KR100972800B1 - Micro needle apparatus - Google Patents

Abstract

PURPOSE: A micro-needle apparatus is provided to enlarge the pores of the skin, and to enhance the drug delivery efficiency. CONSTITUTION: A micro-needle apparatus includes: a medicine storage(20) storing medicines; a medicine passage connected to the medicine storage; a micro-needle head(30) which is equipped with a plurality of micro-needles transporting drug of the medicine passage to the dermal layer of skin by punching the dermal layer of skin when the skin is pressurized, wherein tip-end part of the needle is projected to the outside; a heating portion(50) applying heat to the skin through the micro-needle head; and a drug cut-off unit blocking the medicine passage if the micro-needle head is separated from the skin, otherwise, opening the medicine passage if the micro-needle head contacts the skin.

Description

Micro needle apparatus

The present invention relates to a micro-needle device, and more particularly, to make it easier to introduce drugs into the body when injected into the body through the percutaneous immune active drugs such as therapeutics or vaccines or skin-elastic drugs for skin care. A microneedle device.

Immune active agents or drugs (hereinafter referred to as 'drugs'), such as therapeutic agents or vaccines, are generally introduced into the body by oral or injection administration.

However, in the case of oral administration, many drugs are not directly absorbed into the blood stream or modified by the action of digestive enzymes in the digestive tract and thus do not exhibit full efficacy. Also, drugs such as aspirin can damage the digestive tract.

In the case of injection administration, the drug is injected directly into the bloodstream through the skin or vein, and thus can be introduced into the bloodstream without being modified by digestive enzymes in the digestive tract as in oral administration, but the needle penetrates into the dermal layer of the skin during injection. Or can cause pathogen infection.

In order to alleviate the disadvantages caused by oral or injection, recent studies on transdermal administration methods for administering drugs to the local tissue or systemic circulation through the skin have been actively conducted.

One example of a device using such a transdermal administration method is a microneedle device having a microneedle head provided with a plurality of microneedles. In this microneedle device, the microneedles function to penetrate the epidermal layer physically including the stratum corneum of the skin without causing pain when administering the drug. Thus, such a microneedle device may improve the rate at which the drug supplied through the drug supply portion is delivered to the dermal layer of the skin by penetrating the epidermal layer through the microneedles during drug administration.

However, such a conventional microneedle device does not provide a device that can alleviate the pores of the skin due to low temperature or when the tissue is rigid. Therefore, when the drug is administered at low temperatures or in cold winters, even if the microneedle is used to penetrate the epidermal layer containing the stratum corneum, the drug may not be absorbed well through the epidermal layer of the skin or the drug may be well delivered into the dermal layer of the skin. Will not. As a result, drug administration can be difficult.

In addition, the conventional microneedle device does not provide a device that can control the leakage of the drug supplied to the microneedle through the drug supply unit before or after the drug administration in the micro needle head portion. Therefore, there has been a problem that the drug may leak through the microneedle when the needle device is moved or the microneedle head portion is shaken to use or store the needle device before or after the drug administration.

The present invention has been made in view of the above-mentioned problems in the prior art, and an object of the present invention is to heat the skin during drug administration to expand the pores of the skin or to stimulate the skin with far infrared rays and / or infrared rays. It is to provide a micro-needle device that can improve the drug delivery efficiency.

It is another object of the present invention to provide a microneedle device which can prevent the outflow of the drug through the microneedle before or after the drug administration.

Microneedle device according to an embodiment of the present invention for achieving the above object, the drug storage unit for storing a drug; A microneedle head having a drug passage connected to the drug reservoir and a plurality of microneedles arranged to protrude outward and penetrating the dermal layer of the skin when pressed against the skin so that the drug in the drug passage is delivered to the dermal layer of the skin ; And a heating unit for applying heat to the skin through the microneedle head.

Here, the micro needle head forms a drug distribution space in communication with the drug passage between the fixed body having a drug passage therein, a needle fixing plate for fixing the plurality of microneedles, and the needle fixing plate, and a plurality of micro insides. The needle may include a needle cover having a plurality of needle holes through which the needles protrude outwardly. In this case, each of the needle holes may be formed to have a slightly larger inner diameter than the outer diameter of the microneedles so that the drug in the drug distribution space can be discharged along the microneedles.

