KR102225891B1 - System for injecting drug of micro needle patch - Google Patents

Abstract

The present invention discloses a microneedle patch drug injection system. The present invention can selectively control the injection timing of the microneedle patch using an illumination device and a quantum dot filter.

Description

Drug injection system of micro needle patch {SYSTEM FOR INJECTING DRUG OF MICRO NEEDLE PATCH}

The present invention relates to a microneedle drug injection system, and more particularly, to a drug injection system of a microneedle patch capable of selectively controlling a drug injection timing of a microneedle patch using an illumination device and a quantum dot filter.

As a method for effective drug delivery of drugs applied to the human body, a method of injecting drugs in liquid form through a hypodermic injection needle has been widely applied.

However, a hypodermic injection needle having a diameter of about several mm can cause pain to a patient by stimulating a number of pain points existing in the skin, and there is a problem that requires a high level of skill for use thereof.

Recently, in order to overcome the above disadvantages of a hypodermic injection needle, a method for transdermal drug delivery using a microneedle device having a diameter and height of only tens or hundreds of µm has been actively studied.

1 is an exemplary diagram showing a drug delivery process using a general microneedle, wherein the microneedle patch 10 is made by using a plurality of microneedles piercing the stratum corneum layer of the skin, which is the main barrier layer for transdermal drug delivery. It forms a number of channels through the skin at once.

Through the channels, a sufficient amount of the drug can reach the epidermis layer 20 or the dermis layer 30, and then the drug is absorbed through blood vessels and lymph nodes and injected into the circulatory system of the human body.

However, in the transdermal drug delivery patch, the drug contained in the patch is generally delivered to the body through diffusion, and the diffusion rate decreases due to the stratum corneum present in the outermost part of the skin, and thus shows a relatively low drug permeability.

In addition, since it is delivered through multiple skin layers, it is difficult to immediately administer the drug according to the needs of the patient, and while wearing the microneedle patch, the drug is continuously injected, so that the drug cannot be controlled to be selectively injected at a specific time. have.

Korean Registered Patent Publication No. 10-1030752 (Name of invention: microneedle unit that can control fluid delivery)

In order to solve this problem, an object of the present invention is to provide a drug injection system of a microneedle patch capable of selectively controlling a drug injection timing of a microneedle patch using an illumination device and a quantum dot filter.

In order to achieve the above object, the present invention is a drug injection system of microneedle patching, which is attached to the skin and is turned on when light of a predetermined specific wavelength is incident, so that the internal drug is injected into the skin. A drug injection unit that operates; And an illumination unit that irradiates light of a specific wavelength to the drug injection unit.

In addition, the drug injection unit according to the present invention, a quantum dot filter unit for filtering so that light of a predetermined specific wavelength is incident; A switching unit for outputting a switching-on signal in response to light passing through the quantum dot filter unit; A controller configured to output an operation control signal to a drug controller when the switching-on signal is input; And a drug control unit operating the microneedle so that the drug is injected into the skin according to the operation control signal of the control unit.

In addition, the quantum dot filter unit according to the present invention is characterized in that it is made of a thin film having a nano-sized semiconductor material.

In addition, the drug control unit according to the present invention comprises a first chamber storing an arbitrary drug; A second chamber connected to the first chamber through a connection pipe and installed with a microneedle so that the drug supplied through the connection pipe is injected into the skin; A first pressurizing unit to pressurize the drug stored in the first chamber to be supplied to the second chamber; A second pressing unit for pressing the microneedles installed in the second chamber to contact the skin; And a microneedle in contact with the skin so that the drug supplied to the second chamber is injected into the skin.

In addition, the drug control unit according to the present invention may further include a check valve installed in the connection pipe to prevent the drug supplied to the second chamber from flowing back to the first chamber.

The present invention has the advantage of selectively controlling the injection timing of the microneedle patch using an illumination device and a quantum dot filter.

In addition, the present invention has the advantage of preventing abuse of drugs by controlling the timing of injection of drugs using light of a specific wavelength.

In addition, the present invention has the advantage of improving the accuracy of optical sensors rather than electrical sensors for IoT commercialization.

