JP5448097B2 - Method of inserting microneedle into skin and auxiliary device used for the method - Google Patents

Description

  The present invention relates to a method for reliably inserting a microneedle (microneedle) into a skin and an auxiliary device therefor.

  Drug administration using a syringe is severely damaged and painful. As a new drug delivery system (DDS) that overcomes these problems, microneedles have been actively developed, and many proposals have been made regarding the materials and shapes of microneedles. However, when the microneedle is inserted into the skin, the microneedle may be broken and cannot be inserted without entering the skin. In addition, the microneedle may be broken simultaneously with the insertion, and the microneedle may remain in the skin. Therefore, an insertion tool (that is, an auxiliary device) for easily and surely inserting the microneedle into the skin is desired, and several proposals have been made (Patent Documents 1, 2, and 3). However, all of these conventionally proposed insertion tools are intended to be applied to metal microneedles, and sufficient studies have not been made to allow the microneedles to enter the skin without breaking.

  Further, as an improved type of a jet type syringe without a needle, a drug injection device for skin using an asymmetrical microneedle with high impact strength is disclosed (Patent Document 4). However, application to microneedles using a biodegradable resin with relatively low strength is considered difficult.

  By the way, if the biodegradable microneedle is used, if the microneedle is held on the skin surface after being inserted into the skin, the drug penetrates through the microneedle, and further, along with the decomposition of the microneedle, The drug contained in the microneedle is released. Thus, the use of biodegradable microneedles has many advantages such as improved drug absorbability and sustained drug release.

Therefore, in order to exhibit the above characteristics of the biodegradable microneedle, it is necessary to hold the microneedle on the skin surface after insertion of the microneedle. However, for that purpose, it is necessary to fix the microneedle with an adhesive tape or the like, and the microneedle may fall off or break during the fixing operation, and a simple fixing method is desired. . In addition, although the patch agent (patent document 5) which sticks a metal microneedle on the skin surface is known, it is not suitable for the application to the microneedle made from biodegradable resin which is weak to an impact and easy to break. .
Japanese translation of PCT publication No. 2004-510530 Special table 2007-509706 gazette JP 2005-533625 A JP 2005-518873 A Special table 2007-521092 gazette

  An object of the present invention is to provide a method and an auxiliary device for inserting a microneedle surely and easily into the skin, and in particular, since it has a relatively low strength, it is generally weak against impact and tends to be broken. It is an object to provide a method and an auxiliary device therefor that can be reliably and easily inserted into the skin without causing breakage even if the microneedles are made of biodegradable resin.

  In addition, even biodegradable resin microneedles that tend to break can be reliably and easily inserted into the skin without causing breakage, and the microneedle after insertion into the skin can be placed on the skin surface. It is to provide an auxiliary device that makes it easy to hold.

  Microneedle (microneedle-shaped member) made of biodegradable resin breaks when it comes into contact with the skin surface when it enters at an angle other than approximately perpendicular to the skin, or it cannot be inserted into the skin. May remain on the skin.

  Therefore, the present inventors fixed the skin surface, moved a biodegradable resin microneedle (using a symmetrical microneedle) in the axial direction of the microneedle, and pressed the microneedle to the skin. Thus, it was found that microneedles made of biodegradable resin can be inserted into the skin reliably and easily. In particular, if the skin surface is fixed so that the skin surface is perpendicular to the axis of the microneedle, the microneedle is moved in the axial direction and inserted perpendicularly to the skin surface. In addition, the microneedle can be inserted into the skin without breaking, and as an auxiliary device that allows the microneedle to be inserted into the skin surface while the skin surface is fixed, a cylindrical or spring type (bendable / extendable) It was found that a method using a frame made of a flat plate member is suitable. The above “symmetrical microneedle” means a microneedle array in which a plurality of microneedles are arranged in a symmetrical arrangement on a substrate.

  In addition, the microneedle is pressed against the skin surface together with the backing film by fixing the microneedle to the auxiliary device by adhering the microneedle onto the adhesive layer of the backing film having the adhesive layer formed on the surface. As a result, the insertion of the microneedle into the skin and the holding (fixing) of the microneedle on the skin surface can be performed substantially simultaneously, and the exterior having a recess for accommodating the microneedle Using the case and placing the peripheral wall portion surrounding the recess of the outer case in a state in which the microneedle is encapsulated in the recess, the workability of the insertion work into the skin of the microneedle is improved, If the microneedle falls off the skin surface or the microneedle breaks, It found that such can be prevented with Le.

