KR20240035096A - Continuous Anaylyte Measurement Device With Tansmitter - Google Patents

Abstract

The present invention provides an electrochemical sensor that invades into the skin; It includes a main board to which a battery is connected and a housing to accommodate the main board, the housing being attached to the skin, and the main board comprising: a transmitter that controls the measured signal of the electrochemical sensor; A needle that guides the electrochemical sensor to invade into the skin; Including,
The transmitter or needle is moved from a first position to a second position to penetrate the user's skin, the proximal portion of the electrochemical sensor is electrically connected to the main substrate, and the distal portion of the electrochemical sensor is coupled with the needle to the skin. It is inserted into the housing, and the housing consists of an upper lid and a lower lid, a depression that is not formed as a closed curved surface is formed in the upper lid and the lower lid, and when the upper lid and the lower lid are combined, an insertion portion that aligns the needle A continuous analyte measuring device formed in the depression may be provided.

Description

Continuous Anaylyte Measurement Device With Tansmitter}

The present invention relates to a continuous analyte measuring device comprising an electrochemical sensor that penetrates into the body and continuously measures an analyte and a transmitter having a recess.

When using the inserter as a reference position, one end of the electrochemical sensor connected to the main board is located close to the inserter and can be called the proximal portion, and the other end of the electrochemical sensor inserted into the body is located far from the inserter. It can be called distal.

The proximal portion of the electrochemical sensor may be electrically connected to the main board of the transmitter, and at least a portion of the distal portion of the electrochemical sensor may be inserted into the body. The proximal portion and the distal portion may be located at opposite ends. The proximal portion of the electrochemical sensor may be electrically connected to the main board of the transmitter, which includes the electrical circuitry necessary for measuring analytes, including glucose.

The transmitter may be placed inside the insert along with an electrochemical sensor before being attached to the skin. A type in which a transmitter and an electrochemical sensor are pre-combined can be called an all-in-one type transmitter.

The transmitter is in signal communication with the sensor, wherein the sensor is configured to detect and measure the patient's glucose level for a predetermined period of time and to transmit data corresponding to or related to the measured glucose level for a predetermined period of time for further analysis. .

Since various electronic components, including sensors, are installed in the transmitter and are attached to the skin for a long time, errors may occur if analytes or body fluids seep into the interior of the transmitter.

The present invention provides a continuous analyte measuring device in which a transmitter provided with a recessed portion can be disposed with a needle and part of the electrochemical sensor exposed through the recessed portion.

The transmitter of the present invention has a structure that does not form a through hole through which the needle that penetrates and separates into the body's skin is passed, so it is easy to waterproof and can move the needle without frictional resistance when separating it from the skin. .

The present invention provides an electrochemical sensor that invades into the skin; It includes a main board to which a battery is connected and a housing to accommodate the main board, the housing being attached to the skin, and the main board comprising: a transmitter that controls the measured signal of the electrochemical sensor; A needle that guides the electrochemical sensor to invade into the skin; Including,

The transmitter or needle is moved from a first position to a second position to penetrate the user's skin, the proximal portion of the electrochemical sensor is electrically connected to the main substrate, and the distal portion of the electrochemical sensor is coupled with the needle to the skin. It is inserted into the housing, and the housing consists of an upper lid and a lower lid, a depression that is not formed as a closed curved surface is formed in the upper lid and the lower lid, and when the upper lid and the lower lid are combined, an insertion portion that aligns the needle A continuous analyte measuring device formed in the depression may be provided.

The depression may include a first depression formed in the upper lid and a second depression formed in the lower lid.

After the upper lid and the lower lid are assembled, the insertion portion can be drilled into only one of the first depression and the second depression.

The insertion portion may include a first insertion portion formed in the first depression and a second insertion portion formed in the second depression.

When viewed from the top of the transmitter after the upper and lower lids are assembled, the first recess is in a rotated position with respect to the second recess, and the first insertion portion and the second insertion portion are mutually penetrating. You can.

When viewed from the top of the transmitter after the upper and lower lids are assembled, the first insertion part may be closed by the second recess, and the second insertion part may be closed by the first recess.

In the conventional embodiment in which the through hole of the needle is formed in the upper lid and the lower lid of the transmitter, when inserted, the needle sequentially passes through the through hole formed in the upper lid of the transmitter and the through hole formed in the lower lid, and when disconnected, the needle passes through the through hole formed in the upper lid of the transmitter and vice versa. It passes through the through hole in the following order and is separated from the transmitter. The electrochemical sensor is exposed to a through hole to align with the needle.

At this time, an outer sealing member is required at the joint between the upper lid and lower lid located on the outer periphery of the transmitter, an inner sealing member is required at the joint between the upper lid and lower lid located at the through hole, and an electrochemical sensor is transmitted through the through hole. A sensor sealing member may be required in the exposed area.

