KR102241309B1 - Optical Simulator Controlled by Electrowetting-on-Dielectric - Google Patents

Abstract

An optical stimulator according to an embodiment of the present invention is a device for stimulating a specific nerve cell in the body to obtain a neural signal, comprising an electrode, a body portion provided with a plurality of electrical terminals connected to the electrode, and one side of the body portion A plurality of conductive water droplets for driving the electrowetting, extending from the optical path substrate disposed to be spaced apart from each other by a predetermined distance; And a light source unit disposed on the main body and generating light in a direction in which conductive water droplets formed on the optical path substrate are arranged, and each of the electrical terminals is connected to each of the conductive water droplets, and the conductive water droplets are electrically When an electric field is applied by a terminal, light passes through, and when an electric field is not applied, light that proceeds is reflected to the top of the conductive water droplet to stimulate specific neurons.
Accordingly, not only nerve cells of a single stimulation point can be stimulated, but also nerve cells of several points in the depth direction can be stimulated, so that the nerve signals can be measured and analyzed more precisely.

Description

Optical Simulator Controlled by Electrowetting-on-Dielectric {Optical Simulator Controlled by Electrowetting-on-Dielectric}

The present invention relates to a photostimulator that changes the optical path to nerve cells to be stimulated by controlling the shape of conductive water droplets in an electrowetting method.

In recent years, optogenetics, called Optogenetics, have attracted the attention of those currently engaged in neuroscience or engineering. In optogenetics, some neurons modify their genes to respond to specific wavelengths of light. These genetically modified neurons react when exposed to light in a specific wavelength range and emit nerve signals, and because stimulation is possible for single neurons, more local stimulation is possible than nerve stimulation through conventional electricity. There is a big advantage.

In general, optical fibers, LEDs, and OLEDs were used as stimulation devices for this purpose. In the case of OLEDs and LEDs, they can emit light with only a power source, which has the advantage of reducing the size of the overall device, but the area that emits light is relatively larger than that transmitted through an optical fiber. In addition, manufacturing ultra-small LEDs and OLEDs has a very high manufacturing cost, and has a lower intensity than light transmitted through optical fibers, making it difficult to reach the response threshold of genetically modified neurons.

In the case of a stimulation device using an optical fiber, the optical fiber part is implanted in the specimen, and there is a light source such as a laser outside, and it is used by connecting it to the end of the optical fiber only during stimulation. The part that can be stimulated is the end of an optical fiber inserted into the brain or nerve, and for this reason, there is a problem that it is difficult to use it in different locations or other areas depending on the depth in the brain of the experimenter implanted with the device for a chronic experiment. In order to perform the experiment while changing the location of the depth of the brain, it is possible only through an acute experiment. These conventional optogenetics devices using optical fibers limit the research area of optogenetics.

The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a photostimulator capable of performing photostimulation at multiple sites in the depth direction rather than a single site when studying nervous system optogenetics through a long or short period of time. .

An object of the present invention is to provide a photostimulator capable of applying a precise stimulus at a position closer to a target neuron to be stimulated, and an electrode for recording the applied stimulus as well as being able to be variously and closely disposed.

An optical stimulator according to an embodiment of the present invention is a device for stimulating specific nerve cells in a body to obtain a nerve signal, comprising: a main body including an electrode and having a plurality of electrical terminals connected to the electrode; An optical path substrate extending from one side of the main body and on which a plurality of conductive water droplets for driving electrowetting are spaced apart from each other by a predetermined distance; And a light source unit disposed on the main body and generating light in a direction in which conductive water droplets formed on the optical path substrate are arranged; wherein each of the electrical terminals is connected to each of the conductive water droplets, and the conductive water droplets are the When an electric field is applied by an electric terminal, light passes through the shape change, and when the electric field is not applied, the initial shape of the conductive droplet is maintained and the light that proceeds is reflected to the top of the conductive droplet, thereby causing specific neurons to be transmitted. It is characterized by stimulating.

