FIELD OF THE INVENTIONThis invention relates to systems for obtaining physiologic fluid samples. More particularly, a test system for obtaining and testing blood samples with minimum user effort is described.
BACKGROUND OF THE INVENTIONAnalyte concentration determination in physiological samples is of ever increasing importance to today's society. Such assays find use in a variety of application settings, including clinical laboratory testing, home testing,etc., where the results of such testing play a prominent role in the diagnosis and management of a variety of disease conditions. Analytes of interest include glucose for diabetes management, cholesterol for monitoring cardiovascular conditions, drugs for monitoring levels of therapeutic agents or identifying illegal/illegal levels of drugs, and the like. In response to this growing importance of analyte concentration determination, a variety of analyte concentration determination protocols and devices for both clinical and home testing have been developed
In determining the concentration of an analyte in a physiological sample, a physiological sample must first be obtained. Obtaining and testing the sample often involves cumbersome and complicated procedures. Unfortunately, successful manipulation and handling of test elements, lancing members, meters and the like is to a great extent dependent on the visual acuity and manual dexterity of the user, which in the case of people with diabetes is subject to deterioration over the course of the disease state. In extreme cases people that have significant loss of sight and sensation, testing procedures can become significantly difficult and requires additional assistance from ancillary devices or personnel.
A typical procedure involved with making a glucose measurement involves the following actions or steps (but not necessarily in the order given):
- 1) removing supplies from a carrying case,
- 2) removing a lancing device loading cap or door,
- 3) removing and disposing of an old lancet form the lancing device,
- 4) inserting the lancet in the lancing device,
- 5) twisting off a protective cap from the lancet,
- 6) replacing the lancing device cap.
- 7) cocking the lancing device,
- 8) opening a test strip vial/ container,
- 9) removing a strip from the container and inserting or interfacing it with a meter,
- 10) holding a lancing device to the skin,
- 11) firing the lancing device,
- 12) lifting the lancing device and setting aside,
- 13) extracting a sample,
- 14) applying sample to the test strip and getting results,
- 15) disposing of the test strip,
- 16) cleaning the test site, and
- 17) returning supplies to the carrying case.
Sometimes fewer steps are involved. One manner of reducing the number of actions is by integrated devices set to combine multiple functions.
In this regard, certain test strip dispensers are configured to both store and advance successive test strips upon actuation. Examples of such devices are presented in
U.S. Patent Nos. 5,510,266;
5,575,403,
5,797,693 and possibly in
PCT Publication WO 01/63272. In addition some dispensers also include meter functionality. Examples of such of systems that integrate test strip meter and dispenser combination functions are disclosed in
U.S. Patent No, 5,736,103,
5,757,666 and
PCT Publication WO 99/44508. Furthermore, the device described in
WO 01/23885 includes all of the above features, plus a receptacle to receive spent test strip elements that are cut off of a continuous roll of the same.
US 2002/0052618 discloses an analyte detection system comprising a body portion, a magazine containing plural analytical devices, each including a test strip and a lancet, a plunger to pick an analytical device from the magazine and move it into an analysis position, and a lancing mechanism that is moveable to engage the lancet of the selected device so as to urge the lancet past a face of the body portion to penetrate a tissue site.
Another class of devices designed to decrease the number of steps required in test strip use includes automatic or semi-automatic lancing devices.
U.S. Patent No. 6,228,100 discloses a structure configured for sequential firing of a number of lancets, one at a time, in order to eliminate the requirement that a user remove and replace each lancet individually before and after use.
WO 01/00090 discloses a lancing device comprising a body portion, a magazine containing plural lancets, an indexing mechanism for indexing the lancets to an operative position, and a lancing mechanism that is moveable to engage a lancet in the operative position so as to urge the lancet past a face of the body portion to penetrate a tissue site.
