CN211749634U - Analyte sensor module and analyte sensor system - Google Patents

Abstract

An analyte sensor module and an analyte sensor system are provided. The analyte sensor module comprises a base and a functional assembly, the functional assembly comprises a chemical detection element and an electrode contact, the base comprises an installation part, the functional assembly is installed on the installation part, the base is provided with an avoiding part and a joint part which are not communicated with each other, the joint part is used for connecting an electric processing module electrically connected with the electrode contact, the avoiding part is used for accommodating a battery for supplying power to the electric processing module, the avoiding part and the joint part are through holes, the installation part, the avoiding part and the joint part are arranged in a plane perpendicular to the thickness of the analyte sensor module, the base is a single part, the installation part is arranged in the installation part, the part between the avoiding part and the joint part is connected with the installation part, the avoiding part and the joint part are connected into a. The base has a plurality of hollowed-out parts, so that the weight is light, the material is saved, and the lightweight of the analyte sensor module is facilitated.

Description

Analyte sensor module and analyte sensor system

Technical Field

The utility model relates to the technical field of medical equipment, and in particular to analyte sensor module and analyte sensor system.

Background

CN109310372A, CN107949314A and CN102803947A each provide an analyte sensor system comprising a base, a sensor mounted on the base for detecting an analyte, and an electronic component mounted on the base for processing an electrical signal of the sensor, wherein the above-mentioned components are packaged into a whole during the factory shipment.

In the analyte sensor system disclosed in the above prior art, the base is formed of a flat plate, which is relatively thick and heavy, and when it is bonded to the skin surface of a human body, a greater adhesive force is required to ensure that the analyte sensor system is not separated from the human body, which puts higher demands on the adhesive, and the base uses more materials, thereby increasing the manufacturing cost. In addition, the less compact arrangement of the components on the base results in a larger footprint for the analyte sensor system.

SUMMERY OF THE UTILITY MODEL

The present invention has been made in view of the above-described state of the art. An object of the utility model is to provide an analyte sensor module, it has reduced the material that the base used, and whole weight is little, still provides an analyte sensor system.

There is provided an analyte sensor module comprising a base and a functional assembly, the functional assembly comprising a chemical detection element for contacting an analyte and electrode contacts for transmitting data detected by the chemical detection element in the form of an electrical signal, the base comprising a mounting portion to which the functional assembly is mounted,

the base is provided with an avoiding part and a joint part which are not communicated with each other, the joint part is used for connecting an electric processing module electrically connected with the electrode contact, the avoiding part is used for accommodating a battery for supplying power to the electric processing module,

dodge the portion with the joint portion is the hole that link up, the installation department dodge the portion with the joint portion is in the perpendicular to arrange in the plane of analyte sensor module's thickness, the base is single part, being located of base the installation department dodge the portion with part between the joint portion three will the installation department dodge the portion with the joint portion links into a whole.

Preferably, the functional assembly comprises a substrate, a first electrode set and a second electrode set mounted to the substrate, the first electrode set comprising a first working electrode and a counter electrode, the second electrode set comprising a second working electrode and a reference electrode, the first and second electrode sets providing electrode contacts on opposite sides of the substrate,

the sensor also comprises a conductive counter electrode conversion piece and a conductive working electrode conversion piece, wherein the working electrode conversion piece is electrically connected with the first working electrode and the second working electrode, and the counter electrode conversion piece is electrically connected with the counter electrode and switches a contact of the counter electrode to the side of the substrate where the reference electrode is located.

Preferably, the counter electrode conversion member and the working electrode conversion member include a conversion member body for electrical connection with the electrical processing module, and a slot into which the substrate is inserted and clamped by the conversion member body.

Preferably, the functional assembly includes an electrode contact pad electrically connected to the electrode contact, and an elastic sealing block that surrounds the electrode contact pad and has a contact pad window for exposing the electrode contact pad, the elastic sealing block being installed in a hollow space of the installation part by being pressed.

Preferably, the mounting portion comprises a groove with a bottom wall, the bottom wall is provided with a fracture line, and when the bottom wall is acted by a downward acting force, the fracture line is broken, so that the functional component is pushed to leave the mounting portion.

