JP5718622B2 - Microneedle array device - Google Patents

Description

  The present invention relates to a microneedle array device used in, for example, transdermal administration of insulin, and in particular, it is possible to easily realize a desired configuration by freely selecting the number and pitch of microneedles, and Further, the present invention relates to a device devised so as to prevent leakage of drug solution and dissolution / denaturation of microneedles before injection (dissolution or change in properties due to microneedle being invaded by drug solution).

For example, Patent Document 1, Patent Document 2, and Patent Document 3 disclose such a microneedle array device.
First, the microneedle disclosed in Patent Document 1 forms an island-shaped etching mask having a thickness distribution on a substrate, and uses the difference in etching rate between the etching mask and the substrate to make the substrate into a needle shape. To be processed.
Next, the microneedle disclosed in Patent Document 2 forms a desired microneedle by etching using a mask.
Furthermore, the fine needle | hook currently disclosed by patent document 3 comprises a needle | hook from a soluble material.

JP 2008-296037 A Special table 2004-538106 gazette JP 2008-279237 A

The conventional configuration has the following problems.
First, according to the conventional configuration, it is difficult to freely configure the number of microneedles, the pitch, and the like to configure a desired microneedle array device.
In addition, a large number of microneedles have to be molded at the same time, which causes a problem in that molding defects occur in the needle portions of the microneedles.
In addition, for example, when a microneedle array device is configured using microneedles made of biocompatible materials such as PLA (Poly Lactic Acid) resin (polylactic acid resin) and PGA (Poly Glycolic Acid) resin (polyglycolic acid resin). It is also assumed that the microneedles may be invaded by touching the drug solution before injection and become unusable due to dissolution / denaturation or the like.

The present invention has been made on the basis of the above points. The object of the present invention is to realize a desired configuration by freely selecting the number and pitch of microneedles, and the occurrence of molding defects. It is an object of the present invention to provide a microneedle array device that does not cause microneedles to be affected by a chemical solution before injection.

Microneedle array device according to claim 1 of the present invention in order to achieve the above object, a case having microneedles protruding opening, a microneedle that protrudes to the outside through the microneedles projecting opening, the And the case includes an opening and a lower case provided with a fluid supply opening, and an upper case provided with the microneedle protruding opening installed so as to close the opening of the lower case. The microneedle is punctured into the skin.
The microneedle array device according to claim 2 is the microneedle array device according to claim 1, wherein the case is provided with a microneedle array, and the microneedle is provided in the microneedle array. It is characterized by being.
A microneedle array device according to claim 3 is the microneedle array device according to claim 2, wherein the microneedle array has a configuration in which a plurality of microneedles are provided in a row. is there.
A microneedle array device according to a fourth aspect is the microneedle array device according to any one of the first to third aspects, wherein the microneedle projecting opening has an outer periphery on the outer periphery of the microneedle projecting opening. A large-diameter concave portion is formed .
A microneedle array device according to claim 5 is the microneedle array device according to any one of claims 2 to 4, wherein a microneedle array receiving recess is provided between the lower case and the upper case. An internal block having a fluid groove having a fluid supply port and a fluid discharge port is installed, and the microneedle array is housed and disposed in the microneedle array housing portion of the internal block, and the lower case and A flow path groove is provided between the inner block and the fluid supplied into the fluid groove via the fluid supply opening of the lower case and the fluid supply port of the inner block. Fluid is supplied to each microneedle through the fluid outlet and the flow channel, and injected through each microneedle. It is characterized in that the.
The microneedle array device according to claim 6 is the microneedle array device according to claim 5, wherein the fluid supply port and the fluid discharge port are selectively opened between the inner block and the lower case. A shutter plate that can be used is provided .
A microneedle array device according to a seventh aspect is the microneedle array device according to the fifth or sixth aspect, wherein the channel groove is provided in the lower case .
A microneedle array device according to an eighth aspect is the microneedle array device according to the fifth or sixth aspect, wherein the flow channel is provided in the inner block .
The microneedle array device according to claim 9 is the microneedle array device according to claim 5 or 6, wherein the channel groove is formed by a through hole provided in the shutter plate. Is.
The microneedle array device according to claim 10 is the microneedle array device according to any one of claims 1 to 9 , wherein the microneedle array is made of a plastic material safe for a living body. It is characterized by.
A microneedle array device according to an eleventh aspect is the microneedle array device according to any one of the fifth to ninth aspects, wherein the inner block is formed of an elastic member, and the inner portion of the lower case. It is characterized in that it is molded slightly larger than the space .

