阅读说明：本技术 一种汗液酒精浓度多参数监测贴片及制备方法 (Sweat alcohol concentration multi-parameter monitoring patch and preparation method thereof ) 是由 魏红祥 黄显 叶长青 于 2019-10-22 设计创作，主要内容包括：本发明公开了一种汗液酒精浓度多参数监测贴片及制备方法,包括以下步骤,提供柔性可延展基底；结合粘接层,具有第一面以及与第一面相对应的第二面,将所述粘接层的第一面与柔性可延展基底结合；制备多个传感芯片,具有第一面以及与第一面相对应的第二面；转印多个传感芯片,所述多个传感芯片的第一面通过转印方式与粘接层的第二面结合；粘结汗液收集器件,所述汗液收集器件通过与粘接层结合的方式,将所述汗液收集器件设置在多个传感芯片的第二面。本发明的汗液酒精浓度多参数监测贴片,可实时动态监测使用者血液中的酒精浓度,汗液中的氯离子浓度、钠离子浓度和葡萄糖浓度,具有实用性。(The invention discloses a sweat alcohol concentration multi-parameter monitoring patch and a preparation method thereof, and the patch comprises the following steps of providing a flexible extensible substrate; a bonding adhesive layer having a first face and a second face corresponding to the first face, the first face of the adhesive layer being bonded to the flexible extensible substrate; preparing a plurality of sensing chips, wherein each sensing chip is provided with a first surface and a second surface corresponding to the first surface; transferring a plurality of sensing chips, wherein first surfaces of the sensing chips are combined with a second surface of the adhesive layer in a transfer mode; and the sweat collection device is arranged on the second surfaces of the plurality of sensing chips in a mode of being combined with the adhesive layer. The sweat alcohol concentration multi-parameter monitoring patch can dynamically monitor the alcohol concentration in blood, the chloride ion concentration, the sodium ion concentration and the glucose concentration in sweat of a user in real time, and has practicability.)

1. A preparation method of a sweat alcohol concentration multi-parameter monitoring patch is characterized by comprising the following steps:

providing a flexible, extensible substrate (17);

a bonding adhesive layer (16) having a first face and a second face corresponding to the first face, the first face of the adhesive layer (16) being bonded to a flexible extensible substrate (17);

preparing a plurality of sensor chips (12) having a first side and a second side corresponding to the first side, the plurality of sensor chips (12) including an alcohol sensor (8);

transferring a plurality of sensor chips (12), wherein first surfaces of the sensor chips (12) are combined with a second surface of the adhesive layer in a transfer mode;

and a bonded sweat collection device (13), wherein the sweat collection device (13) is arranged on the second surfaces of the plurality of sensor chips (12) by combining with the bonding layer (16).

2. The method of manufacturing a sweat alcohol concentration multiparameter monitoring patch according to claim 1, wherein the plurality of sensor chips (12) further include: a chloride ion sensor (10), a sodium ion sensor (11) and a glucose sensor (9).

3. The method of manufacturing a sweat cortisol monitoring patch according to claim 1 where the step of manufacturing the plurality of sensor chips (12) includes the steps of:

preparing an output interface (1), a curved line (2), a gold electrode (3), a working electrode (6), a reference electrode (4) and an auxiliary electrode (5);

and modifying the working electrode (6) to obtain the chloride ion sensor (10), the sodium ion sensor (11) and the glucose sensor (9), and modifying the gold electrode (3) to obtain the alcohol sensor (8).

4. A method of manufacturing a sweat alcohol concentration multiparameter monitoring patch according to claim 3, wherein the gold electrode (3) modification of the alcohol sensor (8) comprises:

washing the surface of the gold electrode (3), modifying the surface of the gold electrode (3) by dithiobis (succinimidyl propionate), and washing the modified surface of the gold electrode (3) by dimethyl sulfoxide and PBS respectively to form a modified connecting layer (7);

modifying the surface of the modified connecting layer with an ethyl glucuronide monoclonal antibody, and cleaning with a confining liquid to obtain the alcohol sensor (8).