The microneedle head may further include a drug blocking portion disposed in the drug passage and opening the drug passage when the micro needle head contacts the skin and blocking the drug passage when the micro needle head is spaced apart from the skin. In this case, the drug blocking unit may include a blocking rod that can move to a first position that opens the drug passage and a second position that blocks the drug passage, and an elastic spring that elastically supports the blocking rod to maintain the blocking rod in the second position. have. In this case, the blocking rod is a pressurizing end projecting outward longer than the tip of the microneedle when the blocking rod is in the second position, a spring seat for supporting the elastic spring between the drug passages, and the blocking rod when the blocking rod is in the second position. It is preferable to include a blocking end for blocking the drug passage.

The heating portion may comprise a heater disposed between the drug reservoir and the micro needlehead. In this case, the heater may be arranged at a predetermined distance from the micro needle head or in contact with the micro needle head.

The heating unit may further include a far infrared ray generating unit coupled to the heater and generating far infrared rays by heat of the heater. In this case, the far infrared ray generating unit may be formed of jade or ceramic.

In addition, the heating unit may further include an infrared generating unit disposed between the heater and the drug storage unit to generate infrared rays. The infrared ray generator may include an LED or a lamp for generating infrared rays.

As described above, the microneedle device according to the present invention is a heater that heats the skin when the drug is administered to expand the pores of the skin, and / or a far infrared generator and / or infrared that stimulates the skin with far infrared rays and / or infrared rays. It is provided with a generation part. Therefore, upon drug administration, the microneedle device of the present invention activates the cells by bringing the skin cells to an excited state by heat applied by the heater and infrared rays generated in the far infrared and / or infrared rays generated in the far infrared generator. And induces blood circulation, heat, aging, wet and thickening, and resonance of the skin. As a result, the drug discharged to the epidermal layer of the skin along the microneedle is passed through the epidermal layer and delivered to the dermal layer through the expanded pores and activated cells, thereby improving drug delivery efficiency.

In addition, the microneedle device according to the present invention includes a drug blocking portion that opens the drug passage when the micro needle head contacts the skin and blocks the drug passage when the micro needle head is spaced apart from the skin. Therefore, the microneedle device of the present invention automatically blocks the drug from flowing out through the microneedles when the microneedle head is separated from the skin before or after drug administration. As a result, the user can freely move the microneedle head to a desired position without having to worry about the drug flowing out of the micro needle head.

1 is a perspective view of a microneedle device according to an embodiment of the present invention,
2 is an exploded perspective view of the microneedle device shown in FIG. 1, and
3 and 4 are sectional views illustrating the operation of the microneedle head of the microneedle device shown in FIG.

Hereinafter, the microneedle device according to the embodiment of the present invention will be described in detail with reference to the accompanying drawings.

First, referring to FIGS. 1 and 2, a microneedle device 1 according to an embodiment of the present invention is schematically illustrated.

The microneedle device 1 is a device for transdermal administration that makes it easier to inject drugs into the body when an immunoactive drug such as a therapeutic agent or a vaccine or a skin elasticity drug for skin beauty is injected into the body through the skin. 10, the drug storage unit 20, the micro needle head 30, and the heating unit 50.

The power supply unit 10 is composed of a cylindrical body 11. The cylinder 11 has a battery space in which batteries or rechargeable batteries can be placed. In this embodiment, for example, two 1.5V batteries are arranged in series in the battery space. In addition, the cylinder 11 is provided with a switch 12 capable of turning on or off a power supply on an outer circumferential surface thereof, and a lower portion thereof is sealed by a cover 13. The cylinder 11 not only serves as a power source 10 for disposing a battery or a rechargeable battery, but also serves as a body that allows a user to hold the microneedle device 1 by hand during drug administration.

