KR102353644B1 - A Sensor for the depth of anesthesia - Google Patents

Abstract

The present invention relates to a depth of anesthesia sensor, and more particularly, is configured to include a strap provided with an electric circuit, and a sensing unit provided on the strap; The sensing unit is composed of a first hydrogel layer attached to the strap, a metal thin film attached to the first hydrogel layer, and a second hydrogel layer attached to the metal thin film and attached to the subject's skin, biosignal collection It has the effect of improving the efficiency.

Description

A Sensor for the depth of anesthesia

The present invention relates to a depth of anesthesia sensor, and more particularly, to a depth of anesthesia sensor capable of improving biosignal collection efficiency.

In general, when pain accompanies a subject in a medical practice such as surgery and treatment or skin care, the pain is removed or reduced by blocking nerve transmission through anesthesia.

In particular, in the case of a deep disease or severe symptomatic operation, general anesthesia is performed to remove all bodily reactions.

In other words, it is necessary to check the anesthesia state of the patient by detecting the depth of anesthesia, and to ensure that the operation is performed in a sufficiently anesthetized state to prevent the patient from suffering psychological pain due to awakening during surgery.

In the conventional depth of anesthesia sensor currently used for this purpose, a conductive material is used for an electrode for sensing a biosignal, but a flexible material is used for adhesion to the skin. In particular, a gel-type material that has adhesiveness to the skin and is flexible is used. Unlike metal, the gel-type material does not have conductivity as a whole, but is manufactured by combining components with conductivity, so there is a partial difference in conductivity. For this reason, there is a problem in that the collection efficiency of the biosignal is lowered or the accuracy is lowered.

Application No.: 10-2010-0035977 (Registration No.: 10-1079785, Title of Invention: Electroencephalogram analysis device for calculating depth of anesthesia index)

The present invention has been devised to solve the problems of the prior art, and anesthesia capable of overcoming a decrease in bio-signal collection efficiency due to non-uniform conductivity of the conventional bio-signal collecting electrode and improving the accuracy of collected bio-signals It aims to provide a depth sensor.

The depth of anesthesia sensor according to the present invention for solving the above problems is configured to include a strap provided with an electric circuit, and a sensing unit provided on the strap; The sensing unit consists of a first hydrogel layer attached to the strap, a metal thin film attached to the first hydrogel layer, and a second hydrogel layer attached to the metal thin film and attached to the subject's skin.

Here, the metal thin film is made of any one of tin, platinum, copper, silver, and aluminum.

In addition, an adhesive pad is provided on the strap around the sensing unit.

In addition, the sensing unit is made of a plurality of electrodes; The plurality of electrodes are a ground electrode, a reference electrode installed to be spaced apart from the ground electrode, and first and second measurement electrodes respectively installed on both sides of the ground electrode and the reference electrode so that the ground electrode and the reference electrode are positioned therebetween. is composed

The depth of anesthesia sensor of the present invention configured as described above employs an electrode as a hydrogel and consists of two hydrogel layers, and then inserts a metal thin film into the first hydrogel layer and the second hydrogel layer to increase the biosignal collection efficiency. There is an advantage.

1a and 1b are views showing the depth of anesthesia sensor according to the present invention.
2 is a view showing a cross-section of the depth of anesthesia sensor according to the present invention.
3 is a graph showing the biosignal collection efficiency. (a) is a case where the depth of anesthesia sensor according to the present invention is worn, and (b) is a case where the depth of anesthesia sensor according to the prior art is worn.

Hereinafter, an embodiment of the depth of anesthesia sensor according to the present invention will be described in detail with reference to the accompanying drawings.

1A and 1B are views showing the depth of anesthesia sensor according to the present invention, and FIG. 2 is a view showing a cross-section of the depth of anesthesia sensor according to the present invention.

3 is a graph showing the biosignal collection efficiency, (a) is a case in which the depth of anesthesia sensor according to the present invention is worn, and (b) is a case in which the depth of anesthesia sensor according to the prior art is worn.