5. A sweat alcohol concentration multi-parameter monitoring patch is characterized by comprising

A flexible, malleable substrate (17);

an adhesive layer (16) for connecting the flexible, malleable substrate (17), the plurality of sensing chips (11) and the sweat collection device (13), the adhesive layer (16) being disposed on a surface of the flexible, malleable substrate (17);

a plurality of sensor chip (11), a plurality of sensor chip (11) set up the bonding layer surface, a plurality of sensor chip (11) include alcohol sensor (8), chloride ion sensor (10), sodium ion sensor (11) and glucose sensor (9), alcohol sensor (8) chloride ion sensor (10) sodium ion sensor (11) with glucose sensor (9) all are provided with output interface (1) and curved line (2), alcohol sensor (8) are provided with gold electrode (3) through the modification, gold electrode (3) with output interface (1) passes through curved line (2) are connected, gold electrode (2) upper surface is provided with modification connecting layer (7), the surface coating has the antibody layer on the modification connecting layer, chloride ion sensor (10) with sodium ion sensor (11) all are provided with reference electrode (4) and working electrode (6) through the modification ) The glucose sensor (9) is provided with a reference electrode (4), an auxiliary electrode (5) and a modified working electrode (6), wherein the working electrode (6) is connected with the output interface (1) through the curved line (2), the reference electrode (4) is connected with the output interface (1) through the curved line (2), and the auxiliary electrode (5) is connected with the output interface (1) through the curved line (2).

A sweat collection device (13) for collecting and transmitting sweat, wherein the sweat collection device (13) is arranged on the surfaces of the plurality of sensing chips (12).

6. A sweat alcohol concentration multiparameter monitoring patch according to claim 5, wherein the sweat collection device (13) is provided with a plurality of sweat absorbing ports (14), a reservoir (15) and a sweat releasing port (16), the sweat absorbing ports (14) and reservoir (15) being in channel connection, the reservoir (15) and sweat releasing port (16) being in channel connection.

7. A sweat alcohol concentration multiparameter monitoring patch according to claim 5, wherein the reservoir (15) is connected to a modified gold electrode (3), and the reservoir (15) is connected to modified working electrodes (6) of the chloride sensor (10), the sodium ion sensor (11) and the glucose sensor (9).

8. A sweat alcohol concentration multiparameter monitoring patch according to claim 5, wherein said adhesive layer (16) is medical double-sided tape or silicone.

9. A sweat alcohol concentration multiparameter monitoring patch according to claim 5, wherein the area of the sweat collection device (13) is larger than the area of the plurality of sensor chips (12).

10. A sweat alcohol concentration multiparameter monitoring patch according to claim 5, wherein the thickness of the plurality of sensor chips (12) is 10 to 50 microns.

Technical Field

The invention relates to the technical field of sweat detection, in particular to a sweat alcohol concentration multi-parameter monitoring patch and a preparation method thereof.

Background

With the rapid development of science and technology and the improvement of living standard, the demand for physiological monitoring is increasing. To improve the monitoring quality and effect, chinese patent publication No. CN109374713A discloses a new sweat monitoring patch.

However, the patch in the above patent cannot detect the alcohol concentration in sweat, so the invention provides a sweat alcohol concentration multi-parameter monitoring patch and a preparation method thereof.

Disclosure of Invention

The invention mainly aims to provide a sweat alcohol concentration multi-parameter monitoring patch and a preparation method thereof, and aims to solve the problem that a sweat detection patch in the prior art cannot detect alcohol.