As described above, according to the microneedle array device according to the first aspect of the present invention, the lower case includes the opening and the fluid supply opening, and is installed so as to close the opening of the lower case. An upper case provided with a through-hole, and an internal block provided with a fluid groove having a fluid supply port and a fluid discharge port while being provided and disposed between the lower case and the upper case and having a microneedle array receiving recess; A microneedle array that is housed and arranged in the microneedle array housing recess of the inner block and includes microneedles, and a channel groove provided between the lower case and the inner block, Fluid is supplied into the fluid groove through the fluid supply opening of the lower case and the fluid supply port of the internal block, and the supplied flow is supplied. Is supplied to each microneedle via the fluid outlet and the channel groove and injected subcutaneously via each microneedle. First, the microneedle array device is divided into a plurality of components. This makes it possible to freely select and configure the number of microneedles, the pitch, and the like. In particular, by combining an appropriate number of microneedle arrays, the number of microneedles and the like can be freely selected, and a desired “row × column” microneedle array device can be easily provided. At that time, by appropriately changing the pitch of each microneedle of the microneedle array, not only the number of microneedles but also the pitch can be freely selected and configured.
Further, the microneedle array device according to claim 2 can selectively open the fluid supply port and the fluid discharge port of the fluid groove by the shutter plate, thereby preventing inadvertent leakage of the fluid from the fluid groove. For example, when the fluid filled in the fluid groove is a chemical solution that attacks the microneedle array, the microneedle array is impregnated by the chemical solution and cannot be used before the microneedle array device is used for injection. Can be prevented.
Also, the microneedle array device according to claim 3 can obtain the same effects as the microneedle array device according to claims 1 and 2.
Further, the microneedle array device according to claim 4 can obtain the same effect as the microneedle array device according to claim 1.
Further, the microneedle array device according to claim 5 can obtain the same effect as the microneedle array according to claim 2.
A microneedle array device according to claim 6 is the microneedle array device according to any one of claims 1 to 5, wherein the microneedle array is made of a plastic material safe for a living body. Therefore, the safety of the living body can be surely ensured.
A microneedle array device according to a seventh aspect is the microneedle array device according to any one of the first to sixth aspects, wherein the inner block is formed of an elastic member, and the inner portion of the lower case. Since it is molded slightly larger than the space, high sealing performance can be obtained without using a separate sealing material.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the 1st Embodiment of this invention, and is a perspective view which shows the structure of the whole microneedle array apparatus. It is a figure which shows the 1st Embodiment of this invention, and is II-II sectional drawing of FIG. It is a figure which shows the 1st Embodiment of this invention and is a disassembled perspective view of a microneedle array apparatus. It is a figure which shows the 1st Embodiment of this invention and is a top view for demonstrating the application range of a microneedle array apparatus. It is a figure which shows the 2nd Embodiment of this invention, and is an exploded perspective view of a microneedle array apparatus. It is a figure which shows the 2nd Embodiment of this invention, and is sectional drawing of a microneedle array apparatus. It is a figure which shows the 3rd Embodiment of this invention, and is an exploded perspective view of a microneedle array apparatus. FIGS. 8A and 8B are views showing a third embodiment of the present invention, FIG. 8A is a perspective view showing a microneedle array device in a chemical solution filling state, and FIG. 8B is a microneedle array device in a chemical solution storage state. FIG. 8C is a perspective view showing the microneedle array device in an injection state. FIG. 9A is a cross-sectional view showing a microneedle array device in a chemical solution filling state, and FIG. 9B is a diagram showing a microneedle array device in a chemical solution storage state. FIG. 9C is a cross-sectional view showing the microneedle array device in an injection state. It is a figure which shows the 4th Embodiment of this invention, and is a disassembled perspective view of a microneedle array apparatus. FIG. 11A is a cross-sectional view showing a microneedle array device in a chemical solution filling state, and FIG. 11B is a cross-sectional view showing a microneedle array device in a chemical solution storage state. FIG. 11C is a cross-sectional view showing the microneedle array device in an injection state. It is a figure which shows the 5th Embodiment of this invention, and is an exploded perspective view of a microneedle array apparatus. FIG. 13 (a) is a cross-sectional view showing a microneedle array device in a chemical solution filling state, and FIG. 13 (b) is a diagram showing a microneedle array device in a chemical solution storage state, showing a fifth embodiment of the present invention. FIG. 13C is a cross-sectional view showing the microneedle array device in an injection state.

  Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. As shown in FIGS. 1 to 3, first, there is a lower case 1. The lower case 1 has a bowl shape, and is composed of a bottom wall 3 and four side walls 5, 7, 9, and 11 erected from the bottom wall 3. A plurality (six in the case of this embodiment) of channel grooves 13 are formed in the bottom wall 3. Further, an opening 15 for supplying a chemical solution is formed at the center of the bottom wall 3. Further, an opening 16 is formed in the lower case 1. The lower case 1 is made of plastic or metal. In the case of this embodiment, it is made of plastic.