Preferably, the functional module further comprises a mounting seat and a puncture needle, the mounting seat is connected with the inner peripheral wall of the mounting part, the mounting seat comprises a sensing element positioning part and a puncture needle positioning part, the sensing element positioning part is mounted and positioned on the chemical detection element, and the puncture needle positioning part is mounted and positioned on the puncture needle, so that the puncture needle and the chemical detection element are mounted in a matched manner.

Preferably, a sealant is filled between the mounting seat and the inner peripheral wall of the mounting portion.

Preferably, the relief portion occupies a circumferential space having a central angle of 80 to 100 degrees, and occupies a radial space from the center of the base to the edge of the base by 85% or more.

Preferably, the joint portion provided between the avoiding portion and the mounting portion occupies at least 25% of the space between the avoiding portion and the mounting portion.

There is also provided an analyte sensor system comprising an analyte sensor module according to any of the above claims, and the electrical processing module and the battery.

The technical scheme provided by the disclosure at least has the following beneficial effects:

the base has a plurality of hollowed-out parts, so that the weight is light, the material is saved, and the lightweight of the analyte sensor module is facilitated. The mounting portion, the avoiding portion and the joint portion enable the analyte sensor module to provide a more optimized mounting position for the battery and the electric processing module, and the thinning and the miniaturization of the whole structure are facilitated.

The technical scheme can also have the following beneficial effects:

when the bottom wall is acted by a force from bottom to top, for example, the bottom wall is broken manually, the breaking line is broken, so that the bottom wall is broken, and the broken bottom wall pushes the functional component mounted above the broken bottom wall, so that the functional component is separated from the mounting part.

The current signal that first electrode group gathered is same one side with the current signal that second electrode group gathered, compares with utilizing traditional two-sided electrode, and analyte sensor module can be connected with electric processing module in same one side, and this is favorable to analyte sensor module and electric processing module's overall layout, and holistic circuit structure is comparatively optimized, and holistic thickness is less.

Drawings

Fig. 1 is an exploded block diagram of an analyte sensor module provided by the present disclosure.

Fig. 2 is an assembled block diagram of an analyte sensor module provided by the present disclosure.

Fig. 3a is a perspective view of the base.

Fig. 3b is a top view of the base.

Fig. 4 is a structural view of the mount.

Fig. 5a is a perspective view of a sensor element.

Fig. 5b is a top view of the sensor element.

Fig. 5c is an exploded view of the sensor element.

FIG. 6 is a structural view of the counter electrode converting member.

Fig. 7 is a structural view of the working electrode conversion member.

Fig. 8 is a structural view of an electrode contact pad.

Fig. 9 is a structural view of the elastic sealing block.

FIG. 10 is a structural view of the puncture needle

Fig. 11 is a schematic view of the adhesive.

Description of reference numerals:

1, puncture needle assembly, 104 positioning projection, 105 puncture needle, 106 accommodating groove and 107 needle tip;

2 elastic sealing block, 201 positioning projection, 202 contact pad window;

3 electrode contact pad, 301 step surface, 302 upper surface, 303 lower surface;

4 pairs of electrode converters, 5 working electrode converters, 402, 502 converter bodies, 401, 501 slots, 403, 503 surfaces, 504 inner walls;

6 sensing element, 601 substrate, 602 alignment well, 603 reference electrode, 604 second working electrode, 605 counter electrode, 606 chemical detection element, 608 first working electrode;

7 mounting seat, 71 puncture needle mounting groove, 72 sensing element mounting groove, 701 puncture needle positioning part, 705 peripheral wall, 706 sensing element positioning part and 707 tapered block;

8, a base, a bottom wall 801, an inner peripheral wall 802, a 803 notch, a 804 groove, a 805 fracture line and a 808 puncture needle pass through hole;

9, sticking glue, 902 puncture needle passing through holes, 807 and 901 avoiding grooves;

700 joint, 800 mounting section, 900 escape section.

Detailed Description

Exemplary embodiments of the present invention are described below with reference to the accompanying drawings. It should be understood that the detailed description is only intended to teach one skilled in the art how to practice the invention, and is not intended to exhaust all possible ways of practicing the invention, nor is it intended to limit the scope of the invention.