In order to achieve the above object, according to one aspect of the present invention, there is provided a method for manufacturing a sweat alcohol concentration multiparameter monitoring patch, comprising the steps of:

providing a flexible, extensible substrate;

a bonding adhesive layer having a first face and a second face corresponding to the first face, the first face of the adhesive layer being bonded to the flexible extensible substrate;

preparing a plurality of sensing chips, wherein each sensing chip is provided with a first surface and a second surface corresponding to the first surface, and the plurality of sensing chips comprise alcohol sensors;

transferring a plurality of sensing chips, wherein first surfaces of the sensing chips are combined with a second surface of the adhesive layer in a transfer mode;

and the sweat collection device is arranged on the second surfaces of the plurality of sensing chips in a mode of being combined with the adhesive layer.

Further, the plurality of sensor chips further includes: chloride ion sensors, sodium ion sensors, and glucose sensors.

Further, the preparation of the plurality of sensor chips comprises the steps of:

preparing an output interface, a curved line, a gold electrode, a working electrode, a reference electrode and an auxiliary electrode;

and modifying the working electrode to obtain the chloride ion sensor, the sodium ion sensor and the glucose sensor, and modifying the gold electrode to obtain the alcohol sensor.

Further, the gold electrode modification of the alcohol sensor comprises:

cleaning the surface of the gold electrode, modifying the surface of the gold electrode by dithiobis (succinimidyl propionate), and cleaning the modified surface of the gold electrode by dimethyl sulfoxide and PBS respectively to form a modified connecting layer;

modifying the surface of the modified connecting layer with an ethyl glucuronide monoclonal antibody, and cleaning with a confining liquid to obtain the alcohol sensor.

According to another aspect of the present invention there is provided a sweat alcohol concentration multi-parameter monitoring patch comprising:

a flexible, extensible substrate;

an adhesive layer for connecting the flexible, malleable substrate, the plurality of sensing chips, and the sweat collection device, the adhesive layer disposed on a surface of the flexible, malleable substrate;

the plurality of sensing chips are arranged on the surface of the bonding layer, the plurality of sensing chips comprise an alcohol sensor, a chloride ion sensor, a sodium ion sensor and a glucose sensor, the alcohol sensor, the chloride ion sensor, the sodium ion sensor and the glucose sensor are provided with an output interface and a curved line, the alcohol sensor is provided with a modified gold electrode, the gold electrode is connected with the output interface through the curved line, the upper surface of the gold electrode is provided with a modified connecting layer, the upper surface of the modified connecting layer is coated with an antibody layer, the chloride ion sensor and the sodium ion sensor are both provided with a reference electrode and a modified working electrode, the glucose sensor is provided with a reference electrode, an auxiliary electrode and a modified working electrode, and the working electrode is connected with the output interface through the curved line, the reference electrode is connected with the output interface through the curved line, and the auxiliary electrode is connected with the output interface through the curved line.

And the sweat collection device is used for collecting and transmitting sweat and is arranged on the surfaces of the plurality of sensing chips.

Further, the sweat collection device is provided with a plurality of sweat absorbing openings, a liquid storage cavity and a sweat discharging opening, the sweat absorbing openings are connected with the liquid storage cavity through channels, and the liquid storage cavity is connected with the sweat discharging opening through channels.

Further, the liquid storage cavity is connected with a modified gold electrode, and the liquid storage cavity is connected with the chloride ion sensor, the sodium ion sensor and the modified working electrode of the glucose sensor.

Further, the adhesive layer is medical double-sided adhesive tape or silica gel.

Further, the area of the sweat collection device is larger than the area of the plurality of sensor chips.

Further, the thickness of the plurality of sensor chips is 10 to 50 micrometers.

The beneficial effects of the invention are as follows:

through the setting of alcohol sensor for the paster utilizes alcohol sensor to accomplish the monitoring to alcohol concentration in the blood, thereby has realized the control to the internal alcohol concentration of user, when the user is the driver, can judge qualitatively whether the driver drives for wine.