  An upper case 17 is installed and fixed so as to close the opening 16 of the lower case 1. The upper case 17 is also made of plastic or metal like the lower case 1. In the case of this embodiment, it is made of plastic. Insertion pins 19 project from the lower surfaces of the four corners of the upper case 17. On the other hand, concave portions 21 are formed at the four corners on the lower case 1 side already described. The upper case 17 is bonded and fixed to the lower case 1 via an adhesive film (not shown) with the insertion pins 19 at the four corners inserted into the recesses 21 at the four corners of the lower case 1.

Through hole 2 2 a plurality the above upper case 17 (six in the case of this embodiment) are perforated. Also, large-diameter recess 24 through the through-holes 2 2 is an outer surface on the outer periphery of the through hole 2 2 of the upper case 17 is formed. The recess 24 functions so that a microneedle, which will be described later, can be easily stuck into the skin.

An internal block 23 is housed between the lower case 1 and the upper case 17. The internal block 23 is made of, for example, silicon rubber, and is set slightly larger than the dimension of the internal space of the lower case 1 already described. As a result, it is configured such that it can function as a packing while being housed between the lower case 1 and the upper case 17.
In addition to the silicon rubber, for example, it may be configured from an elastic member such as an elastomer.

A plurality (two in the case of this embodiment) of microneedle array accommodating spaces 25, 25 are formed in the internal block 23. The microneedle array accommodating space 25 is formed in a state where the lower side in FIG. 3 is opened. A plurality (six in the case of this embodiment) of through holes 27 are formed on the upper surface side of the microneedle array housing spaces 25, 25.

  A chemical groove 29 is formed at the center of the internal block 23. As shown in FIG. 2, a chemical solution supply port 31 is formed on the bottom wall of the chemical solution groove 29, and a plurality (six in this embodiment) of chemical solution discharge ports 33 are formed. ing.

In the microneedle array housing spaces 25, 25 of the internal block 23, microneedle arrays 35, 35 are respectively housed. The microneedle array 35 is, for example, a plastic material that is safe for a living body, specifically, PLA (Poly Lactic Acid) resin (polylactic acid resin), PVA (Poly Vinyl Alcohl) resin (polyvinyl alcohol resin), It is comprised from PGA (Poly Glycolic Acid) resin (polyglycolic acid resin) etc. The microneedle array 35 is divided in half in the vertical direction, and has a structure in which two microneedle array elements 37 and 37 are bonded together. Each microneedle array element 37 is provided with three microneedles 39. Further, as shown in FIG. 2, a chemical liquid channel 41 is formed in each microneedle 39. As shown in FIG. 1, a pump 53 is connected to the chemical solution supply opening 15 of the lower case 1 via a tube 51.
The patent applicant has filed a separate patent application for molding and bonding the microneedle array 35 in a vertically divided state.

The operation will be described based on the above configuration.
First, the chemical liquid supplied from the pump 53 via the tube 51 is supplied into the chemical liquid groove 29 via the chemical liquid supply opening 15 and the chemical liquid supply port 31. The chemical solution supplied into the chemical solution groove 29 flows into each flow channel groove 13 via each chemical material discharge port 33 and then flows into the chemical solution flow channel 41 of each microneedle 39. Then, for example, it is injected subcutaneously through the microneedle 39.

As described above, according to the present embodiment, the following effects can be obtained.
First, by dividing the microneedle array device into a plurality of constituent members, the number of microneedles 39, the pitch, and the like can be freely selected and configured. In particular, by combining an appropriate number of columnar microneedle arrays 35, the number of microneedles 39 can be freely selected, and a desired “row × column” microneedle array device can be easily provided. It is something that can be done.
At that time, by appropriately changing the pitch of each microneedle 39 of the microneedle array 35, not only the number of microneedles 39 but also the pitch can be freely selected and configured.
In addition, the structure is made of an elastic member between the lower case 1 and the upper case 17 and sandwiches an internal block 23 slightly larger than the internal space, thereby providing high sealing performance without using a separate sealing material. A microneedle array device can be provided.
In addition, since the microneedle array 35 is divided in half in the vertical direction, it is possible to eliminate molding defects of the microneedle 39 and the like.
The microneedle array 35 is made of a plastic material that is safe for the living body, specifically, a polylactic acid resin, a PVA resin, a PGA resin, or the like. it can.
Further, since the recess 24 is formed in the upper case 17, the insertion of the microneedle 39 into the skin can be ensured.

Next, a second embodiment of the present invention will be described with reference to FIGS.
Note that the upper case 17 and the microneedle array 35 are the same as those in the first embodiment described above, and therefore the description of the configuration is omitted and the same reference numerals are given.