The device disclosed in
U.S. Patent No. 5,971,941 attempts to combine the functionality of each of the preceding classes of test strip devices. In effort to provide an "integrated" system for sampling blood and analysis thereof, it includes a magazine of test strips, test strip advancement and dispensing features, a meter with a display and an automated lancing mechanism all housed with a single box. While presenting some measure of advance in user convenience, the test strip and lancing features are removed from each other causing the user to take two steps in lancing and transferring sample to a test strip. Furthermore, the device includes no provisions for used test strips.
While certain combination test strip and lancing systems that do not require that a subject to move the device relative to the sample site in use (
e.g., the systems described in
U.S. Patent Nos. 6,352,514;
6,332,871;
6,183,489;
6,099,484;
6,056,701 and
5,820,570), some of these systems are quite complex and, consequently, either difficult to operate or costly to produce. In addition, some involve changing-out spent test and/or lancet members one-at-a-time. This is true with respect to the systems described in
U.S. Patent Nos. 6,027,459;
6,063,039;
6,071,251 and
6,283,926 as well as for certain embodiments disclosed in
PCT Publication WO 01/64105.
However, another embodiment presented in that reference provides for multiple lancet/sensor pairs that only need to be changed out after the disks including each are spent. An exemplary number of a dozen such radially-oriented pairs is provided.
WO 02/49507 also discloses a meter including a multiple sensor/tester element. Fluid extracted from a subject by a microneedle at a common entrance port is selectively switched between a number of microchannels by means of electro-osmotic pumps and hydrophobic gates. The present invention is distinguished from each of these inventions in terms of its modular use of combination test strip and sensor elements, in which unexposed items may be sealed-off from contamination, and possibly provided in greater number, as well as in the simplicity of the present invention which preferably involves mechanical movement for sample acquisition and handling.
Of course, such advantages may be present in systems according to the invention in various degrees. It is intended that, in one way or another, the invention is of assistance in reducing barriers to patient self-monitoring and therefore result in improved outcomes in the management of disease, such as diabetes.
SUMMARY OF THE INVENTIONAccording to the invention, there is provided an analyte, detection system as set forth in the accompanying claim 1.
The present invention facilitates a method for analyte test strip use that merely involves four user steps. These include: providing a system according to the present invention, placing it against a test site, pushing the system body portions together and reading a test result. The system is then removed and put away. It may include a cap to be removed initially and replaced finally. Methods disclosed herein are not claimed.
In a preferred variation of the invention, such a cap includes a magazine that automatically receives spent or used test strips. In another variation of the invention (one in which test strips are merely ejected) a user disposal step may be added.
The system of the present invention utilizes disposable test strip elements that include an integral lancet. Examples of such strips include those described in
EP-A-1 281 352,
EP-A-1 284 121 and
European patent application No. 03252879.6, claiming priority from
USSN 10/143,399 filed on 9th May 2002 now
published as EP-A-1 360 931. The needle may be configured to collect blood, interstitial fluid, other body fluids, or any combination thereof. Regardless of the type of strip chosen and sample to be collected, the members are stored in a magazine, from which they are fired to produce a wound to receive sample therefrom.
The action provided by the meter/dispenser of the present invention is preferably implemented by a series of links, levers and spring elements such that advancement of an upper body portion relative to a lower body portion resting against a test site causes a test strip to be taken from the magazine advanced to form a stick and collect sample. Following such action, the meter may be removed, test results are displayed and such action as desired to dispose of the used test strip occurs.
BRIEF DESCRIPTION OF THE DRAWINGSEach of the figures diagrammatically illustrates aspects of the invention. To facilitate understanding, the same reference numerals have been used (where practical) to designate similar elements that are common to the figures. Some such numbering has, however, been omitted for the sake of drawing clarity.
Figures 1A, 2A,3A, 4A,5A, 6A,7A, 7C,8A, 9A and10A are perspective views of system(s) according to the present invention at various stages of operation.
Figures 1B, 2B,3B, 4B,5B, 6B,7B, 7D,8B, 9B and10B are top-down cross sectional views of system(s) according to the present invention at various stages of operation.