Drawings

FIG. 1 is a schematic flow chart of a method for manufacturing an alcohol concentration monitoring patch according to the present invention;

FIG. 2 is a schematic diagram of a sensor chip according to the present invention;

FIG. 3 is a schematic view of a sweat collection device of the present invention;

FIG. 4 is a schematic view of the gold electrode modification of the present invention;

fig. 5 is a schematic diagram of the operation of the alcohol concentration monitoring patch of the present invention.

In the figure: 1-output interface, 2-curved line, 3-gold electrode, 4-reference electrode, 5-auxiliary electrode, 6-working electrode, 7-modified connecting layer, 8-alcohol sensor, 9-glucose sensor, 10-chloride ion sensor, 11-sodium ion sensor, 12-sensing chip, 13-sweat collecting device, 14-sweat absorbing port, 15-liquid storage cavity, 16-sweat discharging port and 17-flexible extensible substrate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1 to 4, according to an embodiment of the present invention, a method for manufacturing a sweat alcohol concentration multi-parameter monitoring patch is provided, where the method for manufacturing the sweat alcohol concentration multi-parameter monitoring patch in this embodiment includes the following steps:

s1: providing a flexible extensible substrate 17;

the flexible extensible substrate 17 may be a flexible extensible film structure, the flexible extensible substrate 17 may be made of a material which is flexible and has an elongation rate greater than 30%, and the flexible extensible substrate 17 may be deformed and extended with the skin of the human body without generating a relative displacement with the skin, thereby improving the monitoring accuracy. Alternatively, the flexible extensible substrate 17 may be a spandex fabric, a silicone film, or the like.

S2: a bonding adhesive layer 16 having a first face and a second face corresponding to the first face, the first face of the adhesive layer 16 being bonded to a flexible extensible substrate 17;

optionally, the adhesive layer 16 is a medical double-sided adhesive tape with adhesive properties on both sides, or a medical adhesive silicone gel, the flexible extensible substrate 17 is placed on a horizontal plane, the adhesive layer 16 is adhered to the surface of the flexible extensible substrate 17, when the medical double-sided adhesive tape is used, one side of the medical double-sided adhesive tape is adhered to the flexible extensible substrate 17, the medical adhesive silicone gel is coated on the surface of the flexible extensible substrate 17, and the medical adhesive silicone gel is trowelled and dried.

S3: preparing a plurality of sensor chips 12 having a first surface and a second surface corresponding to the first surface, the plurality of sensor chips 12 including an alcohol sensor 8, the plurality of sensor chips 12 further including: a chloride ion sensor 10, a sodium ion sensor 11, and a glucose sensor 9;

wherein the preparing of the plurality of sensor chips 12 comprises the steps of:

s31: preparing an output interface 1, a curved line 2, a gold electrode 3, a reference electrode 4 and an auxiliary electrode 5;

and respectively cleaning the glass plate by using 70% isopropanol and deionized water, spin-coating a layer of polydimethylsiloxane on the surface of the glass plate after drying, and then baking to obtain the polydimethylsiloxane layer. And taking a cleaned glass plate, pasting a layer of copper foil on the surface of the glass plate, fixing the glass plate by using an adhesive tape, spin-coating a layer of polyimide on the surface of the copper foil, and baking to obtain the polyimide substrate. And (3) tightly attaching the polyimide substrate and the polydimethylsiloxane layer, bonding the polyimide substrate and the polydimethylsiloxane layer together through Van der Waals force, removing the glass plate on the surface of the copper foil, and leaking the surface of the copper foil.

Sputtering a titanium layer on the surface of the copper foil by using a magnetron sputtering instrument, sputtering a gold layer, spin-coating a photoresist layer, using a photoetching machine, washing off part of the photoresist by using acetone after exposure and development, exposing the position of the reference electrode 4, electroplating silver, and chlorinating the plated silver to obtain the reference electrode 4; washing off all the photoresist by using acetone, drying by using an air gun, then spin-coating a layer of photoresist, washing off part of the photoresist by using acetone after exposure and development by using a photoetching machine, and sequentially using a gold etching solution, a titanium etching solution and a copper etching solution to obtain a naked output interface 1, a curved line 2, a gold electrode 3, a working electrode 6 and an auxiliary electrode 5.