The drug storage unit 20 is coupled to the cylinder 11 of the power supply unit 10 on the left side (based on FIGS. 1 and 2) of the power supply unit 10 and includes a drug storage chamber 21 for storing drugs therein. . The drug supply pipe 23 is provided at the outlet side of the drug storage chamber 21. The drug supply pipe 23 extends to the inlet 32 of the fixed body 31 of the microneedle head 30 to be described later, and is sealingly connected to the inlet 32.

The heating unit 50 is disposed between the drug storage unit 20 and the micro needle head 30, in accordance with the present invention by applying heat to the skin when administering the drug through the percutaneous to expand the pores, stimulate the skin skin cells It serves to activate. To this end, the heating unit 50 includes an outer cylinder 51, an inner cylinder 52, and a heater 53 disposed between the outer cylinder 51 and the inner cylinder 52. The outer cylinder 51 is coupled to the left end of the drug storage unit 20 by a screw or the like at the right end and is formed of an insulator capable of blocking heat. The inner cylinder 52 receives and passes the drug supply pipe 23, and is formed of an insulator so as to protect the drug supply pipe 23 from the heat of the heater 53, similarly to the outer cylinder 51. The heater 53 is fixed to the support 54 installed outside the inner cylinder 51 at regular intervals from the micro needle head 30, and heats the micro needle head 30 through the micro needle head 30. Heat your skin. In the present embodiment, the heater 53 is configured by, for example, connecting parallel heating wires 55 such as nichrome wire having a width of 3 mm to generate and maintain heat of 40 to 50 ° C.

Here, the heater 53 is illustrated and described as being indirectly heated to the micro needle head 30 by being fixed at a predetermined distance from the micro needle head 30, but instead, the micro needle head 30 and / or the micro needle. The microneedle 45 of the head 30 may be disposed in direct contact with the microneedle 30 and / or the microneedle 45 to directly heat the skin.

By irradiating the skin with far infrared rays and / or infrared rays to stimulate the skin, it is possible to increase the delivery efficiency of the drug delivered to the dermal layer of the skin by the microneedle 45 of the microneedle head 30 as described below. To this end, the heating unit 50 may further include a far infrared ray generating unit 56 and / or an infrared ray generating unit 57.

The far infrared rays generating unit 56 is disposed in the outer cylinder 51 to face the heaters 53 so as to generate far infrared rays by the heat of the heaters 53. To this end, in the present embodiment, the far infrared ray generating portion 56 is formed of a cylindrical body 58 having an outer diameter smaller than that of the outer cylinder 51 so as to be disposed outside the heater 53 in the left portion of the outer cylinder 51. The cylindrical body 58 may be formed of jade or ceramic.

Optionally, the far infrared ray generating unit 56 may be disposed between the heater 53 and the inner cylinder 52 instead of being disposed outside the heater 54. In this case, the infrared ray generating unit 57 is formed of a cylindrical body (not shown) having an inner diameter larger than the outer diameter of the inner cylinder 52, and the heater 53 is provided on a support (not shown) provided outside the cylindrical body. It is fixed.

The infrared ray generating unit 57 is arranged to generate infrared rays between the heater 53 and the drug storage unit 20. In this embodiment, the infrared ray generating unit 57 is composed of a fixed ring 59 of a circular shape, and, for example, a plurality of infrared LEDs or lamps 60 generating infrared rays having a wavelength in the range of 700 nm to 20 μm. do. The fixing ring 59 has a circular hole 61 into which the inner cylinder 52 is fitted. In order to reflect the far infrared rays and infrared rays generated by the infrared ray generating unit 56 and the infrared lamp 60 and the heat generated by the heater 53 toward the micro needle head 30, the fixing ring 59 is an infrared lamp 60 Reflecting surface may be formed on the surface is installed. In addition, the infrared lamp 60 is arranged at regular intervals around the circular hole 61 of the fixing ring 59.

The heater 53 and the infrared lamp 60 are electrically connected to the power supply unit 10 by wires not shown in the drug storage unit 20.