On the other hand, it is possible to achieve optimized arrangement of electronic components and design freedom of the main board, which can also contribute to improved performance.

Placing electronic components such as batteries and communication units in a coin-sized transmitter avoiding through-holes can ultimately cause inefficiency in circuit design and even cause defects in the electrical connection between the proximal part of the sensor and the main board.

In the present invention, the through hole of the closed curved surface is eliminated when molding the upper and lower lids that make up the transmitter, so component placement and electrical connectivity can be greatly improved.

Additionally, since the sensor must be exposed through a narrow through hole, it may be difficult to assemble the sensor into the transmitter. The sensor may bend sharply in the through hole. In the present invention, since the exposed hole of the electrochemical sensor is located in the recessed part of the transmitter, the electrochemical sensor can be exposed on the outer periphery of the transmitter.

Since the sensor can be exposed to the outside without bending the folded part of the sensor too much, sensor assembly defects can be suppressed on the transmitter assembly line.

In addition, when the sensor is exposed around a conventional through hole, there is a problem that waterproofing measures must be taken for the sensor exposure hole in the area where a sharp curvature is formed. A sharply curved sensor exposure hole can cause sealing failure. In the present invention, the through hole is eliminated and the sensor exposure hole is formed in the recessed part of the transmitter corresponding to the outer periphery of the transmitter, so the sealing member can be installed in a gently curved part and the adhesion of the sealing member to the sensor exposure hole can be improved. there is. It is also possible to prevent defects in which the sealing member protrudes outside the through hole.

On the other hand, by omitting the through hole, the outer peripheral design of the transmitter can be freely designed. Since the transmitter is attached to the human body, it is necessary to continuously check the insertion status of the sensor despite the user's activities. Even when measurement data deviates from expectations, user satisfaction can be achieved if the sensor insertion status can be visually confirmed.

Since the needle holder is supported in the recess of the transmitter, when the transmitter and needle are lowered and the needle is inserted into the skin, the recess holds the needle holder, allowing a hole to be made vertically in the skin and contributing to pain relief.

Two types of alignment of the needle to the recess in the transmitter may be required. One is a centering means that aligns and regulates the assembly position of the electrochemical sensor and needle. Another is an anti-rotation means that prevents rotation of the needle relative to the transmitter.

In the present invention, a centering means or a rotation prevention means is provided in the recessed portion of the transmitter or the needle holder.

A centering means for aligning the assembly position of the electrochemical sensor and the needle and a rotation prevention means for preventing rotation of the needle with respect to the transmitter may be provided in at least one of the insertion portion and the needle holder of the transmitter.

The centering means or anti-rotation means can minimize needle movement when inserting the needle into the human body, thereby reducing pain caused by needle movement during needle insertion.

In the present invention, when the upper lid and lower lid forming the transmitter are combined, the insertion portion of the recessed portion, which is not a closed curved surface, can be converted into a closed curved surface. After forming the depressions in the upper lid and the depressions in the lower lid, respectively, and then rotating at least one of the upper lid and the lower lid, the open depressions are misaligned with each other, and the inside of the depressions is converted from an open state to a closed curved state. You can. This closed surface can enhance the function of the centering means or anti-rotation means.

The needle passes through the insertion part in the switched state, and the needle holder is regulated to maintain a stuck state without passing through, so the needle and needle holder are inserted into the skin while being securely coupled to the transmitter, and the needle and needle holder are inserted into the skin while being securely coupled to the transmitter. It can reduce pain. When separated from the skin again by the inserter, it can be moved from inside the skin to the outside while being stably guided.

1 is a cross-sectional side view of the inserter and transmitter of the present invention.
Figure 2 is a perspective view showing the arrangement of the needle and electrochemical sensor according to the present invention.
Figure 3 is a combined perspective view of the transmitter of the present invention.
Figure 4 is a plan view of Figure 3.
Figure 5 is a cross-sectional view taken along line AA of Figure 4.
Figure 6 is a plan view of the housing constituting the transmitter of the present invention with the needle holder removed.
Figure 7 is an enlarged view of part B of Figure 6.
Figure 8 is a plan view of the top lid of the transmitter of the present invention.
Figure 9 is a plan view of the needle and electrochemical sensor of the lower lid of the transmitter of the present invention in a state where they are disposed.
Figure 10 is an enlarged view of part C of Figure 9.
Figure 11 is a plan cross-sectional view of the upper surface of the upper lid of the transmitter of the present invention with the upper lid and lower lid combined.
Figure 12 is a bottom view of the transmitter of the present invention.
Figure 13 is a front view of the transmitter of the present invention.
Figure 14 is a longitudinal cross-sectional view of Figure 13.
Figure 15 is an exploded perspective view of the transmitter of the present invention.
Figure 16 is an exploded perspective view of the bottom of the transmitter of the present invention.