  As shown in FIGS. 5 and 6, the microneedle array device according to the present embodiment first has a lower case 55. The lower case 55 has a bowl shape and is composed of a bottom wall 57 and four side walls 59, 61, 63, 65 erected from the bottom wall 57. A chemical supply opening 67 is formed at the center of the bottom wall 57. The lower case 55 is formed with an opening 69. Further, recesses 70, 70, 70, 70 corresponding to the insertion pins 19 of the upper case 17 are formed at the four corners of the upper surface of the lower case 55 in FIG. Also in the present embodiment, the lower case 55 is made of plastic, but a case of metal is also conceivable.

  As in the case of the first embodiment described above, the upper case 17 is installed and fixed so as to close the opening 69 of the lower case 55.

  An internal block 71 is housed between the lower case 55 and the upper case 17. The internal block 71 is also made of an elastic member such as silicon rubber, like the internal block 23 of the first embodiment described above, and is set slightly larger than the internal space of the lower case 55. is there.

In the internal block 71, a plurality (two in this embodiment) of microneedle array accommodating spaces 73, 73 are formed. The microneedle array accommodation space 73 is formed in an open state on the upper side in FIG.
As shown in FIGS. 5 and 6, a chemical groove 75 is formed in the internal block 71. A chemical solution supply port 77 is provided near the center of the bottom surface (the lower surface in FIG. 6) of the chemical solution groove 75. Further, chemical solution outlets 79, 79, 79, 79, 79, 79 are provided on the bottom surface (the lower surface in FIG. 5) of the chemical solution groove 75. Further, a plurality (six in this embodiment) of channel grooves 81 are formed on the lower surface of the internal block 71 in FIGS. 5 and 6. The flow channel 81 communicates the chemical solution groove 75 and the microneedle array housing space 73, and the flow channel groove 81 and the chemical solution groove 75 are connected to each other through a chemical solution discharge port 79.
The chemical solution supply port 77 communicates with the chemical solution supply opening 67 of the lower case 55.

In the microneedle array housing spaces 73 and 73 of the internal block 71, microneedle arrays 35 and 35 are housed, respectively. The chemical fluid channel 41 of each microneedle 39 of the microneedle array 35 communicates with the chemical fluid groove 75 through the channel groove 81 and the chemical fluid outlet 79 of the internal block 71, respectively.

  The microneedle array device according to the present embodiment also has the same operations and effects as the microneedle array device according to the first embodiment described above.

Next, a third embodiment of the present invention will be described with reference to FIGS.
The upper case 17 and the microneedle array 35 are the same as those in the first embodiment, and the lower case 1 is almost the same as in the first embodiment. The description of the configuration is omitted, and the same reference numerals are given.

First, the microneedle array device according to the present embodiment has a lower case 1. The lower case 1 has substantially the same configuration as the lower case 1 in the microneedle array device according to the first embodiment, but as shown in FIG. 7, a shutter knob is provided on its side surface (the right side surface in FIG. 7). A through-hole 82 for use is drilled. The shutter knob through hole 82 communicates with the internal space of the lower case 1. Further, the bottom surface (the lower surface in FIG. 7) of the inner space of the lower case 1 and the bottom surface (the lower surface in FIG. 7) of the shutter knob through-hole 82 are flush with each other (continuous as one plane). It is).
Similarly to the case of the first embodiment described above, the upper case 17 is installed and fixed so as to close the opening 16 of the lower case 1.

  An internal block 83 is housed between the lower case 1 and the upper case 17. The internal block 83 is also made of an elastic member such as silicon rubber, and is set to be slightly larger than the internal space of the lower case 1 as in the case of the first embodiment described above.

  A plurality (two in the case of this embodiment) of microneedle array accommodating spaces 85, 85 are formed in the internal block 83. The microneedle array accommodation space 25 is formed in a state where the lower side in FIG. 7 is opened. A plurality (six in this embodiment) of through-holes 87 are formed on the upper surfaces of the microneedle array housing spaces 85 and 85.

A chemical groove 89 is formed at the center of the internal block 83. A chemical solution supply port 91 is formed in the bottom wall of the chemical solution groove 89, and a plurality (six in this embodiment) of chemical solution discharge ports 93 are formed.
Further, the inner block 83 is formed with a shutter plate accommodating portion 95 that opens downward in FIG. The shutter plate housing portion 95 communicates with the microneedle array housing space 25 and communicates with the chemical liquid groove 89 through the chemical liquid supply port 91 and the chemical liquid discharge port 93. A shutter knob groove 97 is formed on the right side of the shutter plate housing 95 in FIG. When the inner block 83 is housed in the lower case 1, the shutter knob through-hole 82 of the lower case 1, the shutter knob groove 97 of the inner block 83, and the shutter plate housing portion 95 communicate with each other. .