An optical stimulator according to an embodiment of the present invention is a device for stimulating specific nerve cells in a body to obtain a nerve signal, comprising: a main body including an electrode and having a plurality of electrical terminals connected to the electrode; An optical path substrate extending from one side of the main body and on which a plurality of conductive water droplets for driving electrowetting are spaced apart from each other by a predetermined distance; And a light source unit disposed on the main body and generating light in a direction in which conductive water droplets formed on the optical path substrate are arranged; wherein each of the electrical terminals is connected to each of the conductive water droplets, and the conductive water droplets are the When an electric field is applied by an electrical terminal, light passes through the shape change, and when the electric field is not applied, the light that proceeds by maintaining the initial shape of the conductive droplet is refracted to the lower portion of the conductive droplet to cause specific nerve cells. It is characterized by stimulating.

According to the present invention, the surface state of the conductive water droplets is changed by turning on or off the electrowetting electrode connected to a portion desired by the user by using the electrowetting properties of the conductive water droplets provided on the optical path substrate. It is possible to stimulate a nerve cell as a target by changing the path of light that proceeds along the way.

According to the present invention, in applying this embodiment to optogenetics, it is possible to stimulate neurons at multiple points in the depth direction instead of stimulating neurons at a single point, so that the measurement of selective nerve signals with more precision and high resolution And analysis can be performed.

According to the present invention, light can travel to a specific point in the depth direction, and a recording electrode is disposed at a point where the progress of light is changed, so that a signal generated from a target neuron can be obtained at a closer distance.

1 is a diagram showing the driving principle of electrowetting
2 is a perspective view showing an electrowetting type photostimulator according to a first embodiment of the present invention
3 is a perspective view showing only a partial configuration of the photostimulator according to the first embodiment of the present invention
4 is a cross-sectional view showing a portion in which an optical path is changed according to a first embodiment of the present invention
5 is a plan view of FIG. 4 viewed from above
6 is a cross-sectional view showing a traveling direction of an optical path according to a first embodiment of the present invention
7 is a perspective view showing an electrowetting type photostimulator according to a second embodiment of the present invention
8 is a perspective view showing only a partial configuration of a photostimulator according to a second embodiment of the present invention
9 is a cross-sectional view showing a portion in which an optical path is changed according to a second embodiment of the present invention
10 is a plan view as viewed from the top of FIG. 9
11 is a cross-sectional view showing a traveling direction of an optical path according to a second embodiment of the present invention

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, but are not limited or limited by the embodiments of the present invention. In describing the present invention, detailed descriptions of known functions or configurations may be omitted to clarify the subject matter of the present invention.

Electrowetting refers to electrically transforming the shape of a conductive water droplet on a solid surface or inducing a change in the contact angle between the solid surface in contact with the water droplet, and generating a conductive water droplet and an electric field in a way to effectively reproduce this. An insulator is placed between the electrodes, which is called Electrowetting-on-dielectric (EWOD).

1 is a diagram showing the driving principle of this electrowetting.

Referring to FIG. 1, a device using an electrowetting driving method that is generally researched and used is composed of an electrode 10, an insulator 11, and a conductive water drop 12.

Until an electric field is generated by supplying power to the electrode, the charges of the conductive water droplets are spread amorphously and the contact angle is θ _s . When electricity is not supplied to the electrode 10, the insulator 11 has a hydrophobic action to push the conductive water droplets, so that the contact area between the insulator and the conductive water droplet is reduced, and the contact angle between the conductive water droplet and the insulator is large.

When an electric field is applied to a conductive droplet in this state, charges in the droplet accumulate in the area where the solid and liquid contact by the electric field induction, which reduces the surface tension of the droplet. Accordingly, the shape of the water droplet spreads, and the contact angle (θ _s (V)) decreases compared to the contact angle (θ _{s) before the electric field is generated.}

Among these configurations, it is not necessary to have an insulator between the water droplet and the electrode, but the reason for use is as follows. 1) By protecting the water droplets from the electrode, it can generate a higher electric field. 2) By applying a very hydrophobic material thinly, the water droplets can be moved easily and the initial contact angle can be increased. Also, the contact angle hysterisis is small. For these reasons, the stable performance of the electrowetting application can be guaranteed.

The present invention is to propose a light stimulator capable of applying stimulation to specific nerve cells by using the electrowetting driving method as described above.

2 is a perspective view showing the electrowetting type photostimulator according to the first embodiment of the present invention. 2, the photostimulator 20 of the first embodiment includes a main body 26, an electrical terminal 21, a light source 22, a recording electrode 24, a light traveling slit 23, and an optical path substrate ( 25) and conductive water droplets 30.