Hereinafter, the case where the electrochemical sensor 400 of the present invention is used in a continuous glucose monitoring system (CGMS) that measures interstitial fluid or blood glucose concentration will be described as an example. However, the continuous blood glucose device of the present invention is not limited to measuring glucose concentration in the body and can be expanded to a continuous analyte measuring device for measuring other biomarkers.

Figure 1 is a side cross-sectional view of the inserter and transmitter of the present invention, and Figure 2 is a perspective view showing the arrangement of the needle and electrochemical sensor according to the present invention.

Referring to Figures 1 and 2, the electrochemical sensor 400 of the present invention can be attached to the skin together with the transmitter 200. The transmitter 200 can control the signal measured by the electrochemical sensor 400 and can transmit continuously measured blood sugar levels to an external terminal, including a mobile phone.

The external terminal is provided separately from the transmitter 200 attached to the skin, and can continuously receive measurement data of the electrochemical sensor 400 wirelessly from the transmitter 200. Users can continuously monitor and diagnose measurement data from the electrochemical sensor 400 for biomarkers including glucose, lactate, etc.

The electrochemical sensor 400 and the transmitter 200 may be provided to the user while being loaded into the inserter 100 before attachment to the skin. By the user's attachment action, the electrochemical sensor 400 and the transmitter 200 may be separated from the inserter 100 and attached to the skin.

One end of the electrochemical sensor 400 connected to the electrical components of the transmitter 200 including the main board 202 may be referred to as the proximal portion 402, and at least a portion of the electrochemical sensor 400 that invades the body The other end can be called the distal part 406, and the proximal part 402 and the distal part 406 are interconnected, and the flexible bent part is called the folded part 405. can do.

Invasion may mean inserting at least a portion of the distal portion 406 of the electrochemical sensor 400 into the body.

The transmitter 200 and the electrochemical sensor 400 may be provided to the user in a state that is already connected to each other before attachment to the skin.

The transmitter 200 is located in the first position while loaded in the inserter 100, and the transmitter 200 moves from the first position to the second position by the user's action. At the second position, the transmitter 200 It may adhere to the skin. The insertion direction of the transmitter 200 and the electrochemical sensor 400 may be from the first position to the second position.

The needle 300 has a portion exposed in the longitudinal direction, and a portion of the electrochemical sensor 400 may be disposed inside the needle 300. The needle 300 may incise the skin and guide the electrochemical sensor 400 so that at least a portion of the distal portion 406 can be invaded into the human body along the insertion direction.

The inserter 100 includes a drive unit 102 that operates the transmitter 200 and the electrochemical sensor 400 from the first position to the second position or returns the needle 300 from the second position to the third position. can do.

The drive unit 102 may advance the needle 300 or the transmitter 200 from a first position to a second position such that the needle 300 or the distal portion 406 is inserted into the skin.

The drive unit 102 attaches the transmitter 200 and the electrochemical sensor 400 to the skin in the second position, and then retracts the needle 300 from the second position to the third position to move the needle 300 to the transmitter 200. ) and can be separated from the electrochemical sensor 400.

The driving unit 102 may be connected to the needle holder 310 on which the needle 300 is fixed. The needle holder 310 can be attached to or detached from the driving unit 102. The driving unit 102 may include a return member to which the needle holder 310 is attached or detached.

3, 13, and 14, the transmitter 200 may include an upper lid 210 and a lower lid 220, and an internal space is formed between the upper lid 210 and the lower lid 220. This can be provided. The main board 202 may be seated in the internal space of the transmitter 200.

A plurality of locking protrusions 211 are formed on the edge of the outer peripheral surface of the upper lid 210 at intervals along the circumferential direction, and a plurality of locking protrusions 211 are detachably coupled to the edge of the outer peripheral surface of the lower lid 220. A locking groove 221 may be formed.

The main board 202 includes a power supply such as a battery required to measure the glucose concentration in the distal part 406, a control unit including an electric circuit, and a control unit for controlling and wirelessly transmitting data measured by the electrochemical sensor 400 to the outside. At least one of a wireless communication unit and an operational amplifier may be installed.

The power supply may supply a bias voltage that can cause an electrochemical reaction of the working electrode.

The analyte signal measured at the distal portion 406 may be amplified by an operational amplifier.

The magnitude of the output current for a given bias on the working electrode may be a measure of the concentration of an analyte, such as glucose, in the vicinity of the electrode.

A control unit comprising an electrical circuit may control the electrical potential between the working electrode and the reference electrode at one or more preset values.

One side of the electrochemical sensor 400 on which the sensor pad is formed may face the main board 202, and the other side of the electrochemical sensor 400 may be exposed to the internal space of the transmitter 200.

