INTEGRATED BLOOD TEST DEVICE

Abstract

An integrated blood test unit including a blood collection recess, a test component, and a reservoir containing test fluid. The blood collection device moves to a delivery position under control of an actuator, which also releases test fluid from the reservoir onto the test component. Additional features are a window over the test outcome indicator, a blood delivery channel that only operates if the sample size is large enough, and a geometry for a lancet and actuator that is adapted for a self test situation.

Description

TECHNICAL FIELD

The present invention relates to devices and methods for conducting blood tests using an integrated testing device.

BACKGROUND OF THE INVENTION

Blood tests have conventionally been conducted by drawing blood, for example by venepuncture, and submitting blood for testing to central pathology facilities. Increasingly, there is a demand for tests to be undertaken and interpreted at the point of care, and for self-tests where the user takes their own blood, submits it to a local test device and reads the test outcome.

Advances in the structure, chemistry and biochemistry of test materials have produced the possibility to extend self-testing to a much wider group of users and conditions, particularly where the potential exists for relatively rapid tests. Tests have been developed to allow for testing for many indications, for example various pathogen, antibodies, blood components, biochemical markers, and other substances.

The present applicant has filed applications directed at various aspects of integrated test units, including for example WO/2012/048388, WO/2011/113114 WO2015075677, and PCT/AU2016/051134, the disclosures of which are hereby incorporated by reference.

There is a need for further refinement in such devices, for example in relation to facilitating self-testing. Self-testing presents a very specific set of design challenges, relative to tests intended for professional or regular users. The user will often not have regular, or even any, experience in conducting such tests. Thus, the risk that errors will be made, which in turn undermine the quality of the outcome, is significant.

It is an object of the present invention to provide integrated testing devices which are reliable and reduce the risk of errors by the user.

SUMMARY OF THE INVENTION

In first broad form, the present invention provides a device in which test fluid and blood are delivered to a test material by a single actuator.

According to one aspect, the present invention provides an integrated test unit including a blood collection recess, a test component, and a reservoir containing test fluid, the blood collection device operatively delivering blood to the test component once actuated, wherein an actuator causes the blood to be delivered to the test component and causes the test fluid to be released from the reservoir in order to contact the test component.

According to a further aspect, the present invention provides an integrated test unit, including a blood collection device and a test component, the test component including one or more visual indications relevant to the test outcome or status, wherein the blood integrated test unit includes a transparent window over the or each visual indication.

According to a further aspect, the present invention provides an integrated test unit including a blood collection recess, a test component, and a reservoir containing test fluid, the blood collection device operatively delivering blood to the test component once actuated, and an integrated lancet, wherein the actuator is located at a first location on the device, and the lancet is located at another location on the device.

According to another aspect, the present invention provides an integrated test unit, including a blood collection unit having a blood collection recess, the recess being adapted to directly receive blood from a user, a test material, and an actuator, wherein when the actuator is activated, the blood collection unit pivots to deliver blood to the test material.

According to another aspect, the present invention provides an integrated test unit, including a blood collection recess, the recess being adapted to directly receive blood from a user, the recess including a channel which operatively progressively fills with blood, such that when the channel is full it provides a visual indication to the user that sufficient blood has been received to conduct a test.

Suitable implementations of the present invention accordingly allow for easily used devices, particularly for self test applications, which facilitate

BRIEF DESCRIPTION OF THE DRAWINGS

Illustrative embodiments of the present invention will now be described with reference to the accompanying drawings, in which:

FIG. 1 shows an isometric view of one implementation of the present invention;

FIG. 2 is an exploded view of the components of the implementation of FIG. 1;

FIG. 3A to 3D are cross-sectional views of a device at various stages of operation;

FIG. 4 is a detailed isometric view of the blood collection unit;

FIG. 5 is a detailed cross sectional view illustrating the catch operation for the activation button;

FIG. 6 is a view of the blood collection unit from the opposite end to FIG. 4;

FIG. 7 is a detailed cross-sectional view illustrating the pivot of the blood collection unit;

FIG. 8 is a view, partly in section, illustrating the operation of the interlock member before the lancet is actuated;

FIG. 9 is a view similar to FIG. 8, showing the interlock after lancet actuation; and

FIGS. 10 and 11 illustrate a fluid unit, in a full and discharged condition.

DETAILED DESCRIPTION

The present invention will be described with reference to a particular implementation. It should be understood that the implementation discussed is purely illustrative, and is in no way limitative of the scope of the inventions disclosed. Various inventive features are disclosed, and it will be understood that this disclosure includes them in the combination as discussed, as well in in their individual integers and in sub-combinations.

