PRIORITY CLAIMPriority is claimed to co-pending U.S. Provisional Patent Application Ser. No. 62/025,073, filed Jul. 16, 2014, 62/025,077, filed Jul. 16, 2014, and 62/049,994 filed Sep. 12, 2014 which are hereby incorporated herein by reference in their entirety.
COPYRIGHT STATEMENTA portion of the disclosure of this patent application document contains material that is subject to copyright protection including the drawings. The copyright owner has no objection to the facsimile reproduction by anyone of the patent document or the patent disclosure as it appears in the Patent and Trademark Office file or records, but otherwise reserves all copyright rights whatsoever.
BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention relates to medical devices, and, more particularly to mask and headgear portions of air delivery devices that assist with the delivery of gas to the nasal passages of users. These mask and headgear systems and devices may be used with positive airway pressure [PAP] such as continuous positive airway pressure devices [CPAP], automatic positive airway pressure devices [APAP], variable positive airway pressure devices [VPAP], and bi-level positive airway pressure devices [BPAP].
2. Description of the Prior Art
Nasal pillows exist to be partially inserted into a user's nare and form a seal with the nare(s), which allows for the user to breathe from the ventilator or PAP device. However, nasal pillows have been known to not necessarily form the best seals for all users, put unnecessary pressure on the nare region when held in place by a mask system, and limited on flexibility. Masks have also tended to be bulky and shift when wearing them at night. Designs are being made to make masks lighter and more secure.
A need therefore exists for a nasal pillow that is interchangeable with a mask system, which is flexible and adaptable to a user's nare and facial profile, and reduces pressure applied on the nare region while in use. A need also exists for an adjustable mask and headgear system that conforms to a user's head and facial features while being comfortable and securely attaching the nasal pillows to a user's nares.
SUMMARY OF THE INVENTIONContemplated herein is a facial interface and headgear system for use with ventilation and positive air pressure systems. The facial interface can include a system and assembly configured to provide a portion of continuous airway pressure to a user's airways. The system and assembly includes a core having an inlet connector for receiving a supply of pressurized gas from a delivery tube, the core including a right arm and a left arm both extending from the core, each arm forming an associated air pathway through each respective arm, wherein each arm includes an aperture. The system can further include a nasal pillow assembly configured to connect to each of the arms over the respective apertures. In this manner each nasal pillow assembly can be configured to communicate the supply of pressurized gas from the air pathway through each nasal pillow assembly and to a user's nostrils.
Optionally, a headgear interface can be provided which is located about a distal end of each of the right and left arms, the headgear interface being configured to be attached to a headgear assembly.
In some embodiments the right and left arms can be offset with respect to one another so as to be non-coaxial, or in other words angled with respect to one another. In yet other embodiments the nasal pillow assembly includes a nasal pillow rotatable about a nasal pillow axis.
In some embodiments the headgear interface provided at each distal end of the left and right arms can include a deformable sidepiece configured to attach to its respective arm. This deformable sidepiece can be configured to attach to the arm at various angular positions with respect to the axis of its respective right or left arm. In some embodiments the deformable sidepiece as a planar member which is configured to be selectively deformed out of plane so as to conform about the facial contours of a user, for example, to hold a shape corresponding to the curvature of the user's cheeks. It will be appreciated that this deformable sidepiece represents a potentially uncomfortable situation wherein the deformable sidepiece could be pressed into the user's face. As such, a malleable cover, such as fabric or neoprene can be provided and configured to encompass the deformable sidepiece.
In some embodiments the nasal pillow assembly can further include an attachment sleeve configured to engage with each of the right and left arms respectively and encompass the associated aperture. The attachment sleeve can thus be configured to provide rotation of each pillow assembly about its respective arm without obstructing flow through the respective aperture. In some embodiments the attachment sleeve includes a radial hose connection for interfacing with its respective nasal pillow. This radial hose connection can be configured to allow for axial adjustable along the radial hose.
In yet other embodiments the attachment sleeve can be provided with one or more washout vents. Alternatively, washout vents can be provided at distal ends of the right and left arms, or about the core, or in any combination of the same.