The depth of anesthesia sensor according to the present invention is configured to include a strap (10) and a sensing unit (20) provided in the strap (10).

The strap 10 serves as a base of the sensor, and an electric circuit 11 for sensing and transmitting a biosignal is provided, and an adhesive pad 12 attached to the skin of the subject is provided.

The strap 10 should be made of an insulating material, and the material should be selected in consideration of the characteristics of the human body, particularly the head of the human body to which the depth of anesthesia sensor of the present invention is attached. That is, in consideration of the fact that the strap 10 has a curved surface rather than a flat head, a material that is flexible in bending or bending should be selected.

The electric circuit 11 senses a bio-signal generated as an electric signal, collects it, and transmits it to a device that utilizes the bio-signal. The electric circuit 11 is preferably configured in the form of a thin-film conductor so as not to be damaged by the bending of the strap 10 .

Since the adhesive pad 12 has high human body adhesion, it is necessary to select a material that is well attached to the skin surface, such as the forehead or scalp, and can be easily removed. It is preferable to do

The adhesive pad 12 is not provided over the entire area of the strap 10, but is provided around the sensing unit 20 to help the sensing unit 20 to adhere well to the skin of the subject.

The sensing unit 20 is composed of a plurality of electrodes, and includes a ground electrode 21 and a reference electrode 22, and a ground electrode 21 and a ground electrode 21 so that the ground electrode 21 and the reference electrode 22 are positioned therebetween. It is composed of first and second measurement electrodes 23 and 24 respectively installed on both sides of the reference electrode 22 .

The ground electrode 21 is in contact with a part of the body to keep the subject in a ground state for electrical safety of the subject when measuring biosignals. That is, the ground electrode 21 prevents a safety accident due to an abnormal voltage when measuring a biosignal, and when a fault current occurs, it is rapidly discharged to the outside of the human body to suppress an abnormal potential rise, thereby promoting electrical safety of the subject. carry out

The reference electrode 22 is a reference electrode for measuring biosignals, and is provided as a reference for measuring a potential difference with the first and second measurement electrodes 23 and 24 . The reference electrode 22 is installed to be spaced apart from the ground electrode 21 by a predetermined distance.

The first measuring electrode 23 is attached to the head of the human body to perform anesthesia or to sense a biosignal during anesthesia, and measures and detects EEG generated from the head. The first measuring electrode 23 is installed on either side of both sides of the reference electrode 22 but far away from the ground electrode 21 .

The second measuring electrode 24, like the first measuring electrode 23, is attached to the head of the human body to perform anesthesia or to sense biosignals during anesthesia, and measure and detect brain waves generated in the head. .

Since the measuring electrode performs the function of measuring and detecting the biosignal, collecting and analyzing the biosignal in a wider range is more advantageous in consideration of the precision or efficiency of measurement. Therefore, as much as possible, the second measuring electrode 24 is installed to be far away from the first measuring electrode 23 . That is, the second measuring electrode 24 is installed at any one of both sides of the ground electrode 21 , and is installed far away from the first measuring electrode 23 .

The sensing unit 20 made of a plurality of electrodes as described above is composed of a first hydrogel layer 20a, a metal thin film 20b and a second hydrogel layer 20c stacked as shown in FIGS. 1A and 2 . That is, the ground electrode 21, the reference electrode 22, and the first and second measurement electrodes 23 and 24 are the first hydrogel layer 20a, the metal thin film 20b, and the second hydrogel layer 20c in the vertical direction. made by stacking

As described above, in the prior art, one hydrogel layer was used, but there is a difference in the intensity of the collected bio-signals depending on the difference in conductivity in the hydrogel layer used for the electrode, and the collection efficiency and accuracy of the bio-signals are poor in the weak conductive part. there was.