As such, the far infrared rays generated by the far infrared ray generating unit 56 and the infrared rays generated by the infrared ray generating unit 57 cause the skin cells to reach an excited state when they are split into the skin, thereby activating the cells, and accumulated in the body due to environmental pollution. It removes free radicals, induces double bonds of unsaturated fatty acids, enhances cosmetic effects, and normalizes tissues acidified by inflammation, etc., by activating skin circulation, heat, aging, wetness, thickening, and resonance. Can be derived.

As shown in FIGS. 3 and 4, the microneedle head 30 physically penetrates the epidermal layer including the stratum corneum of the skin 80 without causing pain when administering the drug through the percutaneous skin so that the drug is applied to the skin 80. In order to improve the speed of diffusion through, the fixing body 31, the drug blocking part 33, the needle fixing plate 39, and includes a needle cover 42.

The fixed body 31 has an inlet 32 coupled to the drug supply pipe 23 at the upper portion (based on FIGS. 3 and 4), and the drug communicating with the drug supply pipe 23 of the drug storage unit 20 therein. A passage 48 is formed. The drug passage 48 is formed in the form of an angular vial and includes an upper passage 49, a lower passage 63, and an intermediate passage 64 connecting the upper passage 49 and the lower passage 63. In the lower portion of the upper passage 49, a truncated cone-shaped blocking sheet 49a is formed to be coupled to the blocking end portion 34c of the blocking rod 34 to be described later to block the drug passage 48, and the lower passage 63 The upper portion is formed with a first spring sheet 63a to which a substantial portion of the elastic spring 62 to be described later is installed.

As shown in FIG. 4, when the microneedle head 30 contacts the skin 80, the drug passage 48 is opened and as shown in FIG. 3, the micro needle head 30 is spaced apart from the skin 80. In order to block the drug passage 48 when the drug passage 48, the drug blocking portion 33 is disposed.

The drug blocking unit 33 has a blocking rod 34 that can move to a first position (FIG. 4) to open the drug passage 48 and a second position (FIG. 3) to block the drug passage 48. The blocking rod 34 includes a pressing end 34a, a second spring sheet 34b, and a blocking end 34c. The pressing end 34a protrudes out of the needle cover 42 longer than the tip of the microneedle 45 when the blocking rod 34 is in the second position. The second spring sheet 34b supports the lower end of the elastic spring 62 to install the elastic spring 62 between the drug passage 48 and the first spring sheet 63a, and moves the drug therein. A plurality of through openings (not shown) are formed. The blocking end portion 34c is engaged with the blocking sheet 49a of the drug passage 48 when the blocking rod 34 is in the second position to block the drug passage 48 and the blocking sheet 49a of the drug passage 48. It is formed in opposing forms.

In order to hold the blocking rod 34 in the second position, the blocking rod 34 is disposed between the first spring sheet 49a of the upper passage 49 of the drug passage 48 and the second spring sheet 34b of the blocking rod 34. ) Is provided with an elastic spring (62) for elastically supporting. The elastic spring 62 may be composed of a compression spring.

According to this configuration, as shown in Figure 4, when the micro needle head 30 is in contact with the skin 80, the blocking rod 34 is the pressing end (34a) by the skin 80 elastic spring ( It is pushed upward against the elastic force of 62 to move to the first position, whereby the blocking end 34c is separated from the sealing sheet 49a to open the drug passage 48. On the other hand, as shown in FIG. 3, when the micro needle head 30 is spaced apart from the skin 80, the blocking rod 34 is returned to the second position by the elastic force of the elastic spring 62 and thus blocked. The end 34c contacts the sealing sheet 49a to block the drug passage 48.

The needle fixing plate 39 fixes the upper ends of the plurality of microneedles 45 in an array form. Each of the plurality of microneedles 45 is formed in a non-pore shape, and the drug supplied from the drug passage 48 is formed by penetrating the epidermal layer of the skin 80 when contacted with the skin 80. The lower end portion is disposed to protrude out of the needle cover 42 so as to be transferred to the dermis layer. The length at which the lower end of the microneedles 45 protrudes out of the needle cover 42 is such that the lower end of the microneedles 45 is in contact with the skin 80 when the microneedles 30 contact the skin 80. It is preferably a length such as 200 to 500 μm that penetrates the epidermal layer and promotes penetration of the drug through the epidermal layer while not stimulating the puncturing of the skin 80.

