KR102532905B1 - Micro needle patch - Google Patents

Abstract

A microneedle patch according to an embodiment includes a main body having at least one opening; It is located in the opening and includes a microneedle body in which at least one microneedle is formed, wherein the microneedle body is configured to administer a drug located in the microneedle to the user's skin when an external force in a first direction is applied. move in one direction

Description

Micro needle patch {Micro needle patch}

An embodiment relates to a microneedle patch.

Drug injection using a conventional syringe has problems such as requiring expert injection and accompanying pain. To solve this problem, a microneedle type drug injection system has been developed.

The microneedle is a system that delivers active ingredients into the skin through the stratum corneum, which is the skin barrier layer. Many technological advances have been made in recent years with new systems that combine the efficacy of conventional syringes with the convenience of patches.
Examples of prior art for conventional microneedles are disclosed in, for example, Japanese Patent Publication No. 6193409 (2017.09.06.) and Korean Laid-Open Patent Publication No. 10-2010-0064669 (2010.06.15.) .

However, in the case of the patch-type microneedles, since the user has to directly attach the microneedles to the skin and inject the drug, there is still a problem in that the user's active attachment action is required.

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The embodiment provides a microneedle patch that can be used in a replaceable cartridge and used multiple times in combination with a wearable device.

A microneedle patch according to an embodiment includes a main body having at least one opening; It is located in the opening and includes a microneedle body in which at least one microneedle is formed, wherein the microneedle body is configured to administer a drug located in the microneedle to the user's skin when an external force in a first direction is applied. move in one direction

The microneedle patch according to the embodiment moves when an external force is applied, administers the drug, moves back to the original position, can be used multiple times by rotation, and is configured in a form that can be used in combination with a wearable device, which is convenient for users. It has the effect of injecting the drug in the form.

1 is a top three-dimensional view of a microneedle patch according to a first embodiment.
2 is a bottom stereoscopic view of the microneedle patch according to the first embodiment.
3 is a cross-sectional view of the microneedle patch according to the first embodiment.
4 is a bottom view of the microneedle patch according to the first embodiment.
5 is a bottom perspective view illustrating a patch assembly according to a second embodiment.
6 is a top view illustrating a microneedle patch according to a third embodiment.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. However, the spirit of the present invention is not limited to the presented embodiments, and those skilled in the art who understand the spirit of the present invention may add, change, delete, etc. other elements within the scope of the same spirit, through other degenerative inventions or the present invention. Other embodiments included within the scope of the inventive idea can be easily proposed, but it will also be said to be included within the scope of the inventive concept.

In addition, components having the same function within the scope of the same idea appearing in the drawings of each embodiment are described using the same reference numerals.

A microneedle patch according to an embodiment includes a main body having at least one opening; It is located in the opening and includes a microneedle body in which at least one microneedle is formed, wherein the microneedle body is configured to administer a drug located in the microneedle to the user's skin when an external force in a first direction is applied. move in one direction

The microneedle body further includes a connection portion connecting the microneedle body and the main body, and when an external force in the first direction is applied to the microneedle body located at a first position, the microneedle body is elastically deformed by the connection portion. After moving to the second position, the microneedle body moved to the second position may move in a second direction opposite to the first direction.

The microneedle body that has moved to the second position may move in the second direction to the first position again.

Hereinafter, a microneedle patch according to an embodiment will be described with reference to the drawings.

1 is an upper stereoscopic view of the microneedle patch according to the first embodiment, FIG. 2 is a lower stereoscopic view of the microneedle patch according to the first embodiment, and FIG. 3 is a cross-sectional view of the microneedle patch according to the first embodiment. 4 is a bottom view of the microneedle patch according to the first embodiment.

1 to 4, the microneedle patch 100 according to the first embodiment includes a main body 110, an opening 120, a shaft connecting portion 130, an auxiliary region 140, and a microneedle structure 150. can include

The microneedle patch 100 according to the first embodiment may be inserted into a watch-shaped wearable device. When the microneedle patch 100 is inserted into a wearable device, the microneedle patch 100 may be operated by combining with a driving structure implemented in the wearable device. For example, the microneedle patch 100 may be rotated by a wearable device, and a portion of the microneedle patch 100 may be moved in a first direction by being pressed by a driving structure of the microneedle patch 100 .

In addition, the microneedle patch 100 may be fixed to a wearable device, and a driving structure of the micropatch 100 may be rotated and pressed to move a portion of the micropatch 100 in a first direction.