The photostimulator of the first embodiment is an embodiment in which light generated from the light source unit 22 reaches the surface of the conductive water droplet 30 and is reflected to advance the optical path, and shows an example of a reflective photostimulator.

An electrode (not shown) is disposed inside the main body 26, and a plurality of electrical terminals 21 connected to the electrode are provided. Each of the electrical terminals 21 may extend along the optical path substrate 25 on which the conductive water droplets 30 are placed and may be connected to any one of the conductive water droplets. One electrical terminal 21 is disposed to control the shape of one conductive water droplet, and the number of electrical terminals 21 may be formed equal to the number of conductive water droplets 30.

An optical path substrate 25 providing a direction in which light travels may be formed on one side of the main body 26 to have a predetermined length. The optical path substrate 25 is an area in which an electrowetting device for determining a propagation direction of light is provided, and is inserted into the body to stimulate target nerve cells according to the propagation direction of light.

A light source unit 22 that provides a specific light may be disposed at the starting point. In the light source unit 22, light may travel in the same direction as the extending direction of the optical path substrate 25.

A plurality of conductive water droplets 30 may be formed on an upper portion of the optical path substrate 25 at predetermined intervals in a path through which light generated from the light source unit 22 passes. The number and spacing of the conductive water droplets 30 may be variously changed according to the type of target neuron and the setting of the stimulation point.

When a part of the optical path substrate 25 is enlarged, conductive water droplets 30 may be disposed on the optical path substrate 25 to be spaced apart at predetermined intervals. Liquid metal may be used for the conductive water droplets 30 in the first embodiment of the present invention. Liquid metal refers to a metal in a liquid state at a use temperature, and mercury at room temperature, sodium, lithium and sodium-potassium alloys, and Galinstan alloys used in coolants of nuclear reactors or high-temperature power engines may be used.

In addition, a light advancing guard 27 extending in the longitudinal direction of the optical path substrate 25 and formed on a side surface of the conductive water droplet 30 may be formed. A glass cover 29 may be provided on the conductive water droplets 30. The light progress guard 27 and the glass cover 29 are provided to prevent the traveling light from deviating to the outside of the photostimulator. The glass cover 29 may be a material manufactured in the form of a film.

The glass cover 29 may be provided with a light advancing slit 23 providing a space for transmitting light reflected from the conductive water droplets at a position corresponding to the upper portion of the conductive water droplets. The light-progressing slit 23 may be manufactured in a form in which a transparent material film or a predetermined space is opened so that the reflected light can be transmitted.

In addition, a recording electrode 24 for measuring a nerve signal may be disposed on the glass cover 29. One or more of the recording electrodes 24 may be formed on one side of each light-progression slit 23, and when stimulation is applied to a neuron as a target through the light-progression slit 23, by measuring its nerve signal You can grasp the response of nerve cells to stimuli and build a database for this.

3 is a perspective view showing only a partial configuration of the photostimulator according to the first embodiment of the present invention. Referring to FIG. 3, in the photostimulator of the first embodiment, a light path using electrowetting is shown in more detail.

As shown, the light 28 generated from the light source 22 is incident on the conductive droplet 30 placed on the optical path at a predetermined angle, and is reflected according to the surface angle of the conductive droplet to serve as an upper target. It is configured to reach the cell. In this embodiment, the shape of the conductive water droplets 30 may be changed to change the traveling direction of the light 28, or the light 28 may pass through the upper portion of the conductive water droplets 30 as it is.

The point in which the shape of the conductive water droplets 30 is changed as described above is characterized in a region where the conductive water droplets 30 are in contact, and will be described.

4 is a cross-sectional view showing a portion in which an optical path is changed according to the first embodiment of the present invention. Referring to FIG. 4, in particular, a region surrounding the conductive water droplet 30 is shown. In order to drive electrowetting, a condition for maintaining a predetermined contact angle when electricity is not flowing to the conductive water droplets 30 must be satisfied. To this end, the active electrode 33 may be formed in a ring shape along the outer periphery of the conductive water droplets in a region on the optical path substrate 25 where the conductive water droplets 30 are seated.