The surfaces of the output interface 1, the curved line 2, the gold electrode 3, the working electrode 6, the reference electrode 4 and the auxiliary electrode 5 are coated with a layer of polyimide in a spin mode, a layer of photoresist is coated in a spin mode after baking, photoetching is carried out through a photoetching machine, etching is carried out through an RIE etching machine, and a plurality of sensor chips 12 without being modified by the working electrode 6 are obtained.

S32: the working electrode 6 is modified to obtain a chloride ion sensor 10, a sodium ion sensor 11 and a glucose sensor 9, and the gold electrode 3 is modified to obtain an alcohol sensor 8.

An alcohol sensor 8: the surface of the gold electrode 3 was washed with 70% isopropyl alcohol three times. The gold electrode surface was modified with dithiobis (succinimidyl propionate). Specifically, dithiobis (succinimidyl propionate) was dissolved in dimethyl sulfoxide to prepare a solution having a concentration of 10mM, the prepared solution was dropped on the surface of the gold electrode 33, incubated for 30 minutes, and then the surface of the modified gold electrode 3 was washed with dimethyl sulfoxide and PBS, respectively, to form a modified junction layer 7, and an ethyl glucuronide monoclonal antibody having a concentration of 10mg/L was dropped on the modified junction layer, incubated for 30 minutes, and washed three times with a blocking solution. The two output interfaces 1, the two curved lines 2 and the modified gold electrode 3 form an alcohol sensor 8.

When the alcohol sensor 8 is in contact with sweat, the ethyl glucuronide in the sweat is combined with the ethyl glucuronide monoclonal antibody of the alcohol sensor to cause the change of impedance, the impedance can reflect the concentration of the ethyl glucuronide in the sweat, and the concentration of the ethyl glucuronide in the sweat can directly reflect the concentration of alcohol in blood because the ethyl glucuronide is a direct metabolite of the alcohol.

The surface modification of the working electrode 6 of the chloride ion sensor 10 comprises the following steps: modifying a chloride ion selective film on the surface of the working electrode 6, wherein the preparation ratio of the chloride ion selective film is as follows: each 100mg of the anion selective membrane contains 2mg of ion selective carrier, 33mg of membrane matrix, 64.5mg of plasticizer and 0.5mg of anion exchanger, wherein the ion selective carrier is tetraphenyl porphin manganese chloride. The membrane matrix is polyvinyl chloride. The plasticizer is diisooctyl sebacate, which is used to increase the flexibility of the ion-selective membrane. The anion exchanger is tetradodecyl ammonium tetrakis (4-chlorophenyl) borate, and the chloride ion sensor 10 consists of two output interfaces 1, two curve lines 2, a reference electrode 4 and a working electrode 6 modified by a chloride ion selective film.

Wherein, when the chloride ion sensor 10 is in contact with sweat, the chloride ion selective membrane only allows chloride ions to enter the interior of the chloride ion sensor 10 from the membrane water interface, and the uneven distribution of charges at the membrane water interface caused by the process generates an interphase potential. The electrode potential between the working and reference electrodes reflects the concentration of ions in the solution containing chloride ions.

The surface modification of the working electrode 6 of the sodium ion sensor 11 comprises the following steps: modifying a sodium ion selective film on the working electrode 6, wherein the sodium ion selective film is prepared according to the following proportion: each 100mg of cation selective membrane contained 2mg of ion selective carrier, 33mg of membrane matrix, 64.5mg of plasticizer, and 0.5mg of cation exchanger. The ion selective carrier is ETH 2120. The membrane matrix is polyvinyl chloride. The plasticizer is diisooctyl sebacate, which is used to increase the flexibility of the ion-selective membrane. The cation exchanger is sodium tetrakis [3, 5-bis (trifluoromethyl) phenyl ] borate, and the sodium ion sensor 11 consists of two output interfaces 1, two curve lines 2, a reference electrode 4 and a working electrode 6 modified by a sodium ion selective film.