In some embodiments the nasal pillows can formed in the shape of a cone, the cone having an elliptical cross section. In this manner as the pillows are rotated about a central pillow axis, or about the axis of the radial hose the relative orientation of each pillow can be adjusted so as to match the nostrils or nares of the user.
In some embodiments the headgear can include a plurality of adjustable straps so as to be adjustable to provide a desired retention force or a desired sealing force as well as be customizable so as to match the specific contours of the user's head. In some embodiments one strap can be configured to extend over a crown of the user's head, and in other embodiments a strap can be configured to extend behind a rear portion of the user's head, or both.
The mask and headgear assembly of claim2, wherein the deformable sidepiece attaches to each arm using an interference interconnector comprising a male connection and a female connection located selectively about either the deformable sidepiece or the interference interconnector.
In some embodiments the inlet connector can includes a swivel connector so as to provide a certain degree of flexibility with respect to an air supply hose and the mask frame provided about the user's face, for example if the user shifts while sleeping.
In some embodiments the core can be provided with a heat moisture exchange (HME) located within the central portion. Alternatively, the HME can be provided within the air supply hose, or within the right or left arms
In yet additional embodiments a method of providing a pressurized stream of air using the device described above is contemplated. The method can include various steps, in varying combinations including: providing a supply of pressurized gas to a delivery tube; receiving the supply of pressurized gas at an inlet of a core; selecting a pair of properly sized nasal pillows from a plurality of various nasal pillows, each nasal pillow having a pillow aperture formed at a top end; affixing the pair of nasal pillows to the core over the respective apertures of each arm such that the air pathway extends through the pillow aperture of each pillow; and positioning the nasal pillows such that the air pathway extends to a user's respiratory system through the nasal pillows through the user's nares.
The method can also include the steps of: affixing a headgear assembly to distal ends of both the right and left arms; and rotating the nasal pillows such that the elliptical cross section coincides with the user's particular nare shape, wherein each of the nasal pillows has an elliptical axial cross section.
These and other embodiments form some of the various inventive concepts as contained herein. The individual embodiments as described are not intended to be limiting, but are intended only as illustrative of the various inventive concepts and are not intended to be limiting except as claimed below.
BRIEF DESCRIPTION OF THE DRAWINGSThe foregoing and other objects, aspects, features, and advantages of the disclosure will become more apparent and better understood by referring to the following description taken in conjunction with the accompanying drawings, in which:
FIG. 1 illustrates a perspective view of a facial interface and headgear system for use with ventilation and positive air pressure systems;
FIG. 2 illustrates a front exploded view of the facial interface and headgear system for use with ventilation and positive air pressure systems ofFIG. 1;
FIG. 3 illustrates a core or mask frame structure for use with the facial interface and headgear system for use with ventilation and positive air pressure systems ofFIGS. 1-2;
FIG. 4 illustrates an exploded view of the core or mask frame structure ofFIG. 3 illustrating a swivel adapter and heat moisture exchange component.
FIG. 5 illustrates an exemplary headgear system attached to the core or mask frame structure ofFIG. 3;
FIGS. 6A-E illustrate various exemplary nasal pillows and configurations for use with the ventilation and positive air pressure systems ofFIGS. 1-2;
FIG. 7 illustrates a top view of the ventilation and positive air pressure systems ofFIGS. 1-2;
FIG. 8 illustrates an exemplary embodiment of a potential headgear connection interface for use with the ventilation and positive air pressure systems ofFIGS. 1-2;
FIG. 9 illustrates another exemplary embodiment of a potential headgear connection interface for use with the ventilation and positive air pressure systems ofFIGS. 1-2;
FIG. 10 illustrates a fitting for the potential headgear connection interface ofFIG. 9;
FIG. 11 illustrates another alternative fitting for the potential headgear connection interface ofFIG. 9;
FIG. 12 illustrates a perspective view of an assembly procedure using the headgear connection interface ofFIG. 9;
FIG. 13 illustrates a perspective view of an assembly procedure of yet another exemplary embodiment of a potential headgear connection interface for use with the ventilation and positive air pressure systems ofFIGS. 1-2;
FIG. 14 illustrates an alternative perspective view of the assembly procedure of the embodiment ofFIG. 13;
FIG. 15 illustrates a perspective view of a user wearing yet another exemplary embodiment of a potential headgear connection interface for use with the ventilation and positive air pressure systems ofFIGS. 1-2;