  This invention is completed by repeating research based on the above knowledge, The summary is as follows.

[1] A method of inserting a microneedle into the skin,
a) Fix the microneedle (1) on one side of the plate (2),
b) The plate (2) is loosely fitted into the tubular member (4), the end surface on one side in the axial direction of the tubular member (4) is pressed against the skin surface, and the skin surface is fixed.
c) moving the plate (2) in the axial direction of the microneedle (1),
d) pressing the plate (2) against the skin surface;
A method of inserting a microneedle into the skin, characterized in that
[2] The method according to [1] above, wherein the cylindrical member (4) is cylindrical.
[3] The piston (3) is provided on one side of the plate (2) opposite to the fixed surface of the microneedle (1), and the piston (3) is pressurized with a finger so that the microneedle (1) The method according to [1] or [2] above, wherein the plate (2) is moved in the axial direction.
[4] The method of the above-mentioned [3], wherein the side surface of the piston (3) has a protrusion that can contact the inner surface of the cylindrical member (4).
[5] The method according to any one of [1] to [4], wherein a rail-like guide that engages with the plate (2) is provided on the inner surface of the cylindrical member (4).
[6] A method of inserting a microneedle into the skin,
a) Fix the microneedle (1) on one side of the plate (2),
b) of the plate member on the side separated from the plate (2) of the frame (20) formed of the plate member (21) having a pantograph-type cross section provided on the side periphery of the plate (2) One end (21a) is pressed against the skin surface to fix the skin surface,
c) The plate (2) is moved in the axial direction of the microneedle (1) by bending and stretching the frame (20),
d) pressing the plate (2) against the skin surface;
A method of inserting a microneedle into the skin, characterized in that
[7] The method according to any one of [1] to [6] above, wherein the displacement between the axis of the microneedle (1) and the movement direction of the plate (2) is less than 5 degrees.
[8] The method according to any one of [1] to [7], wherein the microneedle (1) is fixed on the plate (2) with an adhesive tape (6) and / or a stopper (7).
[9] After pressing the plate (2) against the skin surface, the microneedle (1) is peeled off from the plate (2), and the microneedle (1) is placed in the skin. The method according to any one.
[10] The method according to any one of [1] to [9] above, wherein the microneedle (1) is a bioneedle made of biodegradable resin or a microneedle made of polysaccharide.
[11] The method according to [10] above, wherein the biodegradable resin is one or more selected from polylactic acid, polyglycolic acid, and a copolymer of lactic acid and glycolic acid.
[12] The method according to [10] above, wherein the biodegradable resin is polylactic acid.
[13] The method described in [10] above, wherein the polysaccharide is maltose.
[14] A plate (2) in which one side is a fixed surface of the microneedle (1) and a piston (3) is erected on the other side;
A cylindrical member that holds the plate (2) loosely fitted therein, and has a cylindrical member (4) whose end surface on one side in the axial direction is pressed against the skin surface. Auxiliary device for insertion of microneedles into the skin.
[15] The side surface of the piston (3) has a protrusion (11) that can contact the inner surface of the cylindrical member (4) and / or the plate (2) is engaged with the inner surface of the cylindrical member (4). The auxiliary device according to [14] above, wherein the auxiliary device has a rail-like guide (12).
[16] The auxiliary device according to the above [14], wherein the other side in the axial direction of the cylindrical member is reduced in diameter to form a guide portion (8) for guiding the piston (3).
[17] The above-mentioned [14], wherein an end surface on one axial direction side of the cylindrical member (4) is a surface of a flange (4 ′) formed on an end portion on one axial direction side of the cylindrical member (4). -Auxiliary device in any one of [16].
[18] a plate (2) having one surface (2 ') as a fixed surface of the microneedle (1);
A frame body comprising a plate member (21) provided on a side periphery of the plate (2) and having a bent portion (21b) which can bend and stretch in a direction perpendicular to one side (2 ') of the plate (2). (20) An auxiliary instrument for inserting the microneedle into the skin.