A sensor pad may be formed on the proximal portion 402 of the electrochemical sensor 400. A contact pad electrically connected to the sensor pad may be formed on the main board 202.

Since at least a portion of the electrochemical sensor 400 invades into the skin, it can be flexible to relieve pain upon invasion and reduce foreign body sensation when worn.

The distal portion 406 of the electrochemical sensor 400 may be disposed on an exposed portion along the longitudinal direction of the needle 300. The end of the needle 300 is in a more protruding position than the end of the distal portion 406. The distal portion 406 of the electrochemical sensor 400 may be inserted into the body after the skin is incised by the needle 300.

Reduction of pain and foreign body sensation are the core performance of continuous analyte meters from the user's perspective. To this end, the electrochemical sensor 400 has flexibility that makes it impossible to penetrate the skin alone, and the electrochemical sensor 400 is thin and flexible enough to be inserted into the body only when the needle 300 incises the skin.

As previously described, the transmitter 200 may include a housing including an upper lid 210 and a lower lid 220. The main board 202 may be provided inside the housing, and the lower lid 220 may be attached to the user's skin.

Here, according to the biggest technical feature of the present invention, closed curved through holes through which the needle 300 passes are not formed on the upper and lower surfaces of the housing.

Referring to FIGS. 8 and 9 , a depression may be formed on one side of the upper lid 210 and the lower lid 220, which is not a closed curved surface but a partially open curved surface.

Forming the closed curved surface may be in the form of a hole (or hole), and this type of hole may be a structure that is not provided in the transmitter 200 of the present invention. Therefore, the transmitter 200 does not artificially form a hole through which the needle 300 passes no matter which side of the housing (side, flat, bottom) is viewed, but the transmitter 200 is made by combining the upper lid 210 and the lower lid 220. When (200) is assembled, it is converted into a closed curved surface, which can have the same effect as drilling a hole.

In other words, the transmitter 200 consists of an upper lid 210 and a lower lid 220, and a depression and an opening are formed in the upper lid 210 and the lower lid 220, respectively, and the upper lid 210 and the lower lid 220 When the lower lid 220 is combined, the depression can be converted into a hole-like shape. The depression corresponds to the opposite side of the opening, and the insertion portion may be formed inside the upper lid 210 and the lower lid 220 in an open state.

As a depression, a first depression 212 may be formed in the upper lid 210 and a second depression 222 may be formed in the lower lid 220.

Referring to FIG. 8, a first opening 213 may be formed in a portion of the first depression 212.

The first recessed portion 212 is an insertion portion, which corresponds to the opposite side of the first opening 213 and is formed at an inner position. The first insertion portion 212a corresponds to both sides of the first opening 213 and is formed at an inner position. It may include a first side portion 212b extending from the portion 212a toward the first opening 213.

The first insertion portion 212a may be formed larger than the opening width of the first side portion 212b, may be formed as an open curved surface rather than a closed curved surface, and may serve to regulate the needle holder 310 without passing through it. You can.

When the needle holder 310 is seated in the first insertion portion 212a, the placement positions of the needle 310 and the needle holder 310 in the transmitter 200 may be automatically aligned.

Additionally, the first insertion portion 212a may be formed to have a substantially oval shape in plan, and a portion of the needle holder 310 seated in the first insertion portion 212a may also be formed to have an oval shape in plan. By doing this, the needle holder 310 can prevent the needle holder 310 from spinning in the circumferential direction after being inserted into the first insertion portion 212a, reliably maintain the aligned state, and move accurately only in the vertical direction. .

A pair of first side parts 212b facing each other may be formed to have a predetermined length from the end of the housing of the transmitter 200 toward the first insertion part 212a, and may be flat rather than curved, and the first opening The width, which is the distance between the first side portions 212b formed on both sides of 213, may be formed to become narrower toward the first insertion portion 212a. By doing this, when inserting the needle holder 310 into the first insertion portion 212a, the pair of first side portions 212b do not easily spread apart compared to a structure in which the width, which is the distance between the first side portions 212b, is constant. Can be inserted tightly.

The first opening 213 may be a portion of the outer periphery of the upper lid 210 that is cut off, and the opening length of the first opening 213 may be formed regardless of whether the needle holder 310 passes through it or not.

The first recessed portion 212 may have a first communication portion 212c formed between the first insertion portion 212a and the first side portion 212b. Accordingly, the first depression 212 may be formed of open curves that are connected to each other.

Referring to FIGS. 9 and 10 , a second recess 222 may be formed in the lower lid 220 as a recess, similar to the upper lid 210 .

A second opening 223 may be formed in a portion of the second depression 222.

The second recessed portion 222 is an insertion portion that corresponds to the opposite side of the second opening 223 and is formed at an inner position, a second insertion portion 222a, and a second side portion corresponding to both sides of the second opening 223 ( 222b) may be included.