In addition, an insulating layer 32 made of a material having hydrophobic and electrically insulating properties is formed while covering the active electrode 33. The insulating layer 32 is formed to protect the water droplets from the electrode and generate a higher electric field. By thinly applying a material having a hydrophobicity, the water droplets can be easily moved and the initial contact angle can be increased. In addition, a ground electrode 34 may be formed in the center of the conductive water droplet on the insulating layer 32.

The ground electrode 34 directly contacts the center of the conductive water droplet 30, and the active electrode 33 is disposed under the insulating layer 32 so as not to contact the conductive water droplet 30. In addition, in order to prevent external influences on the progress of light incident on the conductive droplet 30, a light progress guard 27 blocking both sides of the conductive droplet 30 and a glass cover 29 formed on the upper side may be provided. have. A part of the glass cover 29 may be provided with a light advancing slit 23 partially open or formed of a transparent material to provide a path through which the reflected light travels.

In addition, in order to maintain the shape of the conductive water droplets, a thin film such as teflon and parlylene-C may be used, and a thin film may be formed as an outer layer of the conductive water droplets. The size of the conductive water droplets varies depending on the shape and size of the insulating layer 32 on which the conductive water droplets are placed, and may also vary according to a method of forming the conductive water droplets.

5 is a plan view of FIG. 4 viewed from above.

As shown in FIG. 5, an active electrode 33 for applying an electric field to the conductive water droplets is disposed below in the area where the conductive water droplets are seated, and one end of the active electrode 33 is connected to the electrical terminal 21. An electric field is applied to the conductive water droplets.

In addition, an insulating layer 32 is disposed on the active electrode 33 to which the outer periphery of the lower surface of the conductive water droplets comes into contact, and a ground electrode 34 is provided in the upper portion of the insulating layer 32 corresponding to the center of the conductive water droplets. As a result, the electric field applied to the conductive water droplets can be turned on or off.

6 is a cross-sectional view showing a traveling direction of an optical path according to the first embodiment of the present invention. Referring to FIG. 6, the principle of operation of the photostimulator of the first embodiment in which the direction of light travel is changed according to the driving of electrowetting can be described in detail.

6 shows an example of changing the light traveling direction using a plurality of conductive water droplets according to the driving of electrowetting, excluding some configurations.

A plurality of conductive water droplets 30a and 30b may be disposed on the optical path substrate 25 so as to be spaced apart by a predetermined distance, and the light 28 generated by the light source 22 proceeds on the optical path substrate 25. When the active electrode connected to the first conductive droplet 30a is turned on and an electric field is applied, charges in the first conductive droplet 30a are accumulated in the contact between the solid and the liquid by induction of the electric field, which reduces the surface tension. do. As a result, the shape of the water droplet spreads, and as a result, the height of the water droplet decreases, so that the light passes through the upper portion of the first conductive water droplet 30a.

When the electric field is not applied to the second conductive droplet 30b, the light 28 passing through the top of the first conductive droplet 30a is reflected from the surface of the second conductive droplet 30b and proceeds to point A. Point A can be defined as a point where the target nerve cell is located, and when an electric field is applied to the second conductive droplet 30b, the light can move in the direction of B and stimulate nerve cells in other parts. . In order to satisfy the above conditions, the height of light that proceeds must be set between the height of the water droplet to which the electric field is applied and the height of the water droplet to which the electric field is applied.

That is, in the first embodiment of the present invention, in order to stimulate a nerve cell targeted by a user, it may be performed by preventing an electric field from being applied from a conductive droplet disposed in a region in which the target nerve cell is located. For example, if you want to stimulate nerve cells located at the most end of the optical path, light generated by applying an electric field to all conductive water droplets other than the conductive water droplets located at the most end can travel to the end of the optical path substrate. .

Conversely, if you want to stimulate the nerve cells at the initial entrance, the path of light can be changed at the entrance by not applying a magnetic field to all conductive water droplets formed on the optical path substrate.

As described above, the optical stimulator proposed in this embodiment allows a user to perform photo stimulation at multiple sites in the depth direction instead of at a single site.

7 is a perspective view showing an electrowetting type photostimulator according to a second embodiment of the present invention.

Referring to FIG. 7, the photostimulator 40 of the second embodiment may include a body portion 47, an electrical terminal 41, a light source portion 42, an optical path substrate 46, and a conductive water droplet 50.

The photostimulator of the second embodiment is an embodiment in which light generated from the light source unit 42 is refracted after reaching the surface of the conductive water droplet 50 to advance the optical path, and shows an example of a refractive type photostimulator.