FIG. 16 illustrates a perspective view of the assembled exemplary embodiment of a potential headgear connection interface ofFIG. 15;
FIG. 17 illustrates a perspective exploded view of the exemplary embodiment of a potential headgear connection interface ofFIG. 15;
FIG. 18 illustrates a perspective view of an assembly procedure of the exemplary embodiment of a potential headgear connection interface ofFIG. 15;
FIG. 19 illustrates a perspective view of another portion of the assembly procedure of the exemplary embodiment of a potential headgear connection interface ofFIG. 15;
FIG. 20 illustrates a perspective view of a user wearing yet another exemplary embodiment of a potential headgear connection interface for use with the ventilation and positive air pressure systems ofFIGS. 1-2;
FIG. 21 illustrates a perspective exploded view of a yet another exemplary embodiment of a potential headgear connection interface for use with the ventilation and positive air pressure systems ofFIGS. 1-2;
FIG. 22 illustrates a perspective view of yet another partially assembled exemplary embodiment of a potential headgear connection interface for use with the ventilation and positive air pressure systems ofFIGS. 1-2; and
FIGS. 23A-C illustrate exploded side and front views, respectively, of an alternative core or mask frame assembly for use with the ventilation and positive air pressure systems ofFIGS. 1-2.
FIG. 24 illustrates variable core or mask frame with pivoting arms.
Reference will now be made to the exemplary embodiments illustrated, and specific language will be used herein to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended though the exemplary embodiments discussed, but the examples are for purposes of illustration of the inventive concepts.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTTo provide an overall understanding of the systems, devices, and methods described herein, certain illustrative embodiments will be described. Although the embodiments and features described herein are frequently described for use in connection with CPAP apparatuses, systems, and methods, it will be understood that all the components, mechanisms, systems, methods, and other features outlined below may be combined with one another in any suitable manner and may be adapted and applied to other PAP apparatuses, systems, and methods, including, but not limited to, APAP, VPAP, and BPAP apparatuses, ventilators, systems, and methods.
The present application seeks to provide a solution to the aforementioned problems by creating an adjustable, comfortable, mask assembly system that has interchangeable components, light-weight, and adaptable to individual users.
FIGS. 1-2, and 7 illustrate various views of a positiveairway pressure assembly10 configured to aid in supplying a stream of positive pressure air to the airways of a patient wearing theassembly10. The assembly includes amask frame300 having a pair ofnasal pillow assemblies100 attached thereto. Themask frame300 receives a stream of pressurized air from a blower (not shown), which can be attached to themask frame30 by means of asupply hose30. The air then travels through themask frame30 throughapertures354 and through the associatedpillow assemblies100 to provide air into the nostrils or nares of the user wearing the positiveairway pressure assembly10.
The positiveairway pressure assembly10 can optionally include aheadgear system20 configured to provide a sealing force between theindividual pillow assemblies100 and the nostrils of the user. In certain cases theheadgear system20 can also provide a positioning force between themask frame300 and the maxilla of the user or patient, for example on the portion of the face between the upper lip and below the nose. It will be appreciated that theheadgear assembly20 can be formed of a resilient material, or be adjustable through various means so as to conform to the individual user's contours which, understandably, vary between various users. Further, theheadgear assembly20 can also be configured to affix to distal ends of themask frame300 and can be configured to provide a certain degree of rotational adjustment between themask frame300 and theheadgear20.
As shown in various figures,headgear20 may be comprised of multiple straps, such as one configured to go over the top portion of a user's head, and second strap going generally about the back portion of a user's head. Either strap can have an adjustment mechanism, no adjustment mechanism, formed of resilient material, inflexible or formed in a variety of configurations including having a cover or sleeve formed over a portion of the straps or no cover or sleeve.
FIGS. 3-5 illustrate various aspects of themask frame300. It will be appreciated that air supply travels as shown bypathway arrows60 through the tube, through a central portion of themask frame300 and exits apertures354. The apertures can have a pair of lips orshoulders358 upon or about which thepillow assembly100 fromFIGS. 1-2 can rest and seal. Themask frame300 can have acentral portion310 and left and right arms extending therefrom,362 and364 respectively. Each of the right and left arms can be provided with aheadgear connection interface400 about their respective distal ends. The headgear connection interface allows for variation in the types of connectors used for connecting the headgear (not shown here).