The second insertion portion 222a may be formed larger than the opening width of the second side portion 222b, may be formed as an open curved surface rather than a closed curved surface, and may serve to regulate the needle holder 310 without passing through it. You can.

When the needle holder 310 is seated in the second insertion portion 222a, the placement positions of the needle 310 and the needle holder 310 may be automatically aligned in the transmitter 200.

Additionally, the second insertion portion 222a may be formed in an oval shape in plan view, and the needle holder 310 seated in the second insertion portion 222a may also be formed in an oval shape in plan view. By doing this, the needle holder 310 can prevent the needle holder 310 from spinning in the circumferential direction after being inserted into the second insertion portion 222a, reliably maintain the aligned state, and move accurately only in the vertical direction. .

The second side portion 222b may be formed to have a predetermined length from the end of the lower lid 220 of the transmitter 200 toward the second insertion portion 222a, and may be flat rather than curved. The width, which is the distance between the second side parts 222b formed on both sides of the second opening 223, may be formed to become narrower toward the second insertion part 222a. In this way, when the needle holder 310 is inserted into the second insertion portion 222a, the gap between the second side portions 222b does not easily spread and can be maintained tightly.

The second opening 223 may be a portion of the outer periphery of the lower lid 220 that is cut off, and the opening length of the second opening 223 may be formed regardless of whether the needle holder 310 passes through it or not.

The second recessed portion 222 may have a second communication portion 222c formed between the second insertion portion 222a and the second side portion 222b. Accordingly, the second depression 222 may be formed of open curves that are connected to each other.

A first guide member 214 and a second guide member 224 may protrude from the bottom of the upper lid 210 and the upper surface of the lower lid 220. The first guide member 214 and the second guide member 224 may be formed in portions corresponding to the first depression 212 and the second depression 222, respectively.

Referring to FIGS. 5, 11, and 16, the first guide member 214 formed on the bottom of the upper lid 210 is a first insertion guide member 214a protruding from the bottom of the first insertion portion 212a. , It may include a first side guide member 214b protruding from the pair of first side portions 212b.

The first side guide member 214b is formed at each of the positions of the pair of first side portions 212b, and the first side protruding guide member 214b-1 protrudes from one of the first side portions 212b and from the other side. A first side extension protruding guide member 214b-2 may protrude from the first side portion 212b.

The first side extended protruding guide member 214b-2 may be formed to have a wider width (in a direction perpendicular to the longitudinal direction) than the first side protruding guide member 214b-1.

That is, the first side guide member 214b is not composed of a pair of guide members having the same width, but a narrow first side protruding guide member 214b1- and a wide w first side extended protruding guide member 214b. It can be done as -2).

Meanwhile, referring to FIGS. 5, 10, and 15, the second guide member 224 provided on the upper surface of the lower lid 220 is located on the inner surface of the second insertion portion 222a of the second recessed portion 222. It may include a protruding second insertion guide member 224a and a pair of second side guide members 224b protruding from the inner surface of the second side portion 222b.

The second side guide member 224b is formed on a pair of second side portions 222b facing each other of the second recessed portion 222, with a second side protruding guide member 222b-1 on one side and a second side protruding guide member 222b-1 on the other side. The second side-extended protruding guide member 224b-2 may protrude.

The second side extended protruding guide member 224b-2 may have a larger width than the second side protruding guide member 222b-1.

That is, the second side guide member 224b is not composed of a pair of guide members having the same width, but a narrow second side protruding guide member 224b-1 and a wide second side extended protruding guide member 224b. It can be done as -2).

When the upper lid 210 and the lower lid 220 are combined, the catching protrusion 211 formed on the edge of the upper lid 210 can be coupled to the catching groove 221 formed on the edge of the lower lid 220. there is. At this time, the first guide member 214 formed on the bottom of the upper lid 210 and the second guide member 224 formed on the upper surface of the lower lid 220 may face each other.

That is, when the upper lid 210 and the lower lid 220 are combined, the first narrow side protruding guide member 214b-1 of the upper lid 210 and the wide second side of the lower lid 220 The extended protruding guide member 224b-2 faces each other, and the wide first side extended protruding guide member 214b-2 and the narrow second side protruding guide member 224b-1 of the lower lid 220 are provided. It can be face to face.

Referring to FIG. 5, the lower part of the space between the first side portions 212b on the first depression 212 side of the upper lid 210 is the second side-extended protruding guide member 224b with a wider width of the lower lid 220. -2), and as shown in FIG. 8, the first communication portion 212c is blocked by the protruding side of the second side extending protruding guide member 224b-2 and changes from the open state to the closed state. can be converted.