It should be appreciated that the present invention in one form extends to a complete test device, including a test material, such as a test strip. The test material may be in any form and may be intended to be read by the user either directly, for example via conventional line indications, or using an automated or partly automated reading device. The examples described relate primarily to a conventional lateral flow test strip, however, the invention may be employed with alternative test materials, for example other strip based tests, or electronic sensors. The present invention is not limited to any particular test, condition, test approach or test reading process. Aspects of the present invention are concerned, rather, with various usability, mechanical and fluid handling aspects, not the biochemistry or other aspects of the test material as such.

However, the present invention also extends to a device which does not include the test material, but is adapted to do so. Where the context admits, the description and claims should be read to include both a device with a test strip or other material in place, and a device in which the test strip or other material has not yet been inserted. Thus, the present invention extends to both devices with an integrated test material, and devices which have yet to have a test component inserted.

The present invention contemplates that a test fluid is dispensed onto the test material. This may be a suitable buffer, or any other fluid which it is desirable or necessary to dispense onto the test material, in order to facilitate the test. It will be appreciated that the nature and volume of test fluid will be dependent upon the test to be performed, and it is anticipated that the nature of the test fluid and volume will be selected to complement the intended test and test material. In some cases the test fluid may be an active component of the test, and not merely a buffer or carrier.

FIG. 1 illustrates a device 10 according to one implementation of the present invention. It includes an upper shell 30, lower shell 20, blood collection unit 50 with blood collection recess 51 and channel 52. Device 10 further includes actuator 60, lancet mechanism 40 with cap 41, and result window 70.

The operation of the device, from perspective of the user, will now be described. This will be in the context of a self-test situation. However, it will be appreciated that many of the features and advantages of the illustrated device are also advantageous in point of care or other applications, and the scope of the invention includes self tests, professional use and point of care applications.

First, a user washes their hands, ideally with warm water to increase blood flow, and massages the selected finger for 10 seconds. The user then removes the lancet cap 41, by twisting and pulling. The user then presses hard on the exposed lancet mechanism 40. This releases a biased lancet which penetrates the user's finger, and then retracts within the housing of mechanism 40.

The user then milks the finger, so as to produce droplet of blood. Typically, 5 to 20 μl are required. The user places their finger against the blood collection recess 52, so that blood is collected. The blood flows into the recess 52. This provides a visual indication to the user that sufficient blood has been delivered to provide a valid test.

The next step is to depress actuator 60. As will be explained in more detail, until the lancet has been operated, an interlock prevents the actuator from being depressed. Activating the actuator causes the blood collection unit 50 to pivot slightly downward, so that the channel 52 contacts the test material 80 (not visible here) and the blood is delivered. At the same time, actuator 60 also depresses a reservoir of test fluid 100 (not visible here) and this is also delivered to the test material 80. A latch mechanism hold the actuator in the engaged position, so that the fluid is delivered.

A further feature of device 10 is the result window 70. Conventionally, a window is provided in a test device to show two indicator lines, for test outcome and a control line to indicate that the test is valid. These are conventionally open. According to the present implementation, a solid, partly transparent cover is provided over the test and control indicators. This prevents the user inadvertently putting the blood sample into the wrong opening. After the period appropriate for the test, the test and control lines are visible through the results window 70.

The structure and mechanism of device 10 will be further understood by reference to FIG. 2. Lower shell 20 includes various lugs and location features, including an opening 21 for the lancet mechanism 40. Next is the interlock 90, whose operation will be described below in more detail.

Lancet mechanism 40 is conventional in operation, and any suitable lancet mechanism could be substituted as will be apparent to those skilled in the art. Lancet 42 is biased by spring 43, so that when lancet housing 45 is sufficiently depressed relative to device 10, tabs break away and the lancet 42 projects and then return spring 47 retracts it for safety. Safety cap 44 is increased in usability by the addition of safety cover 41, formed as halves 41A, 41B.

Next in the assembly is strip carrier 85, on which strip 80 rests in use and is retained in the correct position for testing, using retainer 86.

Next is blood collection unit 50, including lug 56 and spring 55, which allow for the positive operation of the pivot function when the actuator is released, as will be described below.

Results window 70 as discussed above is transparent, so that the control and test lines can be seen. Preferably, the housing adjacent to the results window has markings of T and C adjacent to the potential results lines, indicating test and control.

Actuator 10 also compresses plate 75, which in turn compresses test fluid test fluid reservoir 100, not shown in this illustration, against surface 87. Upper shell 30 includes actuator 60, forms with a live hinge 61 to allow it to pivot downwards.

FIGS. 3A, 3B, 3C and 3D illustrate the operation of the various components of device 10, in cross section, at different points of operation of device 10. It is important to understand that the device described is a single use device, intended for a single test. Once the device has passed a stage in operation, for example the lancet has been fired, then it is not possible to return to an earlier stage and re-use the lancet.