An electrode (not shown) is disposed inside the main body 47, and a plurality of electrical terminals 41 connected to the electrode are provided. Each of the electrical terminals 41 may extend along the optical path substrate 46 on which the conductive water droplets 50 are placed, and may be connected to an electrode that applies an electric field to any one of the conductive water droplets. One electrical terminal 41 is disposed to control the shape of one conductive water droplet, and the number of electrical terminals 41 may be formed equal to the number of conductive water droplets 50.

An optical path substrate 46 providing a direction in which light travels may be formed on one side of the main body 47 to have a predetermined length. The optical path substrate 46 is an area in which an electrowetting device for determining a propagation direction of light is provided, and is inserted into the body to stimulate target nerve cells according to the propagation direction of light.

A light source unit 42 for generating specific light may be disposed at a point where the optical path substrate starts. In the light source unit 42, light may travel in the same direction as the extending direction of the optical path substrate 46.

On the upper portion of the optical path substrate 46, a plurality of conductive water droplets 50 may be formed in a path through which light generated from the light source unit 42 passes, spaced apart at predetermined intervals. The number and spacing of the conductive water droplets 50 may be variously changed according to the type of target neuron and the setting of the stimulation point.

When a part of the optical path substrate 46 is enlarged, conductive water droplets 50 may be disposed on the optical path substrate 46 to be spaced apart at predetermined intervals. The conductive droplet 50 may be a conductive liquid having a high refractive index on the surface.

8 is a perspective view showing only a partial configuration of a photostimulator according to a second embodiment of the present invention. Referring to FIG. 8, a more detailed illustration of a light path using electrowetting in the photostimulator of the second embodiment.

As shown, the light 45 generated from the light source unit 42 is incident on the conductive droplet 50 placed on the optical path at a predetermined angle, and is refracted according to the surface angle of the conductive droplet to serve as a target underneath. It is configured to reach the cell. In this embodiment, the shape of the conductive water droplets 50 may be changed to change the traveling direction of the light 45, or the light 45 may pass through the upper portion of the conductive water droplets 50 as it is.

The point in which the shape of the conductive water droplet 50 is changed as described above is characterized in a region in which the conductive water droplet 50 is in contact, and will be described.

9 is a cross-sectional view showing a portion in which an optical path is changed according to a second embodiment of the present invention.

Referring to FIG. 9, in particular, a region surrounding one conductive water droplet 50 is shown. In order to drive electrowetting, a condition for maintaining a predetermined contact angle must be satisfied when electricity is not flowing to the conductive water droplets 50. To this end, a seating portion 48 having a circular inclined portion whose diameter is narrowed in a depth direction may be formed in an area where the conductive water droplets 50 are seated on the optical path substrate 46.

An active electrode 52 may be formed on an edge of the seating portion 48 to surround the edge of the conductive water droplet 50.

In addition, an insulating layer 51 made of a material having hydrophobic and electrically insulating properties is formed along the inclined portion while covering the active electrode 52. In addition, a ground electrode 53 may be formed in the center of the conductive water droplet.

The ground electrode 53 directly contacts the center of the conductive water droplet 50, and the active electrode 52 is disposed under the insulating layer 51 so as not to contact the conductive water droplet 50. In addition, in order to prevent external influences on the progress of light incident on the conductive droplet 50, a light progress guard blocking both sides of the conductive droplet 50 and a glass cover formed on the upper side may be provided.

In addition, materials such as teflon and parlylene-C may be used to maintain the shape of the conductive water droplets, and a thin film may be formed as an outer layer of the conductive water droplets. The size of the conductive water droplets varies depending on the shape and size of the insulating layer 51 on which the conductive water droplets are placed, and may also vary according to a method of forming the conductive water droplets.

10 is a plan view of FIG. 9 viewed from above.

As shown in FIG. 10, an active electrode 52 for applying an electric field to the conductive water droplets is disposed on the seating portion 48 in the area where the conductive water droplets are seated, and one end of the active electrode 52 is an electrical terminal ( 41) to apply an electric field to the conductive water droplets.