In addition, the upper part of the space between the second side parts 222b on the second recessed part 222 side of the lower lid 220 is connected to the first side extension protruding guide member 214b-2 with a wide width of the upper lid 210. 10 and 12, the second communication portion 222c is changed from an open state to a closed state by the protruding side of the first side extending protruding guide member 214b-2. can be converted.

Therefore, when the upper lid 210 and the lower lid 220 are combined, the first insertion portion 212a of the first depression 212 and the second insertion portion 222a of the second depression 222 are closed. As it becomes a curved surface, it can create the effect of creating a hole.

Due to this effect, the engaging portion 312 of the needle holder 310 is reliably regulated by the first insertion portion 212 of the upper lid 210 and the second insertion portion 212 of the lower lid 220, You can be guided when moving.

Referring to FIGS. 14 to 16 , a cutout portion 312a through which a portion of the electrochemical sensor 400 passes may be formed on the side of the coupling portion 312.

Referring to FIG. 13, the needle holder 310 may be formed with a locking protrusion 313 that is caught when inserted into the first insertion portion 212a and the second insertion portion 222a. The locking jaw 313 may be formed along the circumferential direction of the needle holder 310 and may be in the form of a circular jaw protruding in the radial direction.

In an embodiment of the present invention, when the needle 300 and the transmitter 200 are lowered simultaneously and the needle 300 is inserted into the skin, the needle is inserted into the skin by the first insertion portion 212a and the second insertion portion 222a. Since the holder 310 does not shake, the hole pierced in the skin can match the diameter of the needle and pain can be alleviated.

Since the needle 300 can only move in the vertical direction while being restricted by the first insertion portion 212a and the second insertion portion 222a, the first opening 213 along the horizontal direction (radial direction of the housing) It is possible to fundamentally prevent the phenomenon of moving away through the second opening 223.

There is no need to limit the relative size of the width of the center wall portion 302 of the needle 300 and the opening width of the first opening 213 or the second opening 223, and the center wall portion 302 of the needle 300 The width of may be smaller than the opening widths of the first opening 213 and the second opening 223.

A first communication part 212c and a second communication part 222c may be formed in the first depression 212 and the second depression 222, respectively. The first communication part 212c is formed between the first insertion part 212a and the first side part 212b, and the second communication part 222c is formed between the second insertion part 222a and the second side part 222b. can be formed in

The width of the first communication part 212c and the second communication part 222c can be formed without limitation regardless of the relative size with the width of the center wall part 302 of the needle 300.

Opening 306 of needle 300 may be positioned toward electrochemical sensor 400.

Therefore, according to the present invention, the needle holder 310 and the needle 300 can be assembled very simply and accurately when assembling the transmitter 200.

The positions of the first insertion portion 212a of the first depression 212 and the second insertion portion 222a of the second depression 222 are located outside the center when the housing of the transmitter 200 is circular in plan. It may be in an eccentric position.

When the first insertion portion 212a of the first recess 212 and the second insertion portion 222a of the second recess 222 are deviated from the center of the transmitter 200, they are provided inside the transmitter 200. It may be easy to secure installation space for the main board 202 or electronic components, and it may be advantageous to miniaturize the transmitter 200.

Since the electrochemical sensor 400 of the present invention has a thin film thickness of 100 micrometers or less, it does not occupy a large thickness when installed inside the transmitter 200, contributing to slimming of the transmitter 200.

A portion of the electrochemical sensor 400 provided inside the transmitter 200 may be exposed to the outside of the transmitter 200, and when placed, the proximal portion 402 and the middle portion 403 of the electrochemical sensor 400 A portion (hereinafter referred to as the 'embedded portion') is disposed inside the transmitter 200, and a portion of the middle portion 403, the folded portion 405, and the distal portion 406 (hereinafter referred to as the 'exposed portion') are disposed inside the transmitter 200. It may be placed outside of (200).

A locking piece 403a that functions as a stopper may be formed in the middle portion 403 formed in the electrochemical sensor 400. The locking piece 403a may be formed to be longer in the width direction than the length direction of the middle portion 403 and may be provided in a form that protrudes on both sides of the middle portion 403.

The locking piece 403a can automatically set the installation position and angle when the exposed portion of the electrochemical sensor 400 is exposed from the housing of the transmitter 200.

The locking portion 403a of the electrochemical sensor 400 is connected to the housing when the exposed portion of the electrochemical sensor 400 is exposed from the embedded portion of the electrochemical sensor 400 provided inside the housing of the transmitter 200 to the outside of the housing. It is possible to provide an appropriate exposure area of the exposed part by hanging it at the exit of the.

The outlet of the housing may be a passing part 224a-1 formed on one side of the second insertion guide member 224a protruding from the second insertion part 222a formed on the upper surface of the lower lid 220. The passing portion 224a-1 may be in the form of a hole or groove.