In some embodiments, the right and left arms can be provided as co-axial, i.e. straight with respect to each other, so as to reduce fabrication complexity and cost. Alternatively, and as shown herein the right and left arms can be angled with respect to one another so as to better conform in shape to the front of the user's face, which understandably typically has a curved profile.
In addition the mask frame orcore300 can be provided with aninlet connector322 about the central portion. The inlet connector can be configured to swivel coaxially with theair supply hose30. In addition the core ormask frame300 can be provided with a heat moisture exchange (HME) component within thecore326 about theinlet connector322. TheHME326 can also be provided in alternative locations as well as in multiples, for example a pair ofHME326 units could be provided within the nasal pillow assemblies or more proximal theapertures354.
In particular,FIG. 5 illustrates how the headgear can be affixed to the core ormask frame300 through the use of one embodiment of aheadgear connection interface400. This particular embodiment illustrates a swivel connection which allows the headgear to rotate with respect to the distal ends of themask frame300.
FIGS. 6A-E illustrate various views of anasal pillow assembly100 for use with the nasal mask frame as shown inFIGS. 3-5. Thenasal pillow assembly100 can include anasal pillow110 andattachment sleeves150. Theattachment sleeves150 in this embodiment are configured to slide over themask frame300 and seal overapertures354 by having aninner shoulder359 which abuts against and slidingly seals against theshoulders358 as shown inFIG. 3. In this manner, the air delivered to the mask frame can be redirected through thepillow assembly100 and into the user's nares. Theattachment sleeve150 can be provided with anattachment portion154 for receiving thepillow110. Theattachment portion154 can be provided with a series of ribs or channels configured to interface with a plurality of annular ribs114 and/or channels provided on an annular tube (or stem) forming an attachment portion of eachpillow110.
In particularFIG. 6D illustrates an air conformbladder162 which can be formed as part of theattachment sleeve150. The air conformbladder162 can be formed of a malleable or flexible material, and have a hollow cavity defined thereby which receives pressurized gas from the interior of theattachment sleeve150 when attached to the mask frame (not shown here). In this manner, as the pressure rises or is increased when the system is on, the air conform bladder becomes partially inflated and acts similar to a balloon. The air conformbladder162 can then rest against the maxilla and provide an air cushioned interface between the mask and the user's face. In some embodiments, the air conform bladder is formed directly on the core frame, as part of the nasal pillows devoid of an attachment sleeve, or a part of the attachment sleeve itself that can form in part the nasal pillow assembly.
The meshing or integration of the annular ribs114 with the channels orribs154 provided in the attachment sleeve allows for incremental adjustment of the relative height or radial positioning of thenasal pillow110 with respect to theattachment sleeve150, and thereby the mask frame or core, by changing which ribs are meshed with which respective channel. In this manner each nasal pillow can translate axially with respect to a pillow axis thus providing a first degree offreedom104A. Additionally, the ribs and channels can slide with respect to one another when twisted about the pillow axis providing a second degree offreedom104B which is rotational about a central axis of each pillow. Finally, theinterior shoulder359 can also slide with respect to its relative exterior shoulder of themask frame358 as shown inFIG. 3. so as to allow the sleeve, and the associated pillow to rotate about the axis of the right or left arm thus providing a third degree of freedom104C. This sealinglip359 allows for theattachment sleeve150 to rotate about the mask along the mask frame axis thus providing a third degree of freedom104C. Additional flexibility in the system can come from the nasal pillow itself. For example, the base portion of the nasal pillow, which functions like a trampoline or pivoting spring allows for the head or conical portion of the nasal portion to tilt or pivot about the stem or annular tube. This is made possible by varying the thickness or durometer of the base portion with respect to the head or conical portion and the stem or annular tube.
FIG. 8 illustrates another embodiment of theheadgear connector400A which utilizes a contouredbarb404 and acorresponding barb receiver408. The barb can have a plurality of shapes including semi-spherical shapes as shown, or any other conceivable geometric shape with a correspondingly shaped receiver. In this embodiment the receiver is configured to be deformable or resilient so as to expand to initially accept thebarb404 when press therein. After thebarb404 is pressed into the receiver, an interference fit is formed and the barb will resist, to a certain degree, being pulled from thereceiver408.