Figures 11A and 11B are perspective views of a preferred test strip for use in the present invention;figures 12A and 12B are perspective views of another preferred test strip for use in the present invention.
DETAILED DESCRIPTION OF THE INVENTIONIn describing the invention in greater detail than provided in the Summary above, details of an embodiment of the invention together with aspects of system use. Two alternate variations of the invention are described in this manner, though other variations are possible. Finally, examples of a preferred test strip for use in the device are disclosed.
Before the present invention is described in such detail, however, it is to be understood that this invention is not limited to particular variations set forth and may, of course, vary. Various changes may be made to the invention described and equivalents may be substituted without departing from the true scope of the invention as defined by the accompanying claims. In addition, many modifications may be made to adapt a particular situation, material, composition of matter, process, process act(s) or step(s), to the objective(s), spirit or scope of the present invention. All such modifications are intended to be within the scope of the claims made herein.
Methods recited herein may be carried out in any order of the recited events which is logically possible, as well as the recited order of events. Furthermore, where a range of values is provided, it is understood that every intervening value, between the upper and lower limit of that range and any other stated or intervening value in that stated range is encompassed within the invention. Also, it is contemplated that any optional feature of the inventive variations described may be set forth and claimed independently, or in combination with any one or more of the features described herein.
All existing subject matter mentioned herein (e.g., publications, patents, patent applications and hardware) is provided solely for their disclosure prior to the filing date of the present application. Nothing herein is to be construed as an admission that the present invention is not entitled to antedate such material by virtue of prior invention.
Reference to a singular item, includes the possibility that there are plural of the same items present. More specifically, as used herein and in the appended claims, the singular forms "a," "and," "said" and "the" include plural referents unless the context clearly dictates otherwise. It is further noted that the claims may be drafted to exclude any optional element. As such, this statement is intended to serve as antecedent basis for use of such exclusive terminology as "solely," "only" and the like in connection with the recitation of claim elements, or use of a "negative" limitation. Last, it is to be appreciated that unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.
Device and System UseTurning now toFIGS 1A and 1B an exemplary system2 according to the present invention is disclosed. The device is a meter that includes actuation features for firing test strips4. A screen6 is provided to display meter results and/or direct user action in connect with system2 use. Other externally visible features include optional adjustment knob8, cap10 and interlock button12.
Whether all or none of these optional features are included, system2 comprises an upper body portion14 and a lower body portion16. As shown inFIG 2A, the lower body portion is exposed upon removal of cap10.
In operation, lower body portion16 is slidingly received by upper body portion14. The relative motion between these two members actuates the various elements within system2. As described further below, the mechanism enables combination of two steps involved in lancing: namely the cocking of the launcher mechanism and the release of the launcher. Specifically, a single motion first cocks the mechanism and later releases the cocked mechanism. This design approach is similar to that of a center punch used in creating an indentation on a surface. In combination with a test strip integrating a biosensor and lancet, pressing system2 against the surface of the skin leads to a single step in performing a procedure that normally involves in excess of 10 to 15 steps.
As shown inFIGS 1A and 1B, system2 is in an "off " mode. In this mode, knob 8 is preferably actuated by turning clockwise or counterclockwise to set the depth, or any other variable that may be necessary to adapt to a specific user (e.g., force on a pressure-ring), to which a lance portion18 of test strip4 will fire relative to a face20 of the system. Face20 may serve as such a "pressure ring" in that when it is applied to the skin surface, it depresses tissue around a periphery of the intended wound site. The force on pressure ring may be dictated by the compression force to slide the lower portion into the upper portion; upon application of this force, the test strip is typically also launched into the skin. The pressure formed at the site to be lanced, resulting at least in part from stretching the skin in this area, is useful for extracting a sample in that it helps "pump" material from the wound produced.
Wound/penetration depth is preferably set to between about 0.02 mm and 2.0 mm, or more preferably set between 0.5 mm and 1.5 mm, by virtue of a screw-type interface22 which advances or retracts an extension24 carrying a stop portion26. Such adjustment action usually accomplished at this stage is indicated by the use of bold in connection with the elements at issue.