1 is an exemplary view showing a drug delivery process using a general microneedle.
Figure 2 is a block diagram showing the configuration of the drug injection system of the microneedle patch according to the present invention.
3 is a cross-sectional view showing the structure of the drug control unit of the drug injection system of the microneedle patch according to the present invention.

Hereinafter, a preferred embodiment of a drug injection system of a microneedle patch according to the present invention will be described in detail with reference to the accompanying drawings.

In the present specification, the expression that a certain part "includes" a certain component does not exclude other components, but means that other components may be further included.

In addition, terms such as "... unit", "... group", and "... module" mean units that process at least one function or operation, which can be classified into hardware, software, or a combination of the two.

Figure 2 is a block diagram showing the configuration of the drug injection system of the microneedle patch according to the present invention, Figure 3 is a cross-sectional view showing the structure of the drug control unit of the drug injection system of the microneedle patch according to the present invention.

As shown in FIGS. 2 to 3, the drug injection system of the microneedle patch according to the present invention includes a drug injection unit 100 and a lighting unit 200.

The drug injection unit 100 is attached to the skin 300 and is turned on when light of a predetermined specific wavelength is incident, so that the internal drug 160 is injected into the skin 300 by the microneedle 150 As a configuration for operating, the quantum dot filter unit 110, the switching unit 120, the control unit 130, the drug control unit 140, and includes a microneedle 150.

In addition, the drug injection unit 100 may be configured to further include a drug to be injected 160.

The quantum dot filter unit 110 is configured to filter so that light of a predetermined specific wavelength is incident, and is made of a thin film including a quantum dot material made of a nano-sized semiconductor material.

Quantum dot material can be configured so that only specific wavelengths can be derived or incident on the wavelength generated by using the phenomenon that is quantized when it is reduced to nano units, and external optical stimulation having a specific wavelength using the characteristics of such quantum dot material Selective operation can be made on the.

The switching unit 120 outputs a switching on signal in response to the light passing through the quantum dot filter unit 110.

When a switching-on signal is input from the switching unit 120, the control unit 130 outputs an operation control signal so that the drug control unit 140 operates.

That is, the controller 130 outputs a motion control signal to be injected into the skin 300 through the microneedle 150 of the drug 160 embedded in the drug controller 140.

The drug control unit 140 operates the microneedle 150 so that the drug 160 is injected into the skin 300 according to an operation control signal of the control unit 130, and includes a first chamber 141, The second chamber 142, the first pressing unit 143, the second pressing unit 144, the connection pipe 145, and a microneedle 150 is configured to be included.

The first chamber 141 is configured to store an arbitrary drug 160 to be injected into the skin 300, and a storage space is formed therein.

In addition, the first chamber 141 may be formed of a flexible material so that the internal drug 160 can move through deformation of an external shape when a pressing force is applied.

The second needle 142 has a storage space formed therein, and is connected to the first chamber 141 through a connection pipe 145.

In addition, a microneedle 150 is installed in the second chamber 142 so that the drug 160 supplied from the first chamber 141 through the connection pipe 145 can be injected into the skin 300.

The first pressing part 143 is installed in the first chamber 141 and the drug 160 stored in the first chamber 141 is supplied to the second chamber 142 through the connection pipe 145. As a configuration to pressurize the first chamber 141, it operates through an operation control signal output from the control unit 130, and preferably consists of an actuator that performs a pumping operation by an electric signal.

The second pressurization part 144 is installed in the second chamber 142, and the microneedles 150 installed in the second chamber 142 contact the skin 300 so that the upper / Controls downward movement.

That is, when the drug 160 supplied from the first chamber 141 is filled in the second chamber 142, the second pressing unit 144 operates through an operation control signal output from the controller 130 The needle 150 is in contact with the skin 300.

At this time, the second pressing unit 144 maintains a pressurized state so that contact between the microneedle 150 and the skin 300 is maintained.

In addition, the second pressing unit 144 operates to separate the microneedle 150 in a state in contact with the skin 300 through an operation control signal output from the control unit 130 after a certain period of time has elapsed.

Meanwhile, the drug control unit 140 is installed in a connection pipe 145 that connects the first chamber 141 and the second chamber 142 to guide the drug 160 to move, 2 The check valve 146 may be configured to prevent the drug supplied to the chamber 142 from flowing back to the first chamber 141 through the connection pipe 145.