FIGS. 9-12 illustrate yet another embodiment of aheadgear connector400C which utilizes aconnector412 which has two ends, one for attaching to the distal end of the mask frame orcore300, and the other for interfacing with theheadgear20. The headgear interfacing end is provided with anaperture414 configured to receive aclip barb416. The core end of theconnector412 has another correspondingaperture416 through which aplug428 can be provided so as to affix theconnector412 to thecore300. The two ends of the connector can be configured to rotate with respect to one another, as illustrated betweenFIGS. 10 and 11, so as to provide additional comfort to the user and allow the strap of the headgear to rest naturally with respect to the distal ends of the mask frame.
FIGS. 13-14 illustrate yet another embodiment of aheadgear connection interface400E in which a strap of theheadgear20 is provided with a simpleannular washer end436. Aplug432 can then be provided theannular washer end436 and have an interference fit with a correspondingplug adapter end434 provided about the distal ends of themask frame300.
FIGS. 15-19 illustrate various views of yet another embodiment of aheadgear connection interface400G in which a strap of theheadgear20 is provided with adeformable side piece500 provided between theheadgear20 and themask frame300. Thedeformable sidepiece500 can attach to each arm using an interference interconnector comprising amale connection518 and afemale connector514 as well as attached to theheadgear20 by means of amale connector522 andfemale aperture524. It will be appreciated that the relative male of female connectors or apertures can be located selectively about either the deformable sidepiece or the interference interconnector. As shown, thedeformable sidepiece500 can be configured to attach to the each respective arm at various angular positions, or in other words rotate with respect to themask frame300. Additionally, thedeformable sidepiece500 can be provided initially as a planar member, which can then be selectively deformed out of plane so as to conform about the facial contours of a user. In this manner the deformable side piece can be shaped so as to follow the contours of the user's cheeks without touching them, or alternatively touch the cheeks but equally distribute any pressure applied thereto.
It should be understood that of the various connectors described herein, some versions are configured to have the headgear connect to the mask frame in a fixed connection (non-rotating), some allow for free rotation connection (no interference or stops), and some have interference mechanisms to selectively rotate or be positioned angularly about the mask frame.
In one instance the deformable sidepiece is formed of a shape retaining plastic. This plastic can have a general deformation characteristic along a single plane while maintaining some rigidity in a second plane. Other types of deformable plastic can be deformed along multiple planes. In one embodiment the cross-section of the deformable sidepiece is rectangular. The curvature of the deformable sidepiece along a particular plane (seeFIGS. 15 and 17) can be preset or formed to transfer the force of the head gear system around certain features of the user's face. Since user's faces have three-dimensional features the deformable sidepiece can then conform to the remaining features of the user's face. Thus, allowing a customizable headgear system that maintains a balance between rigidity and flexibility, while being conformable to a user's unique facial features.
It will be further appreciated that thedeformable sidepiece500 might cause a certain degree of discomfort to a user. As such, amalleable sleeve510 can be provided which encompasses thedeformable sidepiece500. The malleable sleeve can be formed of fabric, silicone, or other comfort increasing material having any number of desired attributes, such as heat transfer rate, elasticity, softness, etc.
FIG. 20 illustrates adeformable sidepiece500A which has asilicone shell560 having a malleable shape retaining core.
FIG. 21 illustrates yet anotherheadgear connection interface400H which includes akeyed post440 located about a distal end of themask frame300 and keyed opening442 which slid through the keys to aninner portion442 with a smaller diameter which allows free rotation. The assembly can only be separated when angularly positioned correctly so as to align the keys. It will be appreciated that the keys should be provided out of phase from each other in normal angular positions between themask frame300 and theheadgear20 while being worn. In order to ensure that the keyed components do not separate unintentionally, acap444 can be provided which prevents unintentional separation.
FIG. 22 illustrates another keyed embodiment, similar to that ofFIG. 21. having analternative strap portion442A, which covers the hardware, i.e. thekeyed post440 and the associated connector inside thestrap442A, so as to improve comfort and reduce the likelihood of catching the mask on something while shifting during sleep and thus tearing the mask off the user's face. This embodiment utilizes asimilar plug444A to cover the connection from the outside of thestrap442A and thus prevent premature decoupling or catching.