In FIG. 3A, the device is as supplied, ready for use. The safety cap 44 is in position and lancet 42 has not been operated. Blood collection unit 50 is positioned so that its lower edge 53 is not in contact with the test strip 80. Reservoir 100 is filled with test fluid, for example buffer or any other fluid required to facilitate the test. Actuator 60 is not depressed. The interlock member 90 is located engaged with the lancet mechanism 40, and is slidable on the lower shell 20. At this stage, it is in the (in this view) left hand position, and the lock posts 91 are positioned to engage actuator posts 66 (not visible here, see FIG. 9). Thus, the user is prevented from depressing the actuator, and so neither blood nor test fluid can be delivered to test strip 80.

As a result, the user has limited opportunities to make erroneous use of the device. The accompanying instructions next tell the user to remove the safety cap 44.

FIG. 3B illustrates device 10 with the safety cap 44 removed. The lancet is now ready for use. At this stage, nothing else in the device is altered. The user presses front surface 45 against the prepared finger, the lancet 42 fires, penetrates the finger, and retracts into the lancet mechanism 40. This is the situation shown in FIG. 3C.

The lancet mechanism is now in the retracted state, with front surface 45 moved back into lower shell 20, and the lancet 42 safely stored. Additionally, the retraction has pushed interlock member 90 to the right, and so moved lock posts 91 (only one is visible) to the right, so that they no longer prevent the movement of actuator 60.

The user at this stage should produce a droplet of blood, and place it into contact with blood collection recess 51. The user receives a visual indication that sufficient blood is provided when groove 52 is filled. Device 10 is now ready for the actuator to be depressed.

It is important to understand the mechanism of the blood collection unit. It is as this stage captured in a locked, upward position, biased by spring 55 on lug 56. It is also, via transverse section 58, captured in groove 36 of latch 35. Thus, at this stage the blood collection unit 50 is held away from contact with test strip 80. This can be seen in more detail in FIG. 5. A more detailed view of blood collection unit 50 can be seen in FIG. 4.

The user next depresses actuator 60. This has several consequences. The reservoir 100 is located directly under the actuator, so as to be depressed and the test fluid discharged into well 101 for discharge via opening 102 onto test strip 80. Thus, test fluid is discharged onto the test strip 80.

The actuator moving down also releases transverse section 58 from groove 36, and spring 55 then forces the blood collection unit 50 to pivot downwards, about pivot pins 53, 54. FIG. 6 provides a more detailed view of the blood collection member 50 in which the pivot pins 53, 54 can be seen. These are located in holders 35 extending from top shell 30, one of which is visible in the detailed view of FIG. 7.

As a result of the pivoting movement, the lower edge 53 engages the test strip 80, and blood flows by capillary action from groove 52 into the bibulous material of the test strip 80.

The actuator 60 is further locked into the closed position. Latch 35 via recess 36 now engages the lower projection 64 of actuator 60, so that it is retained in the closed position. The retention assists in producing positive pressure within the reservoir 100 and well 101, so that the fluid is forced from reservoir 100 and into the test strip 80, so as to minimise surface losses of the test fluid and provide reliable delivery to the test strip 80.

The user then waits the appropriate time, and determines (in this case) if lines appear in the test and control windows. The test result can thereby be determined, together with verification that a valid test has been conducted.

It is generally preferable that the blood is always delivered at the same time, or earlier, than the test fluid, particularly if the fluid is a buffer. The purpose of the buffer is to provide enough fluid to sufficiently drive the movement of the blood along the strip. If the buffer is added before the blood, or runs ahead of the blood, the test may not function correctly.

In one respect, the test fluid is added at about area 81 on the test strip, and blood is delivered from blood collection unit 50, because the action of spring 55, at about area 82. Hence, even if the blood and buffer are added at the same time, the buffer is behind the blood.

FIGS. 8 and 9 illustrate the operation of the interlock member 90 in more detail. FIG. 8 corresponds to the situation in FIG. 3A, in which device 10 is ready for use, but the lancet 42 has not been prepared or fired. Lock post 91 is at it's original, left-most position, that is, closest to the lancet end. It will be understood that another lock post is located on the other side of the lower shell, as can be seen in FIG. 2. In this position, lock post 91 engages actuator post 66, so that actuator 60 cannot be depressed.

FIG. 9 illustrate the situation in FIG. 3C, after the lancet has been fired. Lock post 91 has now moved to the right, that is, to its position at the end closest to the actuator 60. The lock posts 91 no longer engage the actuator posts 66 and actuator 60 can be depressed.

The arrangement illustrated has the actuator at the opposite end to the lancet. When the device is used for self test, this is convenient for the user, as they lance their finger at one end, place the blood onto the blood recess 51, and operate the actuator from the other end. The interior structure is better organised that in arrangements in which the actuator, reservoir and lancet were all at the same end.