That is, the pressure generated by the relaxation of the first chamber 141 or the pressure generated inside the second chamber 142 during the operation of the microneedle 150 causes the supply to the second chamber 142. By preventing the reverse flow of the drug 160, a certain amount of the drug 160 from the first chamber 141 is accurately supplied to the second chamber 142 and can be injected into the skin 300.

The microneedle 150 is installed in the second chamber 142 so as to be movable in the up/down direction, and moves through the operation of the second pressurization unit 144 to contact the skin 300, so that the second chamber The drug 160 supplied to 142 is injected into the skin 300.

In addition, the microneedle 150 is separated from the skin 300 by moving through the operation of the second pressing unit 144.

The lighting unit 200 is installed at an arbitrary position around the drug injection unit 100 and irradiates light of a specific wavelength for the operation of the drug injection unit 100.

In addition, the lighting unit 200 may be installed as a light source that emits a specific wavelength in a lighting device that is installed in a building and emits infrared rays, visible rays, and the like.

In addition, the lighting unit 200 may be connected to a lighting control system that controls the lighting of the building through a network, and is configured to be turned on through a control signal output from the lighting control system at an arbitrary time to irradiate light of a specific wavelength. Can be.

Therefore, it is possible to selectively control the injection timing of the microneedle patch using the lighting device and the quantum dot filter.

As described above, although it has been described with reference to a preferred embodiment of the present invention, those skilled in the art will variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the following claims. You will understand that you can do it.

In addition, reference numerals in the claims of the present invention are provided for clarity and convenience of description, and are not limited thereto. In the process of describing the embodiments, the thickness of the lines shown in the drawings, the size of components, etc. May be exaggerated for clarity and convenience of description, and the above-described terms are terms defined in consideration of functions in the present invention and may vary according to the intentions or customs of users and operators. Should be made based on the contents throughout this specification.

100: drug injection unit
110: quantum dot filter unit
120: switching unit
130: control unit
140: drug control unit
141: first chamber
142: second chamber
143: first pressurization part
144: second pressurization part
145: connector
146: check valve
150: micro needle
160: drug
200: lighting unit
300: skin

Claims (5)

A drug injection unit 100 that is attached to the skin 300 and is turned on when light of a predetermined specific wavelength is incident to operate the microneedle 150 so that the internal drug 160 is injected into the skin 300 ); And
Including a lighting unit 200 for irradiating light of a specific wavelength to the drug injection unit 100,
The drug injection unit 100 includes a quantum dot filter unit 110 for filtering light of a predetermined specific wavelength to be incident;
A switching unit 120 outputting a switching on signal in response to light passing through the quantum dot filter unit 110;
A controller 130 for outputting an operation control signal to the drug controller 140 when the switching-on signal is input; And
Drug of a microneedle patch, characterized in that it comprises a drug controller 140 that operates the microneedle 150 so that the drug 160 is injected into the skin 300 according to the operation control signal of the controller 130 Infusion system.
delete The method of claim 1,
The quantum dot filter unit 110 is a drug injection system of a microneedle patch, characterized in that made of a thin film having a nano-sized semiconductor material.
The method of claim 1,
The drug control unit 140 includes a first chamber 141 storing an arbitrary drug 160;
A second chamber connected to the first chamber 141 through a connection pipe 145 and in which a microneedle 150 is installed so that the drug 160 supplied through the connection pipe 145 is injected into the skin 300 (142);
A first pressing unit 143 for pressing the drug 160 stored in the first chamber 141 to be supplied to the second chamber 142;
A second pressing unit 144 for pressing the microneedle 150 installed in the second chamber 142 to contact the skin 300; And
A drug injection system of a microneedle patch, comprising a microneedle 150 that contacts the skin 300 and allows the drug 160 supplied to the second chamber 142 to be injected into the skin 300 .
The method of claim 4,
The drug control unit 140 further comprises a check valve 146 installed in the connection pipe 145 to prevent the drug supplied to the second chamber 142 from flowing back to the first chamber 141 Microneedle patching of drug injection system.

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