  A shutter plate 99 is accommodated in the shutter plate accommodating portion 95 of the internal block 83 so as to be movable in the left-right direction in FIG. As shown in FIG. 7, the shutter plate 99 includes a shutter plate main body 101 made of a substantially rectangular plate-like member, and a shutter knob 103 protruding and formed from the shutter plate main body 101 on the right side in FIG. The shutter plate main body 101 is provided with a circular supply through-hole 105. The shutter plate main body 101 is perforated with six sets of two holes, a chemical groove side through hole 107 and a microneedle array side through hole 109. The shutter knob 103 displays a filling position display scale 111, a storage position display scale 113, and an injection position display scale 115. These display scales are used as a guide when operating the shutter plate 99.

The shutter knob 103 passes between the shutter knob groove 97 of the inner block 83 and the bottom surface of the inner space of the lower case 1 and through the shutter knob through hole 82 of the lower case 1, It protrudes to the outside.
The shutter plate 103 can be moved by holding the shutter knob 103 with a hand or the like. The movement of the shutter plate 99 opens and closes the chemical liquid supply port 91, and connects the chemical liquid groove 89 and the chemical liquid flow path 41 of the microneedle 39 through the chemical liquid discharge port 93 and the flow channel groove 13 of the lower case 1. Communication / blocking can be performed.
The height of the shutter plate accommodating portion 95 (the vertical length in FIG. 9A) is set slightly smaller than the thickness of the shutter plate 99.

The operation will be described based on the above configuration.
First, when the shutter knob 103 is gripped and the shutter plate 99 is moved to a position where the filling position display scale 111 overlaps the opening outside the shutter knob through hole 82, the microneedle array device is shown in FIG. ) As shown in FIG. In this state, as shown in FIG. 9A, the chemical solution supply opening 15 of the lower case 1, the supply through hole 105 of the shutter plate 99, the chemical solution supply port 91 of the internal block 83, and the internal block 83 described above. The chemical groove 89 is communicated. Further, all the chemical solution outlets 93 of the chemical solution groove 89 are closed by the shutter plate 99. This state is a state where the microneedle array device is filled with a chemical solution.

In this state, a tube (not shown) passes through the chemical liquid supply opening 15 and is inserted into the chemical liquid supply port 91 of the internal block. And the chemical | medical solution is filled in the said chemical | medical solution groove | channel 89 by the pump which is not shown in figure through this tube.
The diameter of the chemical liquid supply port 91 is set to be slightly smaller than the diameter of the tube, and the internal block 83 is made of an elastic member such as silicon rubber. The sealing property between the outer peripheral surface of the tube is ensured.

  When the chemical liquid groove 89 has been filled with the chemical liquid, the tube is removed from the chemical liquid supply opening 15, the shutter knob 103 is gripped, and the shutter plate 99 has its storage position indication scale 113 penetrating the shutter knob. It is moved to a position that overlaps the opening on the outside of the hole 82. At this time, the microneedle array device is in a state shown in FIG. In this state, as shown in FIG. 9B, the chemical solution supply port 91 and all the chemical solution discharge ports 93 of the internal block 83 are closed by the shutter plate 99. Therefore, the filled chemical solution is confined in the chemical solution groove 89. This state is the chemical solution storage state of the microneedle array device.

  Next, the shutter knob 103 is gripped, and the shutter plate 99 is moved to a position where the injection position display scale 115 overlaps the opening outside the shutter knob through hole 82. At this time, the microneedle array device is in a state shown in FIG. In this state, as shown in FIG. 9C, the chemical solution supply port 91 of the internal block 83 is blocked by the shutter plate 99. On the other hand, all the chemical solution outlets 93 are open, and all the chemical solution channels 41 of the chemical solution groove 89 and the microneedle microneedle 39 pass through the chemical solution outlet port 93 and the chemical solution groove side of the shutter plate 99. The hole 107, the flow path groove 13 of the lower case 1, and the microneedle array side through hole 109 of the shutter plate 99 are in communication with each other. This state is an injection state of the microneedle array device. In this state, the microneedle 39 is pierced into the skin, so that the chemical solution in the chemical solution groove 89 can be injected subcutaneously through the microneedle 39.