FIGS. 23A-C illustrate an alternative embodiment of amask frame600. This mask frame is more rigid and instead of interfacing with thenasal pillow assembly100 using a rotatable sleeve, the arms ofmask frame600 are rigid and do not provide rotation of thepillow assemblies100 about the respective arm portions. This embodiment provides increased stability for headgear attachment and facial placement purposes. In this embodiment the nasal pillows are still permitted to rotate about the pillow's central axis, wherein the pillows can have an elliptical cross section.
In this embodiment a plurality of washout vents604 can be provided in a central portion of themask frame600. Additionally, theheadgear20 can be attached to themask frame600 using any of the previously discussed headgear attachment interfaces.
FIGS. 6E, 21 and 23A all show various placements of CO2washout vents. Being at a bottom portion of thepillow assembly100, on theattachment sleeve150 as shown by158 inFIG. 6E, at the ends of the right or left arms, as shown by159 inFIG. 21, and on the mask frame at a central portion as shown by604 inFIG. 23A. It will be appreciated that any one of these placements either alone or in any combination is within the scope of the present invention. The CO2washout vents may be comprised of a material that has silicone knife coated across it. In other embodiments the CO2vent is a plurality of holes that have been formed therein.
It is contemplated that the wall thickness and/or durometer of the nasal pillow portion can be varied. In one exemplary embodiment the flat underside portion which connects the bell like top of the nasal pillow to the tube portion may have either a thinner wall portion then the flared bell like portion and tube portion or may have a lower durometer value. This thinner wall or lower durometer value allows the tube connected to the flat underside to collapse into the bell like portion when pressure is exerted on the bell like portion. When the nasal pillows are formed of the silica material or silken like material the nasal pillow returns to its original state when no pressures being exerted on it. Again this allows for the flared bell like portion to pay that about the tube portion when being inserted into the nasal region. The collapse ability again helps reduce pressure exerted onto the nasal region while at the same time helping to find an optimal position that forms a good seal between the nasal pillow and each of the nostrils.
It will be appreciated that in certain embodiments the headgear can cause a direct tightening of the pillows into the nostrils of the user, thus having a direct correlation to a sealing force. In yet other embodiments, for example, when providing an air conform bladder, as discussed with reference toFIG. 7, the force applied by the headgear can be partially directed through the air conform bladder and into the maxilla to provide a primarily a positioning force, where the sealing force can be adjusted by changing the relative placement of the mask frame on the face, which is held by the positioning force. In yet additional embodiments, the nasal pillows can be caused to enter into, and hold their relative position by the elastic properties of the pillows being exerted onto the inner walls of the user's nostrils or nares without the use of headgear altogether.
FIG. 24 illustrates another alternative core ormask frame300A where the right and left arms are arranged to pivot or rotate about the center of the core. In some versions the right and left arms can form a 180 degree angle between each other, making the core look more like “T” shape, each arm can then be repositioned to form a “Y” shape. The angles between each arm can range from several degrees to greater than 180 degrees. However, most users will have the arms angled somewhere less than 180 degrees. This additional degree of freedom presented by thisalternative core300A can also work with the attachment sleeves, rotatable nasal pillows as described above for a customizable fit.
In some versions the rotation of the arms is a constant and consistent motion, which can be enabled by a pressure sliding fit between the pivoting arm and the core. In other versions discrete angled positions are enabled by each arm locking into a groove or channel or other distinct locking mechanism. Some of the rotation mechanisms can function similar to the locking and rotation features of the headgear interface assembly.
While the forgoing examples are illustrative of the principles of the present invention in one or more particular applications, it will be apparent to those of ordinary skill in the art that numerous modifications in form, usage and details of implementation can be made without the exercise of inventive faculty, and without departing from the principles and concepts of the invention. Further, discussion with regard to any of the specific features is intended to be for illustrative purposes, with the understanding that any feature discussed herein can be used in combination with any number of other features in any combination from any of the various embodiments. Accordingly, it is not intended that the invention be limited, except as by the claims set forth below.