The needle cover 42 is fixed by the fixing screws 44 together with the needle fixing plate 39 to form a drug distribution space 43 in communication with the drug passage 48 between the needle fixing plate 39. 31). A plurality of needle holes 47 are formed in the needle cover 42 so that the microneedles 45 fixed to the needle fixing plate 39 penetrate through each of them. The needle holes 47 are formed to have an inner diameter that is slightly larger than the outer diameter of the microneedle 45.

At this time, the size of the drug distribution space 43 and the needle holes 47 is the size of the drug distribution space when the micro needle head 30 is in contact with the skin 80 when the blocking rod 34 opens the drug passage 48 ( 43 allows the drug of the microneedle 45 and the needle holes 47 to be discharged at a constant speed or a certain amount along the microneedle 45 by capillary action, 30 is spaced from the skin so that the blocking rod 34 blocks the drug passage 48, the drug in the drug dispensing space 43, the microneedle (in the gap between the microneedle 45 and the needle holes 47) It is regulated not to discharge along 45).

The fixed body 31, the drug blocking part 33, the needle fixing plate 39, and the needle cover 42 of the microneedle head 30 are far infrared rays generated by the far infrared ray generating part 56 and the infrared ray generating part 57. In order to pass the infrared rays generated by the to pass to the skin 80, for example, it is formed of a transparent material such as polymethyl methacrylate (PMMA). In addition, the fixing body 31, the needle fixing plate 39, and the needle cover 42 may be coated with a heat-resistant paint on the side outer peripheral surface for aesthetic appearance.

This micro needle head 30 is kept closed by the needle head cap 81 after the drug administration operation.

In the above, the microneedle device 1 of the present invention has a microneedle 45 is formed in a non-pore shape and the drug movement path is the microneedle 45 through the drug distribution space 43 from the drug passage 48. Although illustrated and described as being configured to be supplied onto the skin 80 through the gap between the microneedle 45 and the needle holes 47 along the), the present invention is not limited thereto. For example, the microneedle device (not shown) of the present invention has a microneedle 45 in the hollow form and the drug path is from the drug passage 48 to the micro within a range not departing from the principles of the present invention. It may be configured to be fed onto the skin 80 along the hollow space of the needle 45.

The operation of the microneedle device 1 according to an embodiment of the present invention configured as described above will be described in detail with reference to FIGS. 1 to 4.

In order to administer the drug through the transdermal, the user first removes the needle head cap 81 from the micro needle head 30 and then switches to operate the heater 53 and the infrared generator 57 of the heating part 50. Turn on (12).

As a result, the far infrared rays generating unit 56 is heated by the heater 53 to generate far infrared rays, and the microneedle head 30 is heated by the heater 53. In addition, the infrared ray generating unit 57 generates infrared rays.

In this state, when the needle cover 42 of the micro needle head 30 is in contact with the skin, the blocking rod 34 is pressed end portion 34a before the needle cover 42 contacts the skin as shown in FIG. ) Is pushed upward by the skin 80 against the elastic force of the elastic spring 62 to move to the first position, whereby the blocking end 34c is separated from the blocking sheet 49a to open the drug passage 48. . As a result, the drug moved from the drug storage chamber 21 of the drug storage unit 20 to the inlet 32 of the fixed body 31 through the drug supply pipe 23 is the drug distribution space ( 43, and then, at a gap between the microneedle 45 and the needle holes 47, the microneedle 45 is discharged at a constant speed or a predetermined amount out of the needle cover 42 along the microneedle 45.

Then, when the needle cover 42 of the micro needle head 30 is in full contact with the skin, the micro needles 45 protruding outward through the needle holes 47 of the needle cover 42 cause pain. Without going through the epidermal layer of the skin (80). In addition, at this time, the microneedle head 30 heated by the heater 53 temporarily heats the skin 80 to expand the contracted pores, and the far-infrared rays generated by the far-infrared generator 56 The infrared rays generated by the infrared ray generating unit 57 pass through the microneedle head 30 formed of the transparent material and are split into the skin 80, thereby activating the cells by bringing the cells of the skin to an excited state. Together, it induces blood circulation, heat, ripening, wet and thickening, and resonance of the skin.