[19] The auxiliary device according to [18] above, wherein the frame (20) comprises a plate member (21) having a pantograph-type cross section that can bend and stretch.
[20] The auxiliary device according to [18] or [19] above, wherein the projection (3 ′) is formed on the other side (2 ″) of the plate (2).
[21] The microneedle (1) is fixed to the skin application cloth (17) bonded to one side of the plate (2) via the weak adhesive (18) via the strong adhesive (16). The auxiliary device according to any one of [14] to [20].
[22] The above-mentioned [14], wherein the microneedle (1) is fixed to the plate (2) via a double-sided adhesive tape (6) whose adhesiveness on the microneedle (1) side is weaker than that on the plate (2) side. ] To [20].
[23] A double-sided pressure-sensitive adhesive tape (6) having a lower adhesive force on the microneedle (1) side than the plate (2) side covers the entire surface of the plate (2), and the microneedle (1) is covered with the double-sided pressure-sensitive adhesive tape (6 ), The auxiliary device according to any one of the above [14] to [20], which is fixed to the plate (2).
[24] An adhesive tape (6) having an adhesive surface only on one side on the microneedle side is held on one side of the plate (2), and the microneedle (1) is fixed to the adhesive tape (6). The auxiliary device according to any one of [14] to [20] above.
[25] It further has an exterior case (30) provided with a recess (31) containing the frame (20),
While the protruding portion (3 ′) formed on the other surface of the plate (2) is inserted into the through hole (30B) formed in the bottom plate (30A) of the outer case (30), the outer case (30 The end (21a) of the plate member (21) on the side away from the plate (2) of the frame (20) is fixed to the tip of the peripheral wall (30C) surrounding the recess (31) of
With the peripheral wall portion (30C) of the outer case (30) placed on the skin surface, the projection (3 ′) of the plate (2) is pushed down so that the microneedle (1) is inserted into the skin. The auxiliary device according to any one of [20] to [24], configured as described above.
[26] One side of the backing film (33) is bonded to one side (2 ') of the plate (2) via the weakly adhesive layer (32), and the other side of the backing film (33) The auxiliary device according to the above [25], wherein the microneedle (1) is fixed on a strong adhesive layer (34) formed on one side.
[27] An adhesive layer for adhesion to the skin is attached to the end (21a) of the plate member (21) constituting the frame (20), which is fixed to the tip of the peripheral wall (30C) of the outer case (30). The auxiliary device according to [25] or [26] above, wherein (35) is formed.
[28] A through hole (30B) is formed in the bottom plate (30A) of the outer case (30) having a recess (31) containing the microneedle (1), and a plug member (30B) is formed in the through hole (30B). 38) is loosely fitted,
A weak adhesive layer (32) is formed on the surface of the plug member (38) on the concave portion (31) side and the periphery of the through hole (30B) of the bottom plate (30A) of the exterior case (30). One side of the backing film (33) is bonded to the adhesive layer (32), and microneedles (34) are formed on the strong adhesive layer (34) formed on the other side of the backing film (33). 1) is fixed, while the peripheral edge of the backing film (33) is provided by the weakly supporting projecting member (39) attached to the inner surface of the peripheral wall (30C) surrounding the recess (31) of the outer case (30). Part is supported,
The microneedle (1) is configured to be inserted into the skin by pressing down the plug member (38) with the peripheral wall portion (30C) of the outer case (30) placed on the skin surface. Auxiliary device for inserting needle into skin.
[29] The auxiliary device according to [28] above, wherein an adhesive layer (35) for adhesion to the skin is formed at the tip of the peripheral wall (30C) of the outer case (30).
[30] The auxiliary instrument according to any one of [25] to [29] above, wherein a peelable protective film (36) for closing the opening of the recess (31) of the outer case (30) is attached.
[31] The auxiliary device according to any one of [14] to [30], wherein the microneedle (1) is a bioneedle made of biodegradable resin or a microneedle made of polysaccharide.
[32] A microneedle type preparation comprising a drug-containing microneedle fixed to the plate (2) of the auxiliary device according to any one of [14] to [31].