When the sodium ion sensor is in contact with sweat, the sodium ion selective film only allows sodium ions to enter the sodium ion sensing chip from the membrane water interface, and charges caused by the process are unevenly distributed on the membrane water interface to generate an interphase potential. The electrode potential between the working and reference electrodes reflects the concentration of ions in the solution containing sodium ions.

The sodium ion sensor 11 and the chloride ion sensor 10 would share an output interface 1 and a curve 2.

The surface modification of the working electrode 6 of the glucose sensor 9 comprises the following steps: electroplating nano-porous gold on the surface of the working electrode 6, then electroplating Prussian blue, modifying an electron transfer layer on the surface of the Prussian blue, and preparing 1: 1, dripping the mixed solution on the surface of Prussian blue, standing and airing to form an electron transfer layer, dripping an oxidase solution on the electron transfer layer, standing and airing to form an oxidase layer, modifying a protective layer on the surface of the oxidase layer, dissolving chitosan in 2% acetic acid, magnetically stirring for 1 hour, adding a cation exchanger, standing and airing to form the protective layer. The glucose sensor 9 consists of three output interfaces 1, three curved lines 2, a reference electrode 4, an auxiliary electrode 5 and a series of modified working electrode groups 6.

Wherein the oxidase and glucose in sweat are subjected to enzyme-catalyzed reaction to generate electron transfer at the working electrode of the glucose sensor 9, the working electrode of the glucose sensor 9 and the reference electrode of the glucose sensor 9 provide a bias voltage, and the current between the working electrode and the auxiliary electrode increases with the increase of the concentration of glucose

S4: transferring the plurality of sensor chips 12, wherein the first surfaces of the plurality of sensor chips 12 are combined with the second surface of the adhesive layer by means of transfer;

an optional plurality of sensor patches 12 are transferred to the second side of the adhesive layer and smoothed. The gold electrode 3 modification surfaces of the alcohol sensor 8, the chloride ion sensor 10, the sodium ion sensor 11, and the working electrode 6 modification surfaces of the glucose sensor 9 are second surfaces of the plurality of sensor chips 12.

S5: and 13, the sweat collection device 13 is combined with the adhesive layer 16, and the sweat collection device 13 is arranged on the second surfaces of the plurality of sensing chips 12.

Optionally, the sweat collection device 13 is attached to the second side of the plurality of sensor chips 12 by bonding the second side of the adhesive layer to contact the second side of the plurality of sensor chips 12, thereby securing the sweat collection device to the second side of the plurality of sensor chips 12.

According to another aspect of the present invention there is provided a sweat alcohol concentration multi-parameter monitoring patch comprising: a flexible malleable substrate 17, an adhesive layer 16, a plurality of sensor chips 11, a sweat collection device 13.

An adhesive layer 16 for connecting the flexible and malleable substrate 17, the plurality of sensor chips 11 and the sweat collection device 13, the adhesive layer 16 being disposed on the surface of the flexible and malleable substrate 17;

the plurality of sensing chips 11 are arranged on the surface of the bonding layer, the plurality of sensing chips 11 comprise an alcohol sensor 8, a chloride ion sensor 10, a sodium ion sensor 11 and a glucose sensor 9, the alcohol sensor 8, the chloride ion sensor 10, the sodium ion sensor 11 and the glucose sensor 9 are all provided with an output interface 1 and a curved line 2, the alcohol sensor 8 is provided with a modified gold electrode 3, the gold electrode 3 is connected with the output interface 1 through the curved line 2, the upper surface of the gold electrode 2 is provided with a modified connecting layer 7, the upper surface of the modified connecting layer is coated with an antibody layer, the chloride ion sensor 10 and the sodium ion sensor 11 are both provided with a reference electrode 4 and a modified working electrode 6, the glucose sensor 9 is provided with a reference electrode 4, an auxiliary electrode 5 and a modified working electrode 6, and the working electrode 6 is connected with the output interface 1 through the curved line 2, the reference electrode 4 is connected to the output interface 1 via the curved line 2, and the auxiliary electrode 5 is connected to the output interface 1 via the curved line 2.