FIGS 2A and 2B show cap10 being removed from system2. It is slidingly received by lower body portion16. Detent features may be provided in order to prevent inadvertent separation of the elements.
Removal of cap10 preferably turns the system "on" as indicated inFIG 2A. Where no cap is provided, another preliminary action may be required to activate the system (such as depressing a button) or system2 could be activated by subsequent activity that is described.
In any event, as shown in the other figures, various user directions or messages may be displayed by the meter. In addition to displaying test results and directions, display6 may present information regarding the number of test strips left, time to expiration,etc.
FIG 3B illustrates actuation of button12 for a different purpose (though, it could be used to turn the system on as well). When a user depresses button12 as shown, an interlocking interface28 formed by an extension30 of button12 and another extension32 of lower body portion16 is released. A spring member34 may be provided to bias the button outwardly.
Any form of spring may be used in this regard. The same is true for other springs employed in the invention. By varying the internal configuration of system2 flat springs, leaf springs, coil springs, torsion springs or extension springs may be used. What is more, metal or polymer spring members may be interchangeably used.
Regardless of such constructional details, with face20 exposed and interlock or safety mechanism28 set free (most preferably by depressing button12) the face is set against a target site. Such a target site might be a patient's or user's finger, forearm, palm, or elsewhere.
With system2 so positioned an "apply" message may appear on screen6 as shown inFIG 4A. Whether prompted in this manner or not,FIG 4B shows the next action taken by a user. Here, upper body portion14 is pushed toward the target site. This causes system2 to collapse, with lower body portion16 slidingly received within upper body portion14.
Such user activity results in several actions within device 2. For one, interlock portions28 and32 slide past each other (instead of interfering with each other's movement). In addition, a lancing mechanism36 within system2 is cocked. This is accomplished by stressing launch spring38. While this may be accomplished otherwise, in the variation of the invention shown here, a lever arm40 driven by a cocking extension42 of lower body portion16 provides the input. A lance interface member44 is held in a cocked position by a latch46 and cooperative catch48 at one end of the interface member.
At the other end of interface member44, test strip interface features50 are provided. These pick up or interface with a test strip4. As shown, interface features advance a test strip slightly relative to other test strips contained within a magazine52.
The magazine may be configured in any convenient manner to allow loading of a large number of test strips therein (e.g., between about 10 and 100, more preferably between 15 and 25) and release therefrom. Providing numerous test strips as possible in view of the magazine format employed by the present invention allows for greatly increased user convenience.
Magazine52 is preferably spring-loaded in order to function properly regardless of orientation. The magazine preferably has a door136, which remains closed except during brief periods of time when the test strip is removed, serves as a moisture barrier. (A similar door or barrier may be provided for waste magazine22). Also, a drying agent (e.g., a desiccate) may be contained within the magazine to protect the test strips' reagent from moisture. To further preserve the integrity of unused test strips, the mechanism driving the test strip and operating the door is preferably configured so it will not leave a test strip partially advanced or the magazine open if the user were not to complete the total relative motion of sliding lower portion16 into upper portion14.
The magazine, may take the form of a removable cartridge or cassette as shown inFIG. 10A described further below. Especially under such circumstances, it may contain a barcode or some other means (such as a chip) for transferring information to the meter upon loading the same with test strips or a strip cartridge. In which case, the meter would automatically read this information when the magazine/cartridge is loaded into the system, via an optional detection system138 (shown inFIG. 10B). Any conventional reader or placement as appropriate to the media by which the information is expressed may be employed. Regardless of such constructional details, examples of information that may be useful include: a calibration factor or code, number of strips remaining/used in magazine, number of days since magazine was installed and/or days until strip expiration (such as a hard date or a date that is a function of when the magazine was loaded into the system).
Further optional feature(s) that may be included in meter2 include diagnosis or calibration system(s). For example, system2 may include features to determine if it is working properly in reference to one or more control species, such as a control solution comprising glucose of a known concentration.
