlation, CAP-FEV1, CAP-FEV1/FVC ratio or any combination thereof.

46. The method according toclaim 40, wherein the second medical parameter comprises a breathing related parameter, a heart function related parameter, a neurological parameter, a systemic perfusion related parameter, a visual parameter, FEV1, FVC or any combination thereof.

47. The method according toclaim 46, wherein the heart function related parameter comprises blood pressure, NI blood pressure, a systolic to diastolic ratio, a related parameter or any combination thereof.

48. The method according toclaim 46, wherein the breathing related parameter comprises a respiratory rate.

49. The method according toclaim 46, wherein the neurological parameter comprises an electroencephalogram (EEG) related parameter.

50. The method according toclaim 40, further comprising computing a change in the first medical parameter, in the second medical parameter, in the output indication or in any combination thereof.

51. The method according toclaim 50, further comprising controlling the provision of at least one treatment to the patient in response to a change in one or more output indications.

52. The method according toclaim 50, further comprising prising controlling the provision of at least one treatment to the patient in response to a change in the relationship between one or more output indications.

53. The method according toclaim 40, further comprising monitoring the first medical parameter, the second medical parameter, the one or more output indications or any combination thereof.

54. A system employing a plurality of parameters relating at least to respiration of a patient for providing a plurality of indications relating to at least one medical condition, the system comprising:

a medical data input interface providing the plurality of medical parameters regarding a patient;

a medical parameter interpretation functionality receiving the plurality of medical parameters regarding the patient and providing the plurality of output indications; and

a medical treatment control functionality for controlling the provision of at least one treatment to a patient in response to changes in the relationship between the output indications.

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