As shown in fig. 1 and 2, the present disclosure provides an analyte sensor module for binding to a biological body, for example, a human body, and detecting an analyte in the body, such as blood glucose concentration or the like.

It should be understood that the analyte sensor module is generally flat, with the thickness direction being the direction in which it is implanted into the human body during use, and the side of the analyte sensor module closer to the human body is the "lower side" and the side farther from the human body is the "upper side".

This analyte sensor module includes base 8, pastes glue 9 and functional module, and the downside of base 8 is pasted through medical glue and is pasted glue 9, pastes glue 9 and has viscidity thereby can combine with human surface towards one side of human body. The upper side of the base 8 is provided with a functional component, the functional component comprises a chemical detection element 606 and an electrode contact, the chemical detection element 606 is contacted with the analyte in the body, and the electrode contact transmits the data detected by the chemical detection element 606 in the form of an electric signal.

The analyte sensor module is used in cooperation with an electrical processing module and a battery, the electrical processing module comprises a circuit, the electrical processing module processes an electrical signal formed by the analyte sensor module and transmits the electrical signal to the outside for use, and the battery supplies power to the electrical processing module.

As shown in fig. 3a and 3b, the base 8 includes a hollow mounting portion 800, a relief portion 900, and an engaging portion 700, and the relief portion 900 and the engaging portion 700 are not in communication with each other. The mounting portion 800, the escape portion 900, and the coupling portion 700 are arranged in a plane perpendicular to the thickness direction of the analyte sensor module, and a partial base body for integrally connecting the three is provided therebetween. The mounting portion 800 mounts a functional component, and the mounting portion 800 may be, for example, a groove with a bottom wall 801, and the functional component is, for example, mounted or bonded with interference with an inner peripheral wall of the groove. The battery is connected to the electrical processing module, and the portion of dodging 900 is for from last hole of penetrating through down and being used for holding the battery to the portion of dodging 900 can form the breach in the edge of base 8. The joint part 700 is a hole penetrating from top to bottom and used for connecting an electric treatment module, for example, the peripheral wall of the hole is in clamping joint with the electric treatment module, the electric treatment module is stably installed and is not easy to fall off, and a user can conveniently detach the electric treatment module.

The base body between the three is only used for connecting the three into a whole to occupy less projected area, be less than installation department 800, dodge portion 900 and the total projected area of joint portion 700 three, for example account for total projected area's 70%, thereby the base forms hollow out construction. The hollow base 8 is light in weight, saves materials, and is favorable for the lightweight of the analyte sensor module, and the installation part 800, the avoiding part 900 and the joint part 700 enable the analyte sensor module to provide more optimized installation positions for the battery and the electric processing module, and are favorable for the thinning of the whole structure.

In other embodiments, the mounting portion 800 may also be a through hole.

Specifically, the mounting portion 800 and the relief portion 900 may occupy a circumferential space having a central angle of 80 to 100 degrees and a radial space from the center to the edge of the base 8 of 85% or more, respectively. The junction 700 provided between the relief portion 900 and the mounting portion 800 may occupy at least 25% of the space between the relief portion 900 and the mounting portion 800.

Like this, base 8 large area ground fretwork is favorable to losing weight of base 8, pastes gluey 9 and can firmly paste the analyte sensor module that weight has alleviateed on skin.

The bottom wall 801 of the mounting portion 800 has, for example, a fracture line 805 and a puncture needle passing hole 808, the fracture line 805 being formed by providing holes at intervals along a straight line, and the puncture needle passing hole 808 through which the puncture needle 105 (described in detail below) passes. When the bottom wall 801 is acted by a downward force, for example, the bottom wall 801 is manually broken, the breaking line 805 is broken, so that the bottom wall 801 is broken, and the broken bottom wall 801 pushes the functional component mounted above the broken bottom wall, so that the functional component is separated from the mounting portion 800.

Moreover, the mounting 7 can be pushed to disengage the electrical treatment module from the base 8.

The outer periphery of base 8 has a notch 803 to avoid a booster mounted thereto for pushing the analyte sensor module.