  According to the present invention, since the microneedle can be reliably and easily inserted into the skin, even if it is a microneedle made of biodegradable resin with relatively low strength, the needle tip of the microneedle does not break, Alternatively, it can be reduced and a microneedle can be punctured on the skin surface.

  Moreover, in the suitable aspect of the auxiliary instrument used for insertion of the microneedle of this invention into skin, since it has the exterior case provided with the recessed part which accommodates microneedle, microneedle is inserted in skin. Up to this point, the microneedle can be stored in the case, and the microneedle can be inserted into the skin while the microneedle is included in the recess of the outer case. Therefore, even a microneedle made of biodegradable resin can prevent the needle tip of the microneedle from being broken at a higher level.

It is sectional drawing of an example of the auxiliary tool used for skin insertion of the microneedle of this invention. Drawing (a), (b) is a sectional view of an auxiliary instrument using a comparatively short cylindrical member. 4 is a view showing that the skin surface is fixed (maintained) in an arrangement in which the skin surface is always perpendicular to the axis of the microneedle by using the auxiliary device of the present invention. It is sectional drawing which shows the fixing method (double-sided adhesive tape) of the microneedle installed in a plate. It is sectional drawing which shows the fixing method (single-sided adhesive tape and stopper) of the microneedle installed in a plate. Figures (a) to (c) are cross-sectional views of auxiliary devices provided with technical means for stable movement of the plate, respectively. Sectional drawing (figure (a)), perspective view (photograph) (figure (b)) seen from the plate side, and perspective view seen from the microneedle side of the pantograph type auxiliary device used for skin insertion of the microneedle of the present invention It is a figure (photograph) (figure (c)). It is sectional drawing of the pantograph type auxiliary instrument which provided the projection site | part in the plate. It is the shape (photograph) of the microneedle of the microneedle before insertion when inserting the microneedle into the skin of a rat by hand. It is the shape (photograph) of the microneedle of the microneedle after the insertion when the microneedle is inserted into the skin of the rat by hand. It is the shape (photograph) of the microneedle before insertion when inserting a microneedle into the skin of a rat using an insertion assisting device (cylindrical shape). It is the shape (photograph) of the microneedle after insertion in the case of inserting a microneedle in the skin of a rat using an insertion auxiliary instrument (cylindrical shape). It is a schematic cross-sectional view of a test auxiliary instrument for pressing the plate against the skin in a state where the axial direction of the microneedle and the traveling direction of the plate are shifted by 5 degrees. It is the shape (photograph) of a microneedle after making a plate press-fit to the abdomen of a rat with the auxiliary instrument of FIG. 13, and inserting a microneedle into skin. It is sectional drawing showing the fixing method of the microneedle installed in a plate. It is sectional drawing of the modification of the pantograph type auxiliary instrument used for skin insertion of the microneedle of this invention. It is an auxiliary instrument for inserting the microneedle of the present invention into the skin, and is a schematic sectional view of a first example of an auxiliary instrument using an exterior case. It is a schematic cross section which shows the operation | work which peels off the film for operation at the time of using the auxiliary tool shown in FIG. It is a schematic cross section which shows the state which peeled off the film for operation at the time of using the auxiliary tool shown in FIG. It is a schematic cross section which shows the state which mounted the auxiliary device shown in FIG. 17 on the skin surface. It is a schematic cross section which shows the state which is performing the skin insertion of the microneedle using the auxiliary | assistant instrument shown in FIG. It is a schematic cross section which shows the state which fixed the microneedle to the skin surface using the auxiliary tool shown in FIG. It is an auxiliary instrument for inserting the microneedle of this invention in skin, Comprising: It is a schematic cross section of the 2nd example of the auxiliary instrument using the exterior case. It is a schematic cross section which shows the state which peels off the protective film from the auxiliary instrument shown in FIG. 23, and is performing the skin insertion of a microneedle. It is a schematic cross section which shows the state which fixed the microneedle to the skin surface using the auxiliary tool shown in FIG. It is an auxiliary instrument for inserting the microneedle of this invention in skin, Comprising: It is a schematic cross section of the 3rd example of the auxiliary instrument using the exterior case. It is a schematic cross section which shows the state which peels off the protective film from the auxiliary instrument shown in FIG. 26, and is performing the skin insertion of a microneedle. It is a schematic cross section which shows the state which peels off the protective film from the auxiliary instrument shown in FIG. 26, and is performing the skin insertion of a microneedle. It is a schematic cross section which shows the state which fixed the microneedle to the skin surface using the auxiliary tool shown in FIG.

Explanation of symbols

1 Microneedle 2 Plate 3 Piston 4 Cylindrical member 5 Plate material on top of piston 6 Adhesive tape (double-sided tape or single-sided tape)
7 Stopper 8 Guide part 20 A frame (pantograph type frame) made of a plate member formed with a bendable / extendable bent part
30 exterior case 33 backing film 50 skin surface

  Hereinafter, the present invention will be described in more detail with reference to preferred embodiments shown in the accompanying drawings. In the drawings, the same or corresponding elements are denoted by the same reference numerals. Also, the dimensions in the drawings are schematic and do not have an exact proportional relationship with the actual dimensions.