The relative motion between body portions14 and16 also results in cocking or loading a return spring54. Its use will be described further below.
FIGS 5A and 5B, show activity in connection with lance/test strip firing preceding such action. In one variation, motion of the lower body portion16 cams latch46 to release spring loaded interface member44 to travel, push magazine door136 open, and pick-up a strip to advance it out of the magazine. Alternately, an electronic solenoid (not shown) activated by electronics included in system2 can be utilized to release latch46, whereupon interface member44, together with test strip4 advances as indicated. As it advances toward the skin, interface member44 preferably urges the test element through guides78.
In use, since only the needle end of a test element/strip comes in contact with a user, the opposite end of the device adjacent interface member44 does not into contact with body fluids. Accordingly, this element is not able to contaminate unused test strips upon retraction past the same. Further, magazine door136 is opened only for a very short time period, thereby minimizing opportunity for contamination. In addition (as further described below), used test strips are ejected from the system or stored in a (sealed) magazine in the cap and are never brought near the magazine. All of these factors may contribute to maintaining unused test strip quality.
A tip56 of the lance portion of the test strip is shown protruding slightly from the face20 of system2. As shown inFIG 5A, the meter screen preferably directs a user to hold the device in place. This allows time for sample collection from the wound produced, such as by a pressure-ring to force fluid from the wound and capillary action along the lance member18. Still, it is to be noted that other driving forces, such as vacuum, may be employed to facilitate sample acquisition.
Following a sufficient time interval, (e.g., usually between about 0.1 and 15 seconds, preferably less than 3 seconds), as shown inFIG 6A, the system preferably directs the user to remove system2 from the test site. By such action, as shown inFIG 6B, lower body portion returns to its pre-compressed state. Preferably return spring54 urges the body portions away from each other as shown. As the body portions separate, an interface member return catch58 withdraws interface member44. Catch58 is preferably provided at an end of a return member60 that is actuated by lever40, which is, in turn, associated with lower body portion16. Pivoting interface portions62 are preferred, though the parts may be integrally molded with living hinge sections or otherwise produced.
In addition to showing the movement of the body portions relative to each other in an intermediate state,FIG 6B shows a test strip disposal mechanism64 as it swings into position for action. The mechanism may comprise a pusher arm66 with a stop or interface portion68, a lever arm70 and an intermediate link72. These members may also be spring-loaded. Furthermore, there construction may vary in like manner to the other components noted directly above.
In order for the members of the disposal mechanism to reach the location shown inFIG 6B, as it progresses to that shown inFIG 7B (or 7D), certain antecedent actions may have occurred. These are illustrated in connection withFIGS 1B, 2B and4B.
InFIG 1A, disposal mechanism64 is shown at a rest position. A protrusion74 at the end of lever arm70 is interfaced with a complementary pusher portion76 of cap10 (seeFIG 1B). Upon removal of the cap, the disposal mechanism moves to the position shown inFIG 2B. From here, it is able to swing out of the way of lance firing as shown inFIG 4B. Ultimately, as illustrated inFIG 6B, it moves into position as seen inFIG 7B.
InFIG 7B, interface portion68 is shown interfacing with a used strip 4'. The strip is at least partially confined by optional opposing guide members78. In this location an adjacent meter element80 may be used to read the strip-especially where colorametric sensors are employed. Alternately, where electrochemical test strips are used, the guides78 may serve the dual purpose of directing the test strip and also serving as electrical contacts to interface electrochemical strips to the meter, when this type of strip is used.
The result obtained (or a result derived from the data obtained) is displayed on screen6 as shown inFIG 7A.
In the variation of the invention inFIGS 7C and 7D, meter functionality may be identical to that inFIGS 7A and 7B. However, in the variation shown inFIGS 7C and 7D, the disposal mechanism64'is configured somewhat differently. The primary distinction is observed in connection with extension82 off of lever arm70. Instead of being configured to interface with a cap, lever the extension make lever70' suitable for manual operation. It is preferably actuated as indicated by the double-headed arrow along slot84 shown inFIG 7C to eject spent test strips from system2. Before actuating the lever extension, it is preferred that a user direct the device toward a suitably waste receptacle.