A further advantageous feature is that the actuator brings the blood into contact with the test strip in a controlled way, in which the movement is controlled by the device and is not dependant upon the force used by the user. The actuator simply releases the blood collection unit, no understanding or other control is required by the user.

Similarly, the more or less simultaneous release of test fluid and blood, preferably each onto their respective contact areas on the strip, means that the user need not worry about sequencing or volume control, or even timing—the device performs these tasks from a single actuator operation.

The reservoir unit is preferable formed and constructed as disclosed in more detail in PCT/AU2016/051134. While this is a suitable implementation, the present invention is not limited to a fluid delivery mechanism constructed in this manner.

FIGS. 10 and 11 illustrate respectively a full and a discharged fluid unit 105. The unit includes a reservoir 100, a well 101 with a discharge opening 102, and a conduit 104 connecting reservoir 100 to well 101. Conduit 104 is sealed by a frangible seal, which ruptures operatively under pressure from the actuator 60. The reservoir is forced to close and forces fluid into well 101 and then through opening 102, which is in contact with the test strip 80.

The fluid unit 105 may be conveniently formed from laminated heat sealable material, with a relatively stronger seal around the periphery and overlapping edges 106, with the weaker, frangible seal 103, preferably formed as per the above referenced application.

The size of the fluid unit, as well as the capacity of the blood collecting unit, may be varied by appropriate dimensioning to suit the requirements of the test. It will be apparent that within the size constraints of the device, a variety of size options can be accommodated, so that the same basic device may be varied in those component only to provide volumes suitable for different tests.

The present invention may be implemented including electronic components, for example an automated reader for a lateral flow test, or an electronic test material. In such an implementation, the actuator may additionally serve to activate the electronics, for example using a projection to operate a switch to close a circuit.

Claims

1.-16. (canceled)

17. An integrated test unit comprising a blood collection recess, a test component, a reservoir containing test fluid, and an actuator, wherein activation of the actuator causes movement of the blood collection unit to deliver blood to the test component and causes the test fluid to be released from the reservoir in order to contact the test component.

18. An integrated blood test unit according to claim 17, wherein operatively activation of the actuator engages the reservoir to release the test fluid to the test component by a first fluid path, and causes movement of the blood collection unit so as to deliver blood to the test component by a second fluid path.

19. An integrated test unit according to claim 18, wherein the blood collection unit is adapted to receive blood in a recess, and in response to activation of the actuator, the blood collection unit tilts so as to deliver the blood from the recess to the test component.

20. An integrated test unit according to claim 17, wherein the test unit further includes an electronic component, and the electronic component is made operative by activation of the actuator.

21. An integrated test unit according to claim 18, wherein the actuator is locked into an actuated position once operated.

22. An integrated test unit according to claim 21, wherein the locked actuator exerts a continuing force so as to compress the reservoir in order to dispense the test fluid onto the test component.

23. An integrated test unit according to claim 18, wherein the test unit further comprises an integrated lancet, and an interlock is provided so that the actuator is inoperable, such that the blood collection unit cannot move to a delivery position and the test fluid cannot be released, until after the lancet has been discharged.

24. An integrated test unit according to claim 17, wherein the blood collection unit is adapted to pivots or tilts in order to deliver blood to the test component.

25. An integrated test unit comprising a housing, a blood collection recess, a test component, a reservoir containing test fluid, and an actuator being located within the housing, the blood collection recess being adapted to deliver blood contained in the recess to the test component once the actuator is activated, the housing further comprising an integrated lancet, wherein the actuator and the lancet are located adjacent different sides of the housing, so that operatively a user can conveniently operate the actuator after operating the lancet and delivering blood to the blood collection recess.

26. An integrated test unit according to claim 25, wherein the housing is generally shaped as a rectangular box, the actuator is adjacent one short side of the housing, and the lancet is adjacent the opposite short side of the housing.

27. An integrated test unit according to claim 25, wherein the actuator causes the blood collection recess to move to a delivery position so as to deliver blood to the test component, and causes the test fluid to be released from the reservoir in order to contact the test component.

28. An integrated test unit, including a blood collection recess, the recess being adapted to directly receive blood from a user, the recess including a channel which operatively progressively fills with blood, such that when the channel is full it provides a visual indication to the user that sufficient blood has been received to conduct a test.

29. A test unit according to claim 28, wherein the blood collection recess is located on a blood collection device, the blood collection recess being adapted to deliver blood to a test component, wherein the blood collection recess cannot deliver blood to the test component unless the channel is sufficiently filled.

30. A test unit according to claim 29, wherein the blood collection device tilts or pivots downward to place an end of the channel adjacent to the test component, so that blood flows from the channel to the test component.

31. A test unit according to claim 30, wherein the test unit further includes an actuator, and the actuator causes the blood collection device to be moved to an operative position, and causes the test fluid to be released from the reservoir in order to contact the test component.