In order to compensate for this difference in conductivity, the present invention configures the hydrogel layer into two layers and inserts the metal thin film 20b in the middle so that the biosignals collected in the second hydrogel layer 20c are transmitted to the metal thin film 20b and After forming a uniform potential in the metal thin film 20b, it is transferred to the first hydrogel layer 20a, thereby generating an effect of improving the non-uniformity of the conventional conductivity. Of course, even by bonding the two hydrogel layers, the conductivity uniformity can be partially improved, but the collection efficiency decreases due to air bubbles or poor contact in the middle, so the metal thin film 20b also serves to facilitate contact between the two layers can do.

The first hydrogel layer (20a) is attached to the bottom surface of the strap (10).

The metal thin film 20b is attached to the bottom surface of the first hydrogel layer 20a, and the material is made of any one of tin, platinum, copper, silver, and aluminum. Of course, the material of the metal thin film 20b is not limited to the above-described materials, and other conductive metals are also possible.

The second hydrogel layer (20c) is attached to the bottom surface of the metal thin film (20b). Hydrogel has excellent adhesion to the skin, does not cause problems due to skin irritation when attached to the skin, and is advantageous for measuring and collecting biosignals because it adheres well to the skin with excellent adhesion even after adhesion and detachment several times.

As such, the present invention can solve the conventional non-uniformity of conductivity by composing the hydrogel layer into two layers and inserting the metal thin film 20b therebetween, and furthermore, the first hydrogel layer (20a) and the second hydrogel layer (20c) It is possible to improve the biosignal collection efficiency by preventing elements that inhibit biosignal collection, such as air bubbles or negative contact, from being interposed therebetween.

The bio-signal collection efficiency of the present invention can be confirmed through the graph of FIG. 3 showing a case where the depth of anesthesia sensor according to the present invention was worn (a) and a case where the conventional depth of anesthesia sensor was worn (b). .

3, the X-axis represents time and the Y-axis represents the depth of anesthesia. And, the uppermost purple graph shows the depth of anesthesia, the pink graph below shows the CAI index, the green graph below shows the Shannon entropy index, and the bottom black graph shows the EMG signal. This is the graph shown.

In FIG. 2, about 200 on the basis of the X-axis shows the biosignals before anesthesia (that is, brain activation state). Since high-frequency signals are mainly generated in the active state, it is important to collect high-frequency signals to more precisely measure the depth of anesthesia. do.

Comparing (a) and (b) of Figure 3, the CAI graph and Shannon entropy index graph of (a) within 200 on the X-axis are approximately 10% higher than the CAI graph and Shannon entropy index graph of (b) it can be seen that This shows that when the depth of anesthesia sensor according to the present invention is worn, the bio-signal collection efficiency is higher than when the conventional depth of anesthesia sensor is worn.

10: strap 11: electrical circuit
12: adhesive pad 20: sensing unit
20a: first hydrogel layer 20b: metal thin film
20c: second hydrogel layer 21: ground electrode
22: reference electrode 23: first measurement electrode
24: second measuring electrode

Claims (4)

It is configured to include a strap 10 provided with an electric circuit 11, and a sensing unit 20 provided in the strap 10,
The sensing unit 20 includes a first hydrogel layer 20a attached to the strap 10, a conductive metal thin film 20b attached to the first hydrogel layer 20a, and the metal thin film 20b) Consists of a second hydrogel layer (20c) attached to the skin of the subject,
Depth of anesthesia sensor, characterized in that the adhesive pad (12) is provided on the strap (10) around the sensing unit (20).
The method according to claim 1,
The metal thin film (20b) is anesthesia depth sensor, characterized in that the material is composed of any one of tin, platinum, copper, silver, aluminum.
delete The method according to claim 1,
The sensing unit 20 is made of a plurality of electrodes,
The plurality of electrodes includes a ground electrode 21;
a reference electrode 22 spaced apart from the ground electrode 21;
It is characterized in that it consists of first and second measuring electrodes 23 and 24 respectively installed on both sides of the ground electrode 21 and the reference electrode 22 so that the ground electrode 21 and the reference electrode 22 are positioned therebetween. depth of anesthesia sensor.

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