Whether or not manual test strip disposal features are included in system2, it may be preferred to include waste magazine86 in cap10. Such a magazine is used as shown inFIGS 8A - 9B. At any time after system2 is removed from the test site (for instance, in response to meter screen directions provided inFIG 6A), cap10 may be replaced. In doing so tab or protrusion74 of lever arm70 is captured by cap interface76. This advances pusher arm66, causing interface section68 to drive spent test strip4' into waste magazine86. The addition of spent strips to its cache of spent strips held in place by biasing spring88 eventually fills the magazine.FIG 9A and 9B show cap10 in place with system2 restored to its configuration inFIGS 1A and 1B. At this point, spent strip4' is fully deposited within magazine86. When the magazine is full, cap10 may be thrown awayen Toto. Such activity is shown in connection withFIGS. 10A and 10B.
Alternately, the magazine itself may be disengaged from the cap and be thrown away alone. Either way, used test strips thus-packaged for disposal minimize any disposal issues that are presented.
Still, at least in connection with the system approach taught inFIGS 7C and 7D, it may be preferred no cap10 is provided, thereby somewhat simplifying operation of the system. Still, it is possible to provide a system that includes a waste magazine and the ability for the user to individually dispose of test strips, as desired. Regardless, where manual test strip disposal features are provided as shown inFIGS 7C and 7D, release of button12 to reactivate interlock28 prior to actuating lever arm extension82 is advised in order to prevent inadvertent movement of the body portions with respect to each other.
Furthermore, one or both of the magazines may be manually inserted and/or removed in/from their respective housing portions. In either case, a detent mechanism or finger-actuated latch (not shown) may be provided to ensure retention. Removal of an empty cartridge52 from the upper body portion is shown inFIG. 10B. Upon opening a door140, an empty unit may be discarded in favor of a full one or simply reloaded and replaced in the system. Utilizing a new cartridge marked with identification data as discussed above is, however, preferred.
As shown inFIG. 10, action associated with refill, replacement or disposal of test strips or ancillary equipment may be indicated on readout6 when appropriate. Alternately, or additionally, magazines22 and/or52 may be produced with transparent material or an indicator may be provided to inform a user of its status. A open or transparent window in cover10 or the body of the meter may be employed to allow the user to observe the quantity of unused strips in the magazine(s)/cassette(s).
Test StripsAs noted above, many types of test strips which integrally include a biosensor and a forward-pointing lance member may be used in the present invention. However, of the examples given, those described in the co-pending European application referred to above may be most preferred. Details regarding the production and use of such devices are presented therein. Regardless a brief description is provided below.
FIGS 11A and 11B illustrate such an exemplary test strip or biosensor device90 fully described in the above-referenced case. Device90 includes an electrochemical test strip configuration and a microneedle92 integrated therewith. The biosensor is defined by an electrochemical cell generally having two spaced-apart and opposing electrodes94 and96, respectively referred to herein as bottom electrode94 and top electrode96, though in use they may oriented in any direction. At least the surfaces of electrodes94 and96 facing each other are comprised of a conductive layer98 and100, respectively, such as a metal, deposited on an inert substrate102 and104, respectively. The spacing between the two electrodes is a result of the presence of a spacer layer106 positioned or sandwiched between electrodes94 and96. Spacer layer106 preferably has double-sided adhesive to hold the electrodes. The spacer layer is preferably configured or cut so as to provide a reaction zone or area108. A redox reagent system or composition110 is present within reaction zone108, where the reagent system is selected to interact with targeted components in the fluid sample, typically whole blood, during an assay of the sample. Redox reagent system110 is usually deposited on the conductive layer100 of top electrode96 wherein, when in a completely assembled form (as shown inFig. 10B), redox reagent system110 resides within reaction zone108. With such a configuration, bottom electrode94 serves as a counter/reference electrode and top electrode96 serves as the working electrode of the electrochemical cell. However, in other embodiments, depending on the voltage sequence applied to the cell, the role of the electrodes can be reversed such that the bottom electrode serves as a working electrode and top electrode serves as a counter/reference electrode.