As described above, according to the present embodiment, the following effects can be obtained in addition to the effects of the first embodiment described above.
First, depending on the position of the shutter plate 99, the state of the microneedle array device can be reliably switched to the above-described chemical solution filling state, chemical solution storage state, and injection state. Therefore, the chemical liquid leaks from the chemical liquid discharge port 93 when the chemical liquid is filled in the chemical liquid groove 89, the chemical liquid leaks from the chemical liquid groove 89 when the chemical liquid is stored, and the chemical liquid leaks from the chemical liquid supply port 91 during injection. Can be prevented.
In particular, when the microneedle array 35 is made of a material that is affected by the chemical solution, the microneedle array 35 can be prevented from touching the chemical solution before injection, thereby dissolving and denaturing the microneedle array 35. Can be prevented.
The inner block 83 is made of an elastic member such as silicon rubber, and the height of the shutter plate housing portion 95 (the length in the vertical direction in FIG. 9A) is slightly larger than the thickness of the shutter plate 99. It is set smaller. Therefore, the upper surface of the shutter plate 99 in FIG. 9A is pressed by the internal block 83, whereby the sealing performance is enhanced and the leakage of the chemical liquid can be prevented.

  Further, by operating the shutter plate 99, the state of the microneedle array device can be easily switched to the chemical solution filling state, the chemical solution storage state, and the injection state. Further, since the filling position display scale 111, the storage position display scale 113, and the injection position display scale 115 are respectively displayed on the shutter knob 103 as an indication of the chemical solution filling state, the chemical solution storage state, and the injection state, these The switching operation to the state can be reliably performed.

Next, a fourth embodiment of the present invention will be described with reference to FIGS.
The upper case 17 and the microneedle array 35 are the same as those in the first embodiment described above, and the description thereof will be omitted and the same reference numerals will be given.

  First, the microneedle array device according to the present embodiment has a lower case 117. The lower case 117 has a container shape, and includes a bottom wall 119 and four side walls 121, 123, 125, 127 erected from the bottom wall 119, and an opening 129 is formed. Is formed. The bottom wall 57 is formed with a shutter plate housing 131 that opens to the opening 129 side. A shutter knob through-hole 133 is formed on the right side of the shutter plate housing 131 in FIG. 10 so as to penetrate the lower case 117. In addition, a chemical supply opening 135 is formed at the center of the shutter plate housing 131. The lower case 117 has a recess 136 corresponding to the insertion pin 19 of the upper case 17.

  As in the case of the first embodiment described above, the upper case 17 is installed and fixed so as to close the opening 129 of the lower case 117.

  An internal block 137 is housed between the lower case 117 and the upper case 17. This internal block 137 is also made of an elastic member such as silicon rubber, as in the case of the first embodiment described above, and is set slightly larger than the internal space of the lower case 117.

  A plurality (two in this embodiment) of microneedle array accommodating spaces 139 and 139 are formed in the internal block 137. The microneedle array storage space 139 is formed in a state where the lower side in FIG. 10 is opened. In addition, a plurality (six in this embodiment) of through holes 141 are formed on the upper surface side of the microneedle array accommodating spaces 139 and 139.

  A chemical groove 143 is formed at the center of the internal block 137. A chemical solution supply port 145 is formed on the bottom wall of the chemical solution groove 143, and a plurality (six in this embodiment) of chemical solution discharge ports 147 are formed.

A shutter plate 149 is accommodated in the shutter plate accommodating portion 131 of the lower case 117 so as to be movable in the left-right direction in FIG. As shown in FIG. 10, the shutter plate 149 includes a shutter plate main body 151 and a shutter knob 153 protruding and formed from the shutter plate main body 151, as in the third embodiment.
The shutter plate main body 151 is provided with a circular supply through hole 155. The shutter plate body 151 has six long holes 157 perforated. When the shutter plate 149 is accommodated in the shutter plate accommodating portion 131, the elongated hole 157 is closed at the lower opening in FIG. 11C by the bottom surface of the shutter plate accommodating portion 131, and the flow channel groove 165. It functions as.

The shutter knob 153 displays a filling position display scale 159, a storage position display scale 161, and an injection position display scale 163, as in the third embodiment.
The shutter knob 153 passes through the shutter knob through-hole 133 of the lower case 117 and protrudes to the outside.
The height of the shutter plate accommodating portion 131 (length in the vertical direction in FIG. 11A) is set slightly smaller than the thickness of the shutter plate 149.

  The operation of the microneedle array device according to the present embodiment is substantially the same as that of the microneedle array device according to the third embodiment described above. That is, the movement of the shutter plate 149 can be switched between the chemical solution filling state, the chemical solution storage state, and the injection state, and the state shown in FIG. 11A is the chemical solution filling state of the microneedle array device according to the present embodiment. The state shown in FIG. 11 (b) is a chemical solution storage state, and the state shown in FIG. 11 (c) is an injection state.