As shown in fig. 5a, 5b, 5c, 6 and 7, the functional assembly includes a mounting base 7, a sensing element 6, an electrode contact pad 3, an elastic sealing block 2 and a lancet assembly 1, the sensing element 6 includes a substrate 601 (e.g., a flexible substrate), a second electrode set including a first working electrode 608 and a counter electrode 605, a first electrode set including a second working electrode 604 and a reference electrode 603, a chemical detection element 606 as described above, a working electrode converter 5 and a counter electrode converter 4. The first and second electrode sets provide the above-mentioned electrode contacts of the functional assembly, and are located on opposite sides of the substrate 601, thereby forming a double-sided electrode. The chemical detection element 606 is rod-shaped and bent by a special jig to a desired angle, for example, perpendicular to the substrate 601.

Working electrode converter 5 connects first working electrode 608 and second working electrode 604, and counter electrode converter 4 switches the contact point of counter electrode 605 to the opposite side (front side). Providing the first electrode group and the second electrode group on opposite sides of the substrate 601 to form double-sided electrodes enables higher detection accuracy to be obtained, and the space occupied by each electrode on the substrate 601 can be minimized to reduce the size of the sensor element 6.

In fig. 5a, the upper surface in the drawing is the reverse surface (lower surface) of the substrate 601, and the lower surface in the drawing is the obverse surface (upper surface) of the substrate 601. A reference electrode 603 and a second working electrode 604 are formed on the front surface of the substrate 601, and a counter electrode 605 and a first working electrode 608 are formed on the back surface of the substrate 601.

In fig. 5b, the upper surface in the drawing is the front surface (upper surface) of the substrate 601, and the lower surface in the drawing is the back surface (lower surface) of the substrate 601.

The electrode contacts of the counter electrode 605 are switched to the other side of the substrate 601 (the side on which the second electrode set is located, e.g. the top side/front side) such that the current signal collected by the first electrode set is on the same side (e.g. the top side) as the current signal collected by the second electrode set, so that the analyte sensor module can be connected to the electrical processing module on the same side, which is beneficial to the overall layout of the analyte sensor module and the electrical processing module, and the overall circuit structure is optimized and has a small overall thickness.

The counter electrode converting member 4 and the working electrode converting member 5 may each be formed as a sheet body, which may have a sheet-like converting member body 402, 502 and a slot 401, 501, and the substrate 601 is inserted into the slot 401, 501 and clamped by the converting member body 402, 502 to attach the counter electrode converting member 4 and the working electrode converting member 5 together with the substrate 601. Thus, the counter electrode converting element 4, the working electrode converting element 5 and the substrate 601 are formed as a single body. One surface (lower side surface) 403 of the conversion member body 402 is used to form a counter electrode contact, and one surface (upper side surface) 503 of the conversion member body 502 is used to form a working electrode contact.

The inner wall 504 of the slot 501 of the working electrode transducer 5 can abut against the edge of the substrate 601 to position the substrate 601 with the working electrode transducer 5.

As shown in fig. 8 and 9, the electrode contact pad 3 is made of a conductive material, and the electrode contact pad 3 is electrically connected to electrode contacts, such as a surface 503 of the working electrode transition piece 5, the other surface (upper side surface) 403 of the counter electrode transition piece 4, and a reference electrode 603. The elastic sealing block 2 is made of an elastic insulating material (e.g., silicone), and the elastic sealing block 2 has a cavity in which the electrode contact pad 3 is compressively fitted to be positioned with respect to the elastic sealing block 2. For example, the lower surface 303 of the electrode contact pad 3 is flush with the lower surface 203 of the elastic sealing block 2, and a step surface 301 is provided between the upper surface 302 and the lower surface 303, and the step surface 301 is closely attached to the inner wall of the elastic sealing block 2.

The elastic sealing block 2 has a contact pad window 202, the electrode contact pad 3 can be exposed from the contact pad window 202 so that the electric processing module can contact with the electrode contact (electrode contact pad 3) through the contact pad window 202, the electrode contact pad 3 provides a contact plane for a pin of the electric processing module, damage to a conductive pattern layer material printed on the surface of the electrode is reduced, and a protection effect on a biological material coating is achieved.