  In the method of inserting the microneedle of the present invention into the skin, for example, it is desirable to use an auxiliary instrument shown in FIG. FIG. 1 shows a first example of an auxiliary device according to the present invention, which is a syringe-like insertion auxiliary device in which a microneedle (1) is fixed to one side of a plate (2). Here, the microneedle (1) is fixed to the plate (2) so that the axial direction of the microneedle coincides with the moving direction of the plate (2). The plate (2) is loosely fitted inside the cylindrical member (4). By applying an external force to the piston (3) erected on the other side of the plate (2), the plate (2) is directed toward the skin surface (50). Thus, the tubular member (4) can be moved straight. In addition, the code | symbol (5) in a figure is a plate-shaped piece for making it easy to give external force provided in the opposite side to the junction part side with the plate (2) of piston (3), for example, human An external force can be easily applied to the piston (3) by pressing a finger against the plate-like piece (5).

  FIG. 1 (a) shows an initial state in which an external force is applied to the piston (3), and FIG. 1 (b) applies a further external force to the piston (3) to bring the plate (2) onto the skin surface (50). It is in the state advanced toward. As shown in these drawings, the auxiliary device is used in a state where the end surface on one side in the axial direction of the cylindrical member (4) is pressed against the skin surface (50) and the skin surface (50) is fixed. The In addition, the arrow in a figure has shown the external force.

  FIG. 2 shows a second example of the auxiliary device according to the present invention. As shown in FIG. 2 (a), the auxiliary device according to the present invention contracts the other side in the axial direction of a relatively short tubular member (4). The guide portion (8) for guiding the piston (3) may be provided on the cylindrical member (4). Further, as shown in FIG. 2B, a through-hole through which the piston (3) passes is provided at the end of the cylindrical member (4) that is relatively short, on the side away from the microneedle (1). You may make it the structure obstruct | occluded with the cover part (8 ').

  Further, as shown in FIGS. 2A and 2B, a flange (4 ′) is provided at one end in the axial direction of the cylindrical member (4), and the surface of the flange (4 ′) is attached to the skin. You may make it the structure which press-contacts the surface (50) and fixes the skin surface (50). With this configuration, the skin surface (50) can be more securely fixed.

  By using the auxiliary device of the present invention, as shown in FIG. 1, the cylindrical member (4) is pressed vertically against the skin surface (50) (that is, one side in the axial direction of the cylindrical member (4)). After the skin surface (50) is pressed against the skin surface (50) and the skin surface (50) is fixed, an external force is applied to the piston (3) to move the plate (2), and the plate (2) is moved to the skin surface (50). ), The microneedles (1) on the plate (2) are inserted into the skin.

  When the plate (2) is pressure-bonded to the skin surface (50) and the microneedle (1) is inserted into the skin, the microneedle (1) is reliably prevented from breaking, and the microneedle (1) is reliably In order to puncture the skin and place it in the skin, the axial direction of the microneedle of the microneedle (1) on the plate (2) and the traveling direction of the plate (2) match, or It is desirable that these are angle shifts smaller than 5 degrees. For example, if the advancing direction and the axial direction of the microneedle are deviated by 5 degrees or more, the tip of the microneedle is easily broken, and it is difficult to pierce the skin.

  The “microneedle (1)” in the present invention is typically a plurality of microneedles arranged in a direction perpendicular to the substrate surface, as shown in FIGS. The above-described “axial direction of the microneedle of the microneedle (1)” is substantially the same in any microneedle of the plurality of microneedles.

  When the auxiliary device of the present invention is used, as shown in FIG. 3, the cylindrical member (4) pressed against the skin surface (50) is slightly inclined (that is, the end of the cylindrical member (4)). Even if the amount of depression into the skin on the entire circumference is not uniform), the skin surface (50) is fixed at the end face of the tubular member (4), so the microneedle (1) It descends so that the axial direction is orthogonal to the skin surface (50).