When the exposed portion of the electrochemical sensor 400 passes through the second insertion portion 222a of the lower lid 220, the locking piece 403a is caught without passing through, and the electrochemical sensor 400 is automatically aligned. You can.

In order to insert the electrochemical sensor 400 into the user's skin, the exposed portion of the electrochemical sensor 400 may face the needle 300.

More specifically, the distal portion 406 of the electrochemical sensor 400 may pass through the opening 306 of the needle 300 and face the inside of the central wall portion 302 of the needle 300.

In the present invention, it may be preferable that the needle 300 is not freely disposed when moving between the first recessed portion 212 and the second recessed portion 222 of the transmitter 200 but is disposed at a specific position.

Referring to FIG. 2, the needle 300 includes a center wall portion 302 having a predetermined length, a side wall portion 304 that is bent and protrudes on both sides of the center wall portion 302, and a center wall portion 304 between the side walls 304 on both sides. An opening 306 formed at a position facing the wall 302 may be provided.

The opening 306 of the needle 300 may face away from the opening of the depression formed in the transmitter 200. When the opening 306 of the needle 300 faces the electrochemical sensor 400, the electrochemical sensor 400 can be inserted without being caught in the side wall 304 of the moving needle 300.

At this time, the folded portion 405 and the distal portion 406 of the electrochemical sensor 400 may be inserted into the internal space between the side wall portions 304 of the needle 300 and placed therein.

The transmitter 200 needs to remain waterproof. In particular, the portion where the electrochemical sensor 400 is exposed to the outside from the inside of the housing forming the transmitter 200 must be waterproofed.

When the housing consists of an upper lid 210 and a lower lid 220, the upper lid 210 and the lower lid 220 are each provided with a waterproof member, and a portion of the electrochemical sensor 400 is exposed. When the lid 210 and the lower lid 220 are combined with each other, the waterproof member and a portion of the electrochemical sensor 400 can be waterproofed while being in close contact.

Since the exposed position of the electrochemical sensor 400 is the outer periphery of the upper lid 210 and the lower lid 220, a waterproof member can be installed in a gently curved portion, thereby improving sealing properties.

The waterproof member may include a tape, and in an embodiment of the present invention, a tape for waterproofing may be attached to the upper lid 210 and the lower lid 220, respectively, and may be brought into close contact with a portion of the electrochemical sensor 400. By attaching the tape in multiple layers, adhesion to a portion of the electrochemical sensor 400 can be further increased.

Except for the portion exposed from the housing, the remaining outer peripheral portion of the electrochemical sensor 400 may be sealed using a packing member such as an O-ring or a rubber ring. Since the transmitter 200 does not have a through hole, there is only one joint on the outer periphery, and there is an advantage that all joints of the upper lid 210 and the lower lid 220 can be waterproofed with just one O-ring.

Referring to FIG. 13, the position spaced apart from the upper lid 210 and lower lid 220 forming the transmitter 200 is referred to as the first position (P1), and the depression of the upper lid 210 and lower lid 220 When defining the position after moving along the part as the second position (P2), the needle 300 moves from the second position (P2) to the first position (P1) through the recessed part of the transmitter 200. ) can be separated from.

100... inserter 102... driving unit
200... transmitter 202... main board
210... Upper lid 211... Catch protrusion
212... first recessed portion 212a... first insertion portion
212b... first side portion 212c... first communication portion
213... first opening 214... first guide member
214a... first insertion guide member 214b... first side guide member
214b-1... first side protruding guide member
214b-2... first side extension protruding guide member
220... Lower lid 221... Locking groove
222... second recessed portion 222a... second insertion portion
222b... second side portion 222c... second communication portion
223... second opening 224... second guide member
224a... second insertion guide member 224a-1... passing portion
224b... second side guide member
224b-1... first side protruding guide member
224b-2... second side extension protruding guide member
300... Needle 302... Center wall portion
304... side wall portion 306... opening portion
310... Needle holder 311... Locking groove
312...joint part 312a...cut part
313... Stopper
400... electrochemical sensor 402... proximal
403... middle part 403a... locking piece
405... folded portion 406... distal portion
P1... 1st position P2... 2nd position

Claims (13)