Microneedle92 is preferably integrally formed with and extends from bottom electrode94. The microneedle is shown with a space-defining configuration in the form of a concave recess112 within its top surface. The recess creates a corresponding space within skin tissue upon penetration of microneedle92 into the skin. This space acts as a sample fluid collection reservoir wherein fluid released upon penetration is pooled within the space prior to transfer into the electrochemical cell. An opening114 to further expose the pooling area defined by recess112 to the outside environment may also be included, thereby increasing the volume and flow rate of body fluid into the pooling area.
Biosensor device90 further includes a sample fluid transfer or extraction pathway or channel116 which extends from recess112 to within the biosensor. At least a portion of a proximal end of the pathway resides within the biosensor portion of device90, specifically within reaction zone108, and a portion of a distal end of pathway114 resides within microneedle92. Pathway116 is dimensioned so as to exert a capillary force on fluid within the pooling area defined by recess112, and draws or wicks physiological sample to within the reaction zone. Extending laterally from proximal portion114 of the pathway to within a portion or the entirety of the reaction zone are sub-channels118. The sub-channels facilitate the filling of reaction zone108 with the sampled fluid.
FIGS 12A and 12B illustrate another suitable embodiment of a biosensor/skin-piercing device90' which is also disclosed in the co-pending European application referred to above. Device90' has a photometric/colorimetric biosensor configuration and a microneedle92' integrated therewith. The colorimetric or photometric biosensor is generally made up of at least the following components: a support element or substrate120 made of either an inert material, including suitable plastics, or a metal material, a matrix or matrix area122 for receiving a sample, a reagent composition124 within the matrix area, the reagent composition typically including one or more members of an analyte oxidation signal producing system, an air venting port (not shown) and a top layer126 which covers at least matrix122. In some embodiments, top layer126 may be a membrane containing a reagent composition impregnated therein while the matrix122 may or may not contain reagent composition. Further, test strip90' may include a double-sided adhesive layer128 situated between substrate120 and membrane126 to hold them together. Double-sided adhesive layer130 has a cutout portion132 which corresponds to the area of matrix122 and defines an area for deposition of the sampled physiological fluid and for the various members of the signal producing system.
Microneedle92 is preferably formed with and extends from substrate120 and has a space-defining configuration in the form of an opening114 which extends transverse to a dimension,e.g., width or thickness, of microneedle92'. As with recess112 of microneedle90 above, opening114 forms an open space within the tissue upon penetration of the microneedle into the skin. Such open space acts as a sample fluid collection reservoir wherein fluid released upon penetration is pooled within the space prior to transfer into the photometric/ colorimetric cell. Note, however, that the needle variation shown inFIGS 11A and 11B may instead rely solely on a recess and omit a through-hole.
Biosensor device90' hosts a sample fluid transfer or extraction pathway116 having a distal end which extends within a portion of microneedle92' and terminates at a distal opening114. At least a portion of the proximal end of pathway116 resides within the biosensor portion of device, specifically within matrix area122. Pathway116 is dimensioned so as to exert a capillary force on fluid within the pooling area defined by opening114, and draws or wicks physiological sample to within matrix area122. Extending laterally from proximal portion of pathway116 to within a portion or the entirety of matrix area122 are sub-channels134, which facilitate the filling of matrix or matrix area122 with the sampled fluid.
Though the invention has been described in reference to certain examples, optionally incorporating various features, the invention is not to be limited to the set-ups described. The invention is not limited to the uses noted or by way of the exemplary description provided herein. It is to be understood that the breadth of the present invention is to be limited only by the literal or equitable scope of the following claims.