The microneedle patch 100 may have a replaceable structure. When the microneedle patch 100 has a replaceable structure, the microneedle patch 100 may be combined with other hardware structures to form a cartridge assembly. In this case, the microneedle patch 100 may be mounted on the cartridge assembly and inserted into the wearable device. The cartridge assembly may be replaced according to completion of injection of the drug attached to the microneedle patch 100 or other needs.

The main body 110 may serve as a framework for the microneedle patch 100 . The body 110 may have a plate shape. The main body 110 may have a circular plate shape. That is, the main body 110 may have a thin disc shape.

A plurality of openings 120 and shaft connection parts 130 may be formed in the main body 110 . The plurality of openings 120 may be formed penetrating the main body 110 . The plurality of openings 120 may be arranged in a fan shape based on the center of the main body 110 . The plurality of openings 120 may be positioned at regular intervals from adjacent openings 120 . Alternatively, although not shown, the plurality of openings 120 may be arranged in various shapes such as a circle.

The opening 120 may have a different area depending on the distance from the center of the main body 110 . For example, an area of an area of the opening 120 adjacent to the center of the main body 110 may be smaller than an area of an area spaced apart from the center 110 of the main body. The opening 120 may be formed to have a larger area as the distance from the center of the main body 110 increases.

The shaft connecting portion 130 may be formed penetrating the body 110 . The shaft connecting portion 130 may be formed at the center of the main body 110 . The shaft connecting portion 130 may be formed in a circular shape based on the center of the main body 110 . That is, the center of the shaft connecting portion 130 may be the same as the center of the main body 110 . An outer diameter of the shaft connecting portion 130 may be smaller than an outer diameter of the main body 110 . The plurality of openings 120 may be formed between the outer diameter of the shaft connecting portion 130 and the outer diameter of the main body 110 .

An external structure for fixing or rotating the microneedle patch 100 may be inserted into the shaft connecting portion 130 . The external structure may be a partial structure of the wearable device or a partial structure of the cartridge assembly. The external structure may rotate the microneedle patch 100 by the operating structure of the wearable device. Alternatively, the microneedle patch 100 may be fixed to a wearable device by a structure coupled to the main body 110 .

An auxiliary area 140 may be formed in the main body 110 . The auxiliary area 140 may be an area in which the opening 120 is not formed. The auxiliary area 140 may be a non-opened area of the main body 110 . The plurality of openings 120 are positioned at regular intervals. The opening 120 may not be formed in an area where one opening 120 can be located, and the area where the opening 120 is not formed may be assisted. Area 140 can be defined. The auxiliary area 140 may function as a door to block the cartridge assembly from the outside when the wearable device is in a standby state rather than a drug injection state. The auxiliary area 140 may serve to block the internal structure of the wearable device from the outside in the standby state. The internal structure of the cartridge assembly and the wearable device may be protected from external moisture or foreign substances by the auxiliary area 140 .

The microneedle structure 150 may be located in the opening 120 . The microneedle structure 150 may move when an external force is applied. When an external force is applied, the microneedle structure 150 moves in the same direction as the external force, and then returns to its original position. The microneedle structure 150 may move in the same direction as the external force when an external force is applied, and return to its original position when the external force is released.

For example, when an external force is applied in a first direction while the microneedle structure 150 is located at the first position, it moves in the first direction to the second position, and then moves in the opposite direction to the first direction. It may move in the second direction and return to the first position. The microneedle structure 150 moved to the second position may move in the second direction and return to the first position when the external force is released. The first position may be an initial position of the microneedle structure 150 .

Since the microneedle structure 150 has an elastic structure, it can move in a first direction by an external force and move in a second direction when the external force is released.

The external force may be applied to the microneedle structure 150 by the operating structure of the wearable device. Alternatively, the external force may be applied to the microneedle structure 150 by the operating structure of the cartridge assembly. The external force may be transmitted to the microneedle structure 150 by a power source located inside the wearable device.

The microneedle structure 150 may include a microneedle body 151 and a connection part 155 .

The microneedle body 151 may be formed in a plate shape having both sides.

The microneedle body 151 may include a plurality of microneedles 153 . The plurality of microneedles 153 may be formed on one surface of the microneedle body 151 . The plurality of microneedles 153 may protrude from the microneedle body 150 in a first direction.

The plurality of microneedles 153 may serve to deliver drugs to the user's skin. The plurality of microneedles 153 may be composed of at least one type of a coating type, a hollow type, a dissolving type, and a swelling type.

When the microneedle 153 is a coating type, the drug is applied to the outside of the microneedle 153, and when the microneedle is injected into the user's skin, the drug applied to the microneedle 153 can be delivered to the user's skin. there is.