The elastic seal block 2 is mounted in a hollow space of the mounting portion in a pressed manner, for example, elastically deformed by being pressed by an inner peripheral wall of the mounting seat 7. The elastic sealing block 2 has a positioning projection 201, and the mount 7 has a positioning recess (e.g., a portion of the puncture needle mounting groove 71 described later adjacent to the sensor element mounting groove 72) that cooperates with the positioning projection 201 to effect positioning. The electrode contact pads 3 and the elastic sealing block 2 are assembled in such a way that the whole projects from the upper surface of the mounting portion (mounting seat 7) to be received in a corresponding cavity of the electrical treatment module. The elastic sealing block 2 can form good self-sealing between the analyte sensor module and the electric processing module by means of self elastic deformation, and meets the waterproof requirement during assembly between modules. A sealant may be applied to the outer peripheral wall of the elastic sealing block 2, for example, to a gap between the mounting seat 7 and the elastic sealing block 2.

The elastic sealing block 2 and the electrode contact pad 3 are combined into a whole and transmit electric signals between the electric processing module and the electrode contact, and the whole is matched with sealing glue to realize filling and sealing, so that the water tightness requirement of the surface of the electrode is met.

As shown in fig. 4, 5a, 5b, 5c, and 10, the mounting seat 7 has a puncture needle mounting groove 71 and a sensor element mounting groove 72, the puncture needle mounting groove 71 and the sensor element mounting groove 72 are penetrated, and a portion of the puncture needle mounting groove 71 adjacent to the sensor element mounting groove 72 can be used to position the elastic sealing block 2. The inner contour of the sensor element mounting recess 72 is the same as the outer contour of the base 601 of the sensor element, so that the base 601 of the sensor element is supported by the bottom wall and the peripheral wall of the sensor element mounting recess 72. The puncture needle mounting groove 71 has a space penetrating vertically so that the puncture needle assembly 1 can pass therethrough.

The outer peripheral wall 705 of the mount 7 and the inner peripheral wall 802 of the mount 800 include inclined surfaces inclined with respect to the up-down direction, and are interference fitted.

The mount 7 includes a puncture needle positioning portion 701 and a sensor element positioning portion 706, the puncture needle positioning portion 701 is, for example, three positioning grooves extending in the circumferential direction at intervals provided up and down on the inner peripheral wall of the puncture needle mounting groove 71, and the positioning grooves cooperate with the positioning projections 104 (described in detail below) of the puncture needle assembly 1 to position the puncture needle 105 so that the storage groove 106 (described in detail below) of the puncture needle 105 faces a predetermined direction and cannot rotate relative to the mount 7, and orientation is easy.

The sensing element positioning portion 706 is, for example, a positioning protrusion disposed inside the sensing element mounting groove 72, and the positioning protrusion cooperates with a positioning hole 602 (described in detail below) of the sensing element to position the sensing element, so that the chemical detection element 606 of the sensing element can be received in the receiving groove 106. Thus, when the needle tip 107 of the puncture needle 105 is inserted into the human body, the chemical detection element 606 is inserted into the human body together with the puncture needle 105.

The sensing element and the puncture needle assembly 1 are positioned with each other via the mounting seat 7 and are formed as a whole, so that the detachment and the installation are convenient, and the whole structure is compact.

The outer peripheral wall 705 of the mounting seat 7 can be further provided with a tapered block 707, the peripheral wall of the mounting part 800 can be further provided with a groove 804, when the mounting seat 7 is mounted on the mounting part 800, the outer peripheral wall 705 is pressed with the inner peripheral wall 802, and the tapered block 707 extends into the groove 804.

A sealant may be applied between the outer circumferential wall of the mount 7 and the inner circumferential wall of the mounting portion 800, thereby sealing a gap between the mount 7 and the mounting portion 800.

As shown in fig. 3b and 11, the adhesive 9 is attached to the lower surface of the base 8, and the adhesive 9 has a puncture needle passing hole 902, and the puncture needle passing hole 902 is aligned with the puncture needle passing hole 808. The sticker also has an avoidance groove 901, the avoidance groove 901 is aligned with the avoidance groove 807 in the lower portion of the base to avoid the positioning protrusion at the bottom of the storage box for storing the analyte sensor module.