Electrochemical sensors that penetrate into the skin;
It includes a main board to which a battery is connected and a housing to accommodate the main board, the housing being attached to the skin, and the main board comprising: a transmitter that controls the measured signal of the electrochemical sensor;
A needle that guides the electrochemical sensor to invade into the skin; Including,
the transmitter or needle is moved from a first position to a second position to penetrate the skin of the user,
The proximal portion of the electrochemical sensor is electrically connected to the main board,
The distal portion of the electrochemical sensor is inserted into the skin with the needle,
The housing consists of an upper lid and a lower lid,
A depression that is not formed as a closed curved surface is formed in each of the upper and lower lids,
A continuous analyte measuring device in which an insertion portion for aligning the needle is formed in the depression when the upper lid and the lower lid are combined.
According to claim 1,
The depression includes a first depression formed in the upper lid and a second depression formed in the lower lid,
After the upper lid and the lower lid are assembled, the insertion portion is pierced through only one of the first depression and the second depression.
According to claim 1,
The depression includes a first depression formed in the upper lid and a second depression formed in the lower lid,
The insertion portion includes a first insertion portion formed in the first depression and a second insertion portion formed in the second depression,
When viewed from the top of the transmitter after the upper and lower lids are assembled, the first recess is in a rotated position with respect to the second recess, and the first insertion portion and the second insertion portion penetrate each other. Continuous analyte meter.
According to claim 1,
The depression includes a first depression formed in the upper lid and a second depression formed in the lower lid,
The insertion portion includes a first insertion portion formed in the first depression and a second insertion portion formed in the second depression,
When viewed from the top of the transmitter after the upper and lower lids are assembled, the first insertion portion is closed by the second recess, and the second insertion portion is closed by the first recess. water meter.
According to claim 1,
The needle is provided with a needle holder,
The depression is formed by recessing the sides of the upper lid and the lower lid, respectively,
Openings are formed on the sides of the upper and lower lids,
The insertion portion is formed in a direction away from the opening,
The insertion part is a continuous analyte measuring device that allows only the needle to pass and regulates the needle holder.
According to claim 1,
An opening is formed in a portion of the depression,
The recessed portion includes a pair of side portions corresponding to both sides of the opening and facing each other inward from the outer periphery of the upper and lower lids,
The side portion is formed continuously with the insertion portion,
A continuous analyte measuring device in which the opening width of the insertion portion is formed to be larger than that of the side portion.
According to claim 1,
An opening is formed in a portion of the depression,
The recessed portion includes a pair of side portions corresponding to both sides of the opening and facing each other inward from the outer periphery of the upper and lower lids,
The insertion portion is a continuous analyte measuring device in which the insertion portion is formed in an elongated oval shape in the width direction of the opening of the side portion.
According to claim 1,
A continuous analyte measuring device in which guide members are protruded from the bottom of the upper lid and the upper surface of the lower lid, respectively, at positions corresponding to the depressions.
According to claim 1,
The needle is provided with a needle holder,
The depression includes a first depression formed in the upper lid and a second depression formed in the lower lid,
The insertion portion includes a first insertion portion formed in the first depression, and a second insertion portion formed in the second depression,
The first depression and the second depression each include a guide member,
When the upper lid and the lower lid are combined, the guide members face each other,
The first insertion part and the second insertion part are converted into a closed curved surface by the facing guide member to regulate the needle holder, and a continuous analyte measuring device that guides the needle and the needle holder when moving in the vertical direction.
According to claim 1,
The depression includes a first depression formed in the upper lid and a second depression formed in the lower lid,
The first depression and the second depression each include a guide member,
The guide member is,
A pair of first side guide members formed on the bottom of the upper lid and protruding along the first side portion of the first depression,
It includes a pair of second side guide members formed on the upper surface of the lower lid and protruding along the second side portion of the second depression,
The pair of first side guide members includes a first side protruding guide member and a first side extended protruding guide member formed with different widths,
The pair of second side guide members includes a second side protruding guide member and a second side extended protruding guide member formed with different widths,
The first side extended protruding guide member is formed to be larger than the width of the first side protruding guide member,
The second side extending protruding guide member is formed to be larger than the width of the second side protruding guide member,
When the upper lid and the lower lid are combined, the space between the first side portion of the first depression is closed by a second side extending protruding guide member of the lower lid,
A continuous analyte measuring device in which the first insertion portion and the second insertion portion are converted into a closed curved surface while the space between the second side portion of the second depression is closed by the first side extending protruding guide member of the upper lid.
According to claim 1,
An opening is formed in a portion of the depression,
The recessed portion corresponds to both sides of the opening and includes a pair of side portions facing each other inward from the outer periphery of the upper and lower lids,
The insertion portion is formed in an elongated oval shape in the width direction of the opening of the side portion,
A guide member protrudes from the bottom of the upper lid and the upper surface of the lower lid at a position corresponding to the depression, respectively,
A continuous analyte measuring device wherein the depression includes a first depression formed in the upper lid and a second depression formed in the lower lid.
According to claim 1,
A continuous analyte measuring device wherein the insertion portion is formed at an eccentric position outside the center of the housing.
According to claim 1,
A centering means for aligning the assembly position of the electrochemical sensor and the needle and a rotation prevention means for preventing rotation of the needle with respect to the transmitter are provided in at least one of the insertion portion of the transmitter and the needle holder to which the needle is connected. Continuous analyte meter.

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