As shown in FIG. 11A, in the chemical solution filling state, the chemical solution supply opening 135 of the lower case 117, the supply through hole 155 of the shutter plate 149, and the chemical solution supply port 145 of the internal block 137 communicate with each other. The chemical liquid channel 41 of the discharge port 147 and the microneedle array 35 is closed by the shutter plate 149, so that the chemical liquid groove 143 can be filled with the chemical liquid.
As shown in FIG. 11 (b), in the chemical solution storage state, the chemical solution supply port 145, the chemical solution discharge port 147, and the chemical solution channel 41 are closed by the shutter plate 149. In 143, the chemical solution is stored.
As shown in FIG. 11C, in the injection state, the chemical solution supply port 145 is closed by the shutter plate 149, and the chemical solution discharge port 147, the flow channel groove 165, and the chemical solution flow channel 41 communicate with each other. Then, the chemical solution filled in the chemical solution groove 143 is released from the microneedle 39.

  The effect of the microneedle array device according to the present embodiment is the same as that of the microneedle array device according to the third embodiment described above.

Next, a fifth embodiment of the present invention will be described with reference to FIGS.
The upper case 17, the microneedle array 35, and the shutter plate 149 are the same as those in the fourth embodiment described above, and description thereof is omitted and the same reference numerals are given. Further, the lower case 55 is almost the same as in the case of the second embodiment described above, and the description of the common configuration is omitted and the same reference numerals are given.

First, the microneedle array device according to the present embodiment has a lower case 55. The lower case 55 has almost the same configuration as that of the second embodiment described above, except that a shutter knob through-hole 169 is formed in the side wall 61. The bottom surface of the inner space of the lower case 55 (the lower surface in FIG. 12) and the bottom surface of the shutter knob through-hole 169 (the lower surface in FIG. 12) are continuous as one plane.
Similarly to the case of the first embodiment described above, the upper case 17 is installed and fixed so as to close the opening 69 of the lower case 55.

  An internal block 171 is provided between the lower case 55 and the upper case 17. This internal block 171 is also made of an elastic member such as silicon rubber, and is set to be slightly larger than the internal space of the lower case 1 as in the case of the first embodiment described above.

A plurality (two in this embodiment) of microneedle array accommodating spaces 173 and 173 are formed in the internal block 171. The microneedle array accommodation space 173 is formed in an open state on the upper side in FIG.
Further, a chemical solution groove 175 is formed in the internal block 171. A chemical solution supply port 177 is provided near the center of the bottom surface (the lower surface in FIG. 13) of the chemical solution groove 175. Further, chemical solution outlets 179, 179, 179, 179, 179, 179 are provided on the bottom surface (the lower surface in FIG. 13) of the chemical solution groove 175.
Further, through holes 181, 181, and 181 are formed in the bottom surface (the lower surface in FIG. 13) of the microneedle array housing space 173. The number of the through holes 181 corresponds to the number of the chemical liquid channels 41 and the microneedles 39 of the microneedle array 35 housed in the microneedle array housing space 173.

  Further, a shutter plate accommodating portion 183 that is open to the lower side in FIG. 13 of the internal block 171 is formed on the bottom surface (the lower surface in FIG. 13) of the internal block 171. The shutter plate accommodating portion 183 communicates with the microneedle array accommodating space 173 via the through hole 181 and communicates with the chemical solution groove 175 via the chemical solution supply port 177 and the chemical solution discharge port 179. The internal block 171 has a shutter knob groove 185 formed on the right side of the shutter plate housing 183 in FIG. When the inner block 171 is housed in the lower case 55, the shutter knob through-hole 169 of the lower case 55, the shutter knob groove 185 of the inner block 171 and the shutter plate housing portion 183 communicate with each other. .

  A shutter plate 149 is accommodated in the shutter plate accommodating portion 183 of the internal block 171 so as to be movable in the left-right direction in FIG. The individual long holes 157 of the shutter plate 149 function as flow channel grooves 165 by closing the lower opening in FIG. 13C by the bottom surface 57 of the lower case 55. The shutter knob 153 penetrates between the shutter knob groove 185 of the inner block 171 and the bottom surface of the inner space of the lower case 55, and passes through the shutter knob through-hole 169 of the lower case 55, Protruding.

  The effect | action by the microneedle array apparatus by this Embodiment is the same as that of the case of 4th Embodiment mentioned above. That is, the movement of the shutter plate 149 can be switched between a chemical solution filling state, a chemical solution storage state, and an injection state, and the state shown in FIG. 13A is the chemical solution filling state of the microneedle array device according to the present embodiment. The state shown in FIG. 13B is a chemical solution storage state, and the state shown in FIG. 13C is an injection state.