It should be understood that the above embodiments are exemplary only, and are not intended to limit the present invention. Various modifications and alterations of the above-described embodiments may be made by those skilled in the art in light of the teachings of the present invention without departing from the scope thereof.

Claims (10)

1. An analyte sensor module comprising a base (8) and a functional component, the functional component comprising a chemical detection element (606) for contacting an analyte and electrode contacts for transmitting data detected by the chemical detection element (606) in the form of an electrical signal, the base (8) comprising a mounting portion (800), the mounting portion (800) mounting the functional component, characterized in that,

the base (8) is provided with a relief part (900) and a joint part (700) which are not communicated with each other, the joint part (700) is used for connecting an electric processing module electrically connected with the electrode contact, the relief part (900) is used for accommodating a battery for supplying power to the electric processing module,

dodge portion (900) with joint portion (700) is the hole that link up, installation department (800) dodge portion (900) with joint portion (700) is in the perpendicular to arrange in the plane of analyte sensor module's thickness, base (8) are single part, being located of base (8) installation department (800) dodge portion (900) with part between joint portion (700) three will installation department (800) dodge portion (900) with joint portion (700) link into whole.

2. The analyte sensor module of claim 1 wherein the functional assembly comprises a substrate (601), a first electrode set and a second electrode set mounted to the substrate (601), the first electrode set comprising a first working electrode (608) and a counter electrode (605), the second electrode set comprising a second working electrode (604) and a reference electrode (603), the first and second electrode sets providing electrode contacts on opposite sides of the substrate (601),

the sensor module further comprises a conductive counter electrode conversion piece (4) and a conductive working electrode conversion piece (5), wherein the working electrode conversion piece (5) is electrically connected with the first working electrode (608) and the second working electrode (604), and the counter electrode conversion piece (4) is electrically connected with the counter electrode (605) and switches a contact of the counter electrode (605) to the side of the substrate (601) where the reference electrode (603) is located.

3. The analyte sensor module of claim 2, wherein the counter electrode transducer (4) and the working electrode transducer (5) comprise a transducer body (402, 502) and a slot (401, 501), the transducer body (402, 502) being adapted to be electrically connected to the electronic processing module, the substrate (601) being inserted into the slot (401, 501) and clamped by the transducer body (402, 502).

4. The analyte sensor module of claim 2, wherein the functional component comprises an electrode contact pad (3) and an elastic sealing block (2), the electrode contact pad (3) being electrically connected to the electrode contact, the elastic sealing block (2) sheathing the electrode contact pad (3) and having a contact pad window (202) exposing the electrode contact pad (3), the elastic sealing block (2) being compressively mounted within the hollow space of the mounting portion (800).

5. The analyte sensor module of claim 1, wherein the mounting portion (800) comprises a groove with a bottom wall (801), the bottom wall (801) being provided with a break line (805), the break line (805) breaking when the bottom wall (801) is subjected to a force from below upwards such that the functional component is pushed away from the mounting portion (800).

6. The analyte sensor module of claim 1, wherein the functional assembly further comprises a mounting base (7) and a piercing needle (105), the mounting base (7) being connected to an inner peripheral wall (802) of the mounting portion (800), the mounting base (7) comprising a sensing element positioning portion (706) and a piercing needle positioning portion (701), the sensing element positioning portion (706) mounting and positioning the chemical detection element (606), the piercing needle positioning portion (701) mounting and positioning the piercing needle (105), whereby the piercing needle (105) and the chemical detection element (606) are matingly mounted.

7. The analyte sensor module of claim 6, wherein a sealant is filled between the mounting seat (7) and the inner peripheral wall (802) of the mounting portion (800).

8. The analyte sensor module of claim 1, wherein the bypass portion (900) occupies a circumferential space having a central angle of 80 to 100 degrees and occupies a radial space from a center of the base (8) to an edge of the base (8) of more than 85%.

9. The analyte sensor module of claim 1, wherein the junction (700) disposed between the bypass portion (900) and the mounting portion (800) occupies at least 25% of the space between the bypass portion (900) and the mounting portion (800).

10. An analyte sensor system comprising an analyte sensor module according to any one of claims 1 to 9, and the electrical processing module and the battery.

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