When the microneedle 153 is hollow, a hollow is formed in the microneedle 153, and when the microneedle is injected into the user's skin, the drug injected into the hollow can be delivered to the user's skin.

When the microneedle 153 is a dissolving type, the microneedle 153 itself is formed of a drug, and when the microneedle is injected into the user's skin, the microneedle 153 itself is delivered to the user, and then the user's skin The microneedles are dissolved in the drug can be delivered to the user's skin.

When the microneedle 153 is a swelling type, a swelling material containing a drug is coated on the outside of the microneedle 153, and when the microneedle is injected into the user's skin, the coated material is swollen so that the drug is applied to the user's skin. It can be structurally coupled to and delivered to the user.

An external force may be applied to the other surface of the microneedle body 151 . When an external force is applied to the other surface of the microneedle body 151 in the first direction, the plurality of microneedles 153 formed on one surface of the microneedle body 151 move in the direction of the user's skin to apply the drug to the user's skin. can deliver.

The connection part 155 may connect the microneedle body 151 and the main body 110 . The connecting portion 155 may be formed in a structure having elasticity. The connecting portion 155 may be formed in a structure capable of being elastically deformed. Elastic deformation at this time may be temporary deformation.

When an external force is applied to the microneedle body 151 in the first direction, the connection part 155 is elastically deformed, so that the microneedle body 151 maintains a connection with the main body 110. (151) can be moved in the first direction. In addition, when the external force is released, the microneedle body 151 may be moved in the second direction by the elasticity of the connection part 155 .

Due to the elasticity of the connection part 155, the plurality of microneedle bodies 151 included in the microneedle patch 100 rotate and deliver the drug to the skin one at a time. As a result, the microneedle patch 100 has an effect of performing drug delivery multiple times.

The connection part 155 may include a first connection part 157 and a second connection part 159 .

The first connection part 157 may be located in an area adjacent to the shaft connection part 130 . The second connection part 159 may be located in an area spaced apart from the shaft connection part 130 . The first connection part 157 may be located in an area adjacent to the center of the main body 110 , and the second connection part 159 may be located in an area adjacent to the outer diameter of the main body 110 .

The first connection part 157 may connect one side of the microneedle body 151 and the body 110, and the second connection part 159 may connect the other side of the microneedle body 151 and the body 110. ) can be connected.

The first connection part 157 and the second connection part 159 may be formed in a curved structure. The first connection portion 157 and the second connection portion 159 may have elasticity by being formed in a curved structure. The first connection part 157 and the second connection part 159 may be designed to have structures having different elasticity. The first connection part 157 and the second connection part 159 may be formed in a structure having elasticity to move in the first direction when an external force is applied to the microneedle body 151 in the first direction. there is. That is, the first connection part 157 and the second connection part 159 have elasticity to move to the second position in a state parallel to the upper surface of the main body 110 when an external force is applied in the first direction. can be designed as

The first connection part 157 and the second connection part 159 may be formed in a spring structure.

The first connection part 157 and the second connection part 159 may each have a curved structure having a width and a pitch. The first connection part 157 may be formed in a structure having a different width and pitch from the second connection part 159 .

The first connection part 157 may have a first width w1 and a first pitch p1. The first width w1 is defined as the distance between the first connection part 157 area that is most farthest from the base of an imaginary line connecting the center of the microneedle body 151 and the center of the body 110. It can be. The first pitch p1 may be defined as an interval between adjacent regions within the first connection part 157 . That is, the first pitch p1 is the distance between adjacent regions within the first connection part 157 based on a virtual line connecting the center of the microneedle body 151 and the center of the body 110. It can be defined as a minimum distance.

The second connection portion 159 may have a second width w2 and a second pitch p2. The second width w2 and the second pitch p2 may also be defined to correspond to the first width w1 and the first pitch w2 of the first connection part 157 .

The first width w1 may be smaller than the second width w2. The first pitch p1 may be greater than or equal to the second pitch p2.

Alternatively, the first connection part 157 and the second connection part 159 may have a curved section and a straight section. In this case, the width of the first connecting portion 157 and the second connecting portion 159 may be defined as a distance between a straight line connecting the inflection points of one curved section and a straight line connecting the inflection points of the other curved section. In addition, the pitch of the first connection part 157 and the second connection part 159 may be defined as a distance between the straight sections.