In addition, an insulating layer 51 is disposed on the active electrode 52 to which the outer periphery of the lower surface of the conductive water droplets comes into contact, and a ground electrode 53 is provided in a portion corresponding to the center of the conductive water droplet to prevent an electric field applied to the conductive water droplets. It can be turned on or off. In the second embodiment, since the traveling direction of light is refracted and passes through the ground electrode 53 and proceeds downward, the ground electrode 53 must be made of a transparent material such as ITO.

A recording electrode 54 may be disposed opposite the ground electrode 53 for recording a neural signal. The recording electrode 54 can be formed of a transparent material such as ITO because it does not obstruct the optical path and must be transmitted.

11 is a cross-sectional view showing a traveling direction of an optical path according to a second embodiment of the present invention. Referring to FIG. 11, the principle of operation of the photostimulator of the second embodiment in which the direction of light travel is changed according to the driving of electrowetting can be described in detail.

FIG. 11 shows an example of changing the light traveling direction using a plurality of conductive water droplets according to the driving of electrowetting, excluding some configurations.

On the optical path substrate 46, a plurality of conductive water droplets 50a, 50b may be disposed in the seating portion so as to be spaced apart by a predetermined distance, and the light 45 generated from the light source 42 may be disposed on the optical path substrate 46. It goes on. When the active electrode connected to the first and second conductive water droplets 50a and 50b is turned on and an electric field is applied, charges in the first and second conductive water droplets 50a and 50b contact the solid and the liquid due to the electric field induction Accumulates in, which reduces the surface tension. As a result, the shape of the water droplets spreads, and as a result, the conductive water droplets move downward along the inclined portion, their height decreases, and the advancing light passes through the upper portions of the first and second conductive water droplets 50a and 50b. .

When the electric field is not applied to the second conductive droplet 50b, the light 28 passing through the top of the first conductive droplet 50a is refracted at the surface of the second conductive droplet 30b and proceeds downward. In order to satisfy the above conditions, the height of light that proceeds must be set between the height of the water droplet to which the electric field is applied and the height of the water droplet to which the electric field is applied.

That is, the second embodiment of the present invention differs from the first embodiment in that the conductive water droplets are attached to the seating portion, which is a pocket formed vertically or having an inclination, and refracts the light traveling downward. .

The photostimulator of the second embodiment may be performed by preventing an electric field from being applied from a conductive droplet disposed in a region where a target nerve cell is located in order to stimulate a nerve cell targeted by a user. For example, if you want to stimulate nerve cells located at the most end of the optical path, light generated by applying an electric field to all conductive water droplets other than the conductive water droplets located at the most end can travel to the end of the optical path substrate. .

On the contrary, if you want to stimulate the nerve cells at the initial entrance, you can stimulate the nerve cells at the site corresponding to the entrance by changing the path of light at the entrance by not applying a magnetic field to all conductive water droplets formed on the optical path substrate.

As described above, the optical stimulator proposed in this embodiment allows a user to perform photo stimulation at multiple sites in the depth direction instead of at a single site.

In the first and second embodiments of the present invention, precise stimulation can be applied at a position closer to the target neuron to be stimulated, and electrodes for recording the applied stimulation are also various and closely arranged photostimulators. By providing, it is possible to perform a more precise analysis of the stimulation of nerve cells.

In the above, the present invention has been described with reference to its preferred embodiments, but these are only examples and do not limit the present invention, and those of ordinary skill in the field to which the present invention pertains will not depart from the essential characteristics of the present invention. It will be appreciated that various modifications and applications not illustrated above are possible. For example, each component specifically shown in the embodiment of the present invention can be modified and implemented. And differences related to these modifications and applications should be construed as being included in the scope of the present invention defined in the appended claims.

20, 40: optical stimulator
21, 41: electrical terminals
22, 42: light source unit
23: light advance slit
24, 54: recording electrode
25, 46: optical fiber board
27: Gwangjin Guard
29: glass cover
30, 50: conductive water droplets
32, 51: insulating layer
33, 52: active electrode
34, 53: ground electrode
48: seat
28, 45: light path
26, 47: main body
30a, 50a: first conductive water droplet
30b, 50b: second conductive water droplets

Claims (18)