As a result, the drug discharged out of the needle cover 42 passes through the epidermal layer of the skin 80 along the microneedle 45 and is also delivered to the dermal layer through the expanded pores and activated cells.

Thereafter, in order to inject the drug into the adjacent portion of the skin 80 to which the drug is administered, as shown in FIG. 3, when the user separates the micro needle head 30 from the skin 80, the blocking rod 34 is The elastic spring 62 is returned to its second position by the elastic force, and thus the blocking end 34c meshes with the blocking sheet 49a to block the drug passage 48.

Thus, the user moves the microneedle head 30 to the desired skin 80 area without having to worry about the drug flowing from the micro needle head 30, and repeats the operation as described above.

In the above, the present invention has been described and illustrated in connection with embodiments for illustrating the principle, but the present invention is not limited to the configuration and operation shown and described as such. In addition, it will be understood by those skilled in the art that various changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims. Accordingly, all suitable changes, modifications, and equivalents to the present invention should be considered to be within the scope of the present invention.

1: Micro Needle Device 20: Drug Storage
30: micro needle head 31: fixed body
33: drug block 34: blocking rod
39: needle fixing plate 42: needle cover
43: drug distribution space 45: micro needle
47: needle hole 48: drug passage
50: heating part 53: heater
56: far infrared ray generating unit 57: infrared ray generating unit

Claims (12)

A drug storage unit storing a drug;
A plurality of microneedles disposed in the drug passage connected to the drug storage portion and the tip portion to protrude outwards and penetrating the dermal layer of the skin when pressed against the skin so that the drugs in the drug passage are delivered to the dermal layer of the skin; Micro needle head having; And
It includes a heating unit for applying heat to the skin through the micro needle head,
The micro needle head is disposed in the drug passage, the drug blocking portion for opening the drug passage when the micro needle head is in contact with the skin and blocking the drug passage when the micro needle head is spaced apart from the skin Micro-needle device further comprising. The method of claim 1,
The micro needle head,
A fixed body forming the drug passage therein;
A needle fixing plate for fixing the plurality of microneedles; And
And a needle cover forming a drug dispensing space communicating with the drug passage between the needle fixing plate and a plurality of needle holes formed therein, through which the plurality of microneedles respectively protrude outwardly. Needle device. The method of claim 2,
And each of the needle holes is formed to have a smaller inner diameter than the outer diameter of the microneedles so that the drug in the drug dispensing space can be discharged along the microneedles. delete The method of claim 1,
The drug blocking unit,
A blocking rod movable to a first position to open the drug passage and a second position to block the drug passage; And
And an elastic spring for elastically supporting the blocking rod to maintain the blocking rod in the second position. The method of claim 5,
The blocking rod,
A pressing end projecting outwardly longer than the leading ends of the microneedle when the blocking rod is in the second position;
A spring sheet for supporting the elastic spring between the drug passage; And
And a blocking end for blocking the drug passage when the blocking rod is in the second position. The method of claim 1,
And the heating part comprises a heater disposed between the drug reservoir and the micro needle head. The method of claim 7, wherein
And the heater is disposed at a position spaced apart from the micro needle head at a predetermined distance and in contact with the micro needle head. The method of claim 7, wherein
The heating unit, the microneedle device further comprises a far infrared ray generating unit coupled to the heater to generate far infrared rays by the heat of the heater. 10. The method of claim 9,
The far-infrared generating unit is a microneedle device, characterized in that formed in one of jade and ceramic. The method of claim 7, wherein
The heating unit is disposed between the heater and the drug storage unit, the micro-needle device further comprises an infrared generating unit for generating infrared light. The method of claim 11,
The infrared generating unit microneedle device, characterized in that it comprises one or more of the LED and the lamp for generating infrared light.

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