The microneedle body 151, the first connection part 157, and the second connection part 159 may be integrally formed. The microneedle body 151, the first connection part 157, and the second connection part 159 may have the same thickness. Alternatively, although not shown, the thickness of the microneedle body 151 may be larger or smaller than the thicknesses of the first connection part 157 and the second connection part 159 .

The body 110 and the microneedle structure 150 may be integrally formed. In addition, the body 110, the microneedle structure 150, and the microneedle 153 may be integrally formed.

A protective film 160 may be formed on at least one surface of the main body 110 . The protective layer 160 may serve to protect the microneedles 151 from the outside.

The passivation layer 160 may include an upper passivation layer 161 and a lower passivation layer 163 . The upper protective layer 161 may be formed on an upper surface of the main body 110 and the lower protective layer 163 may be formed on a lower surface of the main body 110 .

The protective layer 160 may be formed of a material containing metal. The protective layer 160 may be formed of aluminum. Alternatively, the protective layer 160 may be formed of plastic.

The protective film 160 is damaged by the microneedle 151 when the microneedle structure 150 is pressed by an external structure, so that the microneedle 151 can deliver the drug to the user's skin.

Alternatively, the protective film 160 may be applied to a region corresponding to a specific microneedle structure 150 immediately before being pressed by an external structure when drug injection from a specific microneedle structure 150 among a plurality of microneedle structures 150 is scheduled. The protective film 160 may be damaged or removed in advance so that the drug injection by the microneedle 151 can be performed more smoothly. In this case, a portion of the protective film 160 may be damaged, moved, or removed through a structure of the cartridge assembly or a wearable device.

5 is a bottom perspective view illustrating a patch assembly according to a second embodiment.

The patch assembly according to the second embodiment is provided in a form in which a microneedle patch is mounted on a patch carrier without a separate cartridge housing. Therefore, in the description of the patch assembly according to the second embodiment, the same reference numerals are given to the same reference numerals as those of the first embodiment, and detailed descriptions thereof are omitted.

Referring to FIG. 5 , the patch assembly according to the second embodiment includes a microneedle patch 100 and a patch carrier 200.

The microneedle patch 100 may be mounted on the patch carrier 200 . The microneedle patch 100 may be rotatably mounted on the patch carrier 200 .

The microneedle patch 100 may include a main body 110 , a plurality of openings 120 , shaft connection parts 130 , an auxiliary region 140 and a microneedle structure 150 .

The patch carrier 200 may include a carrier body 210 and a coupling structure 220 .

The carrier body 210 constitutes a frame of the patch carrier 200 . A seating portion is formed on the carrier body 210, and the microneedle patch 100 can be rotatably mounted on the seating portion.

A coupling structure 220 may be formed in a portion of the carrier body 210 . The coupling structure 220 may have a shape protruding outward. The coupling structure 220 may serve to fix the patch carrier 200 to the wearable device when the patch carrier 200 is mounted on the wearable device.

A through hole 230 may be formed in the patch assembly. The through hole 230 may serve as a path through which a power transmission structure among internal structures of the wearable device moves from the outside of the patch assembly to the shaft connection part 130 . That is, when the patch assembly is inserted into the wearable device, the through hole 230 allows the power transmission structure to be located at the shaft connecting portion 130 to move to the shaft connecting portion 130 when the mounting is completed without structural interference It may be a moving route for

The through hole 230 may include a patch through hole 170 and a carrier through hole 240 . The patch through hole 170 may be formed to extend from the shaft connecting portion 130 to an outer diameter of the main body 110 . The patch through hole 170 may be formed in the auxiliary area 140 .

The carrier through hole 240 may be formed to pass through the seating portion and the carrier body 210 . The patch through hole 170 and the carrier through hole 240 may be formed in corresponding regions.

The patch assembly according to the second embodiment is provided in a form in which a microneedle patch is mounted on a patch carrier without a separate cartridge housing, so that it can be implemented with a simple structure, thereby reducing manufacturing cost. In addition, since the patch assembly has the through hole 230, the power transmission structure of the wearable device can be positioned as the shaft connection part 130 without structural interference, so that a separate moving mechanism can be omitted.

6 is a top view illustrating a microneedle patch according to a third embodiment.

Compared to the first embodiment, the microneedle patch according to the third embodiment has a different connection part, a microneedle body shape, and a corresponding body shape, but the rest of the configuration is the same. Therefore, in describing the third embodiment, the same reference numerals are assigned to components common to those of the first embodiment, and detailed descriptions thereof are omitted.

Referring to FIG. 6 , the microneedle patch 300 according to the third embodiment may include a main body 310, a shaft connector 330, and a microneedle structure 350.