As shown in FIG. 13A, in the chemical solution filling state, the chemical solution supply opening 67 of the lower case 55, the supply through hole 155 of the shutter plate 149, and the chemical solution supply port 177 of the internal block 171 communicate with each other. By closing the discharge port 179 and the through hole 181 by the shutter plate 149, the chemical solution groove 175 can be filled with the chemical solution.
As shown in FIG. 13 (b), in the chemical solution storage state, the chemical solution supply port 177, the chemical solution discharge port 179, and the through hole 181 are closed by the shutter plate 149, so that the chemical solution groove 175 is provided. It will be in the state which stores chemicals.
As shown in FIG. 13 (c), in the injection state, the chemical solution supply port 177 is closed by the shutter plate 149, and the chemical solution discharge port 179, the flow channel groove 165, the through hole 181, and the microneedle array 35. The chemical liquid channel 41 communicates, and the chemical liquid filled in the chemical liquid groove 175 is released from the microneedle 39.

  The effect of the microneedle array device according to this embodiment is the same as that of the third embodiment described above.

The present invention is not limited to the first to fifth embodiments.
For example, as shown in FIG. 4, by appropriately adjusting the number of microneedle arrays 35 to be used, the number of microneedles 39 of the finally obtained microneedle array system can be freely selected.
Moreover, you may comprise so that the internal block in the said 1st-5th embodiment may have all or one part of the function of a pump function or a non-return valve.
Further, in the case of the fourth embodiment or the fifth embodiment, a groove may be provided instead of the long hole 157 of the shutter plate 149, and this may be used as a flow channel groove.
In addition, the illustrated configuration is merely an example and is not limited thereto.

  The present invention relates to a microneedle array device, and in particular, to a device devised so that a desired configuration can be easily realized by freely selecting the number and pitch of microneedles, for example, used for administration of insulin. It is suitable for equipment to be used.

DESCRIPTION OF SYMBOLS 1 Lower case 13 Channel groove 15 Chemical solution supply opening 17 Upper case 22 Through-hole 23 Internal block 25 Microneedle array accommodation space 29 Chemical solution groove 35 Microneedle array 39 Microneedle 55 Lower case 81 Channel groove 67 Chemical solution supply opening 71 Internal block 73 Microneedle array accommodation space 75 Chemical solution groove 83 Internal block 85 Microneedle array accommodation space 89 Chemical solution groove 99 Shutter plate 117 Lower case 137 Internal block 139 Microneedle array accommodation space 143 Chemical solution groove 149 Shutter plate 165 Flow channel groove 171 Inside Block 173 Microneedle array storage space 175 Chemical groove

Claims (11)

Comprising a case having microneedles protruding opening, a microneedle that protrudes to the outside through the microneedles projecting opening portion,
The case includes an opening and a lower case provided with a fluid supply opening, and an upper case provided to close the opening of the lower case and provided with the microneedle protruding opening. Configured,
A microneedle array device characterized in that the microneedles are punctured into the skin. The microneedle array device according to claim 1,
A microneedle array device, wherein a microneedle array is installed in the case, and the microneedles are provided in the microneedle array. The microneedle array device according to claim 2,
The microneedle array device has a configuration in which a plurality of microneedles are provided in a row. In the microneedle array device according to any one of claims 1 to 3 ,
A microneedle array device, wherein a recess having a larger diameter than the microneedle projecting opening is formed on the outer periphery of the microneedle projecting opening . In the microneedle array device according to any one of claims 2 to 4 ,
Between the lower case and the upper case, an internal block having a microneedle array housing recess and a fluid groove having a fluid supply port and a fluid discharge port is installed,
The microneedle array is housed and arranged in the microneedle array housing portion of the inner block,
A channel groove is provided between the lower case and the inner block,
Fluid is supplied into the fluid groove through the fluid supply opening of the lower case and the fluid supply port of the internal block, and the supplied fluid is supplied to the respective micro via the fluid discharge port and the flow channel groove. A microneedle array device, characterized in that it is supplied to a needle and injected through each of the microneedles . The microneedle array device according to claim 5,
A microneedle array device, wherein a shutter plate capable of selectively opening the fluid supply port and the fluid discharge port is provided between the inner block and the lower case . The microneedle array device according to claim 5 or 6 ,
The microneedle array device, wherein the channel groove is provided in the lower case . The microneedle array device according to claim 5 or 6 ,
The microneedle array device, wherein the channel groove is provided in the inner block . The microneedle array device according to claim 5 or 6 ,
The microneedle array device, wherein the channel groove is formed by a through hole provided in the shutter plate . In microneedle array device according to any one of claims 1 to 9,
The microneedle array device is made of a plastic material safe for a living body . In the microneedle array device according to any one of claims 5 to 9,
The microneedle array device according to claim 1, wherein the inner block is made of an elastic member and is formed to be slightly larger than the inner space of the lower case .

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