As a device for obtaining nerve signals by stimulating specific nerve cells in the body,
A body portion including an electrode and provided with a plurality of electrical terminals connected to the electrode;
An optical path substrate extending from one side of the main body and on which a plurality of conductive water droplets for driving electrowetting are spaced apart from each other by a predetermined distance; And
It is disposed on the main body, the light source unit for generating light in a direction in which the conductive water droplets formed on the optical path substrate are arranged; includes,
Each of the electrical terminals is connected to each of the conductive water droplets, and the conductive water droplets pass light through a shape change when an electric field is applied by the electrical terminal, and the initial shape of the conductive water droplets when no electric field is applied. An optical stimulator that stimulates specific nerve cells by reflecting the light proceeding by maintaining it to the top of the conductive water droplets. The method of claim 1,
An optical stimulator provided on an upper surface of the optical path substrate in a circular ring shape with an active electrode for applying an electric field to the conductive water droplets. The method of claim 2,
An optical stimulator in which an insulating layer in contact with an outer peripheral surface of the conductive water droplet is deposited on an upper surface of the active electrode. The method of claim 3,
An optical stimulator in which a ground electrode in contact with the center of the conductive water droplet is disposed on an upper surface of the insulating layer. The method of claim 1,
The conductive water droplets are optical stimulators made of liquid metal. The method of claim 1,
An optical stimulator extending in the longitudinal direction of the optical path substrate and provided with a light advancing guard formed on a side surface of the conductive droplet and a glass cover covering an upper portion of the conductive droplet to block optical interference from the outside. The method of claim 1,
A light-progressing slit is provided in a part of the glass cover corresponding to the upper part of the conductive water droplet to provide a space through which the reflected light travels, and the light-progressing slit is manufactured in a shape in which a transparent film or a part thereof is opened. The method of claim 7,
On the surface of the glass cover, a recording electrode for measuring a nerve signal generated after the light propagating through the light advancing slit stimulates a target neuron is disposed around each light advancing slit. The method of claim 1,
A distance between the light generated from the light source unit and the optical path substrate is set to a value between a height of a conductive droplet when an electric field is applied to the conductive droplet and a height of a conductive droplet when an electric field is not applied. The method of claim 1,
An optical stimulator for reflecting light generated from the light source by maintaining an initial shape when the conductive water droplets decrease in height due to a spreading phenomenon as an electric field is applied to pass light generated from the light source unit, and maintain an initial shape when an electric field is not applied. As a device for obtaining nerve signals by stimulating specific nerve cells in the body,
A body portion including an electrode and provided with a plurality of electrical terminals connected to the electrode;
An optical path substrate extending from one side of the main body and on which a plurality of conductive water droplets for driving electrowetting are spaced apart from each other by a predetermined distance; And
It is disposed on the main body, the light source unit for generating light in a direction in which the conductive water droplets formed on the optical path substrate are arranged; includes,
Each of the electrical terminals is connected to each of the conductive water droplets, and the conductive water droplets pass light through a shape change when an electric field is applied by the electrical terminal, and the initial shape of the conductive water droplets when no electric field is applied. An optical stimulator for stimulating specific nerve cells by refracting the light proceeding by maintaining it to the lower portion of the conductive water droplet. The method of claim 11,
An optical stimulator including a seating portion on which the conductive water droplets are seated on an upper surface of the optical path substrate, and the seating portion including an inclined surface whose diameter decreases in a depth direction. The method of claim 12,
An optical stimulator provided on an upper surface of the seating portion is an active electrode that surrounds the conductive water droplets and applies an electric field to the conductive water droplets. The method of claim 13,
An optical stimulator in which an insulating layer is formed along the inclined surface while covering the active electrode on an upper surface of the seating part. The method of claim 11,
A ground electrode is provided at the center of the conductive water droplet on the optical path substrate, and the ground electrode is formed of a transparent film to allow the refracted light to proceed. The method of claim 11,
An optical stimulator extending in the longitudinal direction of the optical path substrate and provided with a light advancing guard formed on a side surface of the conductive droplet and a glass cover covering an upper portion of the conductive droplet to block optical interference from the outside. The method of claim 11,
The distance between the light generated from the light source unit and the optical path substrate is set to a value between the height of the water droplet when the electric field is applied to the conductive water droplet and the height of the water droplet when the electric field is not applied. The method of claim 12,
The conductive water droplets descend along the inclined surface by a spreading phenomenon as an electric field is applied, their height decreases with respect to the optical path substrate, and the optical stimulator passes light generated from the light source unit.

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