And the sweat collecting device 13 is used for collecting and transmitting sweat, and the sweat collecting device 13 is arranged on the surfaces of the plurality of sensing chips 12.

Sweat alcohol concentration multi-parameter monitoring paster is provided with alcohol sensor 8 simultaneously, chloride ion sensor 10, sodium ion sensor 11 and glucose sensor 9, ethyl glucuronide concentration in the sweat can be monitored simultaneously, chloride ion concentration, sodium ion concentration and glucose concentration, alcohol concentration and glucose concentration in the human blood can be qualitatively reflected, internal chloride ion concentration and sodium ion concentration, thereby the control to the internal alcohol concentration of user has been realized, when the user is the driver, can know whether the driver drives for wine, chloride ion concentration and sodium ion concentration in the monitoring sweat, can know whether the internal moisturizing of user needs, glucose concentration in the monitoring sweat, can know whether the user appears hypoglycemia or hyperglycemia risk.

Optionally, the sweat collection device 13 is provided with a plurality of sweat absorbing ports 14, a liquid storage cavity 15 and a sweat releasing port 16, the sweat absorbing ports 14 are connected with the liquid storage cavity 15 through channels, and the liquid storage cavity 15 is connected with the sweat releasing port 16 through channels. The sweat absorbing port 14 absorbs sweat through capillary force and transmits the sweat to the liquid storage cavity 15 through the channel, the sweat is accumulated in the liquid storage cavity 15 until the amount of the sweat capable of being monitored is reached, the detected sweat is discharged through the sweat discharging port 16, the problem that the amount of the little sweat cannot be monitored is solved, and the purpose of real-time monitoring is achieved.

Optionally, the liquid storage cavity 15 is connected with the gold electrode 3, and the liquid storage cavity 15 is connected with the modified working electrode 6 of the chloride ion sensor 10, the sodium ion sensor 11 and the glucose sensor 9, so that various indexes in sweat can be monitored conveniently.

Optionally, the area of the sweat collection device 13 is larger than the area of the plurality of sensor chips 12, so as to facilitate bonding with the second side of the adhesive layer 16, and fix the sweat collection device 13 on the surface of the second side of the plurality of sensor chips 12.

Optionally, the adhesive layer 16 is a medical double-sided adhesive tape or silica gel, which is non-toxic to human body and does not cause allergic reaction, so as to achieve the purpose of adhesion.

Optionally, the thickness of the plurality of sensor chips 12 is 10 to 50 micrometers, and the sensor chips 12 are thin, so that flexibility is achieved, and no obvious foreign body sensation is felt when the sensor chip is worn.

As shown in fig. 5, the alcohol concentration monitoring patch is tightly attached to the surface of the skin of a human body through the adhesive layer 16, when the skin of the human body sweats, the sweat absorbing ports 14 of the sweat collection device 13 absorb sweat through capillary force and transmit the sweat to the liquid storage cavity 15 through the channels, and the sweat is accumulated in the liquid storage cavity 15 until the amount of the sweat which can be monitored is reached. The liquid storage cavity 15 is connected with the modified gold electrode 3 of the alcohol sensor 8, and the liquid storage cavity 15 is connected with the modified working electrodes 6 of the chloride ion sensor 10, the sodium ion sensor 11 and the glucose sensor 9. Therefore, sweat collected in the liquid storage cavity 15 is monitored by the alcohol sensor 8, the chloride ion sensor 10, the sodium ion sensor 11 and the glucose sensor 9, and the monitored sweat is discharged out of the sweat collection device 13 through the sweat discharging port 16.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.