The body 310 may include a first body 311 and a second body 313 . The first body 311 and the second body 313 may have a circular band shape. The first body 311 and the second body 313 may have a circular band shape having the same center. The first body 311 and the second body 313 may have different radii. The first body 311 may have a smaller radius than the second body 313 . The second body 313 may be formed surrounding the first body 311 . The first body 311 and the second body 313 may be formed to be spaced apart from each other. The first body 311 and the second body 313 may be spaced apart from each other to form an opening.

The microneedle structure 350 may be located in an opening between the first body 311 and the second body 313 . At least one microneedle structure 350 may be positioned in the opening.

The microneedle structure 350 may be connected to the first body 311 and the second body 313 .

The microneedle structure 350 may include a microneedle body 351 , a connecting portion 355 and an annular connecting portion 356 .

Microneedles may be formed in the microneedle body 351 .

The microneedle body 351 may be formed in a fan shape. In the drawing, the microneedle body 351 is illustrated and described as having a fan shape, but is not limited thereto.

Widths of one end and the other end of the microneedle body 351 may be different. One end of the microneedle body 351 may be adjacent to the first body 311 , and the other end of the microneedle body 351 may be adjacent to the second body 313 . A width of one end of the microneedle body 351 may be smaller than a width of the other end.

The microneedle body 351 may be connected to the main body 310 through the connection part 355 . The connection part 355 may be arranged toward the center of the circle.

The connection part 355 may include a first connection part 357 and a second connection part 359 .

The first connection part 357 may be located between the microneedle body 351 and the first body 311 . The first connection part 357 may connect the first body 311 and the microneedle body 351 . The first connection portion 357 may have a first width W1 and a first thickness T1.

The second connection part 359 may be located between the microneedle body 351 and the second body 313 . The second connection part 359 may connect the second body 313 and the microneedle body 351 . The second connection portion 359 may have a second width W2 and a second thickness T2.

The first width W1 may be different from the second width W2 , and the first thickness T1 may be different from the second thickness T2 .

The annular connection part 356 may connect adjacent microneedle bodies 351 to each other. The annular connection part 356 may connect adjacent side surfaces of the microneedle body 351 . The annular connection part 356 may be formed in a shape corresponding to that of the main body 310 . A plurality of annular connection portions 356 may be formed spaced apart from each other along a circular band shape. The annular connection part 356 may be disposed along a circle having the same center as the first body 311 .

The connection part 355 and the annular connection part 356 may be physically connected while being formed separately from the microneedle body 351, and at least one of the connection part 355 and the annular connection part 356 may be connected to the microneedle body ( 351) and integrally formed.

The connecting portion 355 and the annular connecting portion 356 may have elasticity. The connection part 355 may have elasticity toward the center of the main body 310 . The annular connecting portion 356 has the same center as the main body 310 and may have elasticity in a circumferential direction of a circle where the annular connecting portion 356 is located.

Since the connection part 355 and the annular connection part 356 have elasticity, when an external force is applied to the microneedle body 351 in the first direction, the microneedle body 351 moves to the second position in a state parallel to the top surface of the body 310. can make it move. In addition, after the microneedle body 351 is moved to the second position, it may be moved to the first position again.

In the above, the configuration and characteristics of the present invention have been described based on the embodiments according to the present invention, but the present invention is not limited thereto, and various changes or modifications can be made within the spirit and scope of the present invention. It is apparent to those skilled in the art, and therefore such changes or modifications are intended to fall within the scope of the appended claims.

Claims (3)

A main body having a plurality of openings;
a microneedle body positioned in the opening and having at least one microneedle formed thereon; and
A connection part connecting the microneedle body and the main body, wherein the connection part includes a first connection part and a second connection part;
The first connection part connects one side of the microneedle body and the main body, and the second connection part connects the other side of the microneedle body and the main body;
The first connection part and the second connection part are formed in spring structures having different widths and pitches,
The microneedle body located in the first position is located in the second position in the first direction to administer the drug located in the microneedle to the user's skin by elastic deformation of the connection part when an external force in the first direction is applied. go to,
The microneedle body moved to the second position moves in a second direction opposite to the first direction.
According to claim 1,
The main body includes an auxiliary region in which the opening is not formed,
Wherein the secondary region blocks an internal structure of the wearable device from the outside when the wearable device is in a standby state.
According to claim 2,
The microneedle body administers a drug to the user's skin in the first direction through an opening of the wearable device,
The microneedle patch is rotated so that the microneedle body can correspond to the opening of the wearable device.

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