  As shown in FIG. 4, in the auxiliary device of the present invention, the microneedle (1) is fixed on the plate (2) via, for example, an adhesive tape (6). Here, the adhesive tape (6) is a double-sided adhesive tape having different adhesive forces on the microneedle (1) side and the plate (2) side. This adhesive tape (6) is used when the piston (3) is pulled up and the plate (2) is returned to its original position after the microneedle (1) is inserted into the skin (FIG. 1 (a), FIG. 3). Etc.), and the microneedle (1) has a function of being peeled and placed on the skin surface. For example, by using the adhesive tape (6) having a weak adhesive force on the microneedle (1) side, only the microneedle (1) is peeled from the adhesive tape (6) and the microneedle (1) is applied to the skin. Can be detained. In addition, the arrow in FIG. 4 has shown the adhesion | attachment to the skin surface.

  Further, as shown in FIG. 4, when the adhesive tape (6) is provided so as to cover not only the mounting portion of the microneedle (1) of the plate (2) but also the entire surface of the plate (2), for example, When the pressure-sensitive adhesive tape (6) has a lower adhesive strength on the surface on the plate (2) side than that on the surface on the microneedle (1) side, the plate (2) is adhered to the skin surface. The periphery of the microneedle (1) of the tape (6) adheres to the skin surface, and the microneedle (1) can be securely fixed to the skin. After that, when the plate (2) is pulled up to the original position, the adhesive tape (6) has a weak adhesive force on the surface on the plate (2) side. The microneedle (1) is placed on the skin by adhering to the skin surface.

  When an adhesive tape having an adhesive surface only on one side on the microneedle side is used for the adhesive tape (6), as shown in FIG. 5, a stopper (locking protrusion piece) provided at the corner portion of the plate (2). ) (7) holds the adhesive tape (6) on one side of the plate (2), thereby fixing the microneedle (1) on one side of the plate (2). Also in this case, when the plate (2) is pressure-bonded to the skin surface, the adhesive tape (6) around the microneedle (1) adheres to the skin, and the microneedle (1) can be fixed to the skin. And then, when the plate (2) is pulled up to the original position, the adhesive tape (6) is detached from the stopper (7) by the adhesive force with the skin, and adheres to the skin surface in a state of covering the microneedles (1), The microneedle (1) will be placed in the skin. Note that the arrows in FIG. 5 indicate adhesion to the skin surface.

  In the auxiliary instrument of the present invention, as described above, the plate (2) is moved so that the moving direction of the plate (2) matches the axial direction of the microneedles of the microneedle (1). As a means for fixing the moving direction in a certain direction, the thickness of the plate (2) is relatively large, and the contact area between the side surface of the plate (2) and the inner surface of the cylindrical member (4) is increased. 1 aspect (FIG. 6 (a)), 2nd aspect which provides the rail-like guide (12) engaged with a plate (2) in the inner surface of a cylindrical member (4), and a cylindrical member on the side surface of a piston (23) A third mode (FIG. 6C) in which a protrusion that can abut on the inner surface of (4) can be mentioned. In addition, the piston (23) in FIG.6 (c) is a piston which served as the plate function for fixing microneedle (1).

In the first embodiment, for example, when the size of the plate (2) (area) is approximately 0.5 cm ² ～30Cm ² mm, it is to roughly 0.5mm~10mm about the thickness of the plate (2) preferable. In the case of the third mode, as a preferable mode, for example, two or more different positions in the axial direction of the piston (23) on the side surface of the piston (23) (a plurality of positions having different distances from the end of the piston) ), And an embodiment in which three or more protrusions are provided at substantially equal intervals on the concentric outer circumference.

  In the syringe-like auxiliary instrument using the cylindrical member (4) described above, the cross-sectional shape of the cylindrical member (4) (the cross-sectional shape orthogonal to the axis of the cylindrical member) is not limited, and the cylindrical member is A cylindrical shape, a rectangular tube shape, or other shapes may be used, but a cylindrical shape or a rectangular tube shape is preferable from the viewpoints of handleability, movable stability of the plate (2), and the like. Therefore, the planar shape of the plate (2) is preferably circular or square.

  In addition to the syringe-like auxiliary device exemplified above, the auxiliary device of the present invention includes a side periphery of a plate (2) that is a base material for fixing the microneedle (1) as shown in FIG. In addition, there is a mode in which a frame body (20) composed of a plate member (21) having a bent portion (21b) that can bend and stretch in a direction perpendicular to one side (2 ′) of the plate (2) is used.

  In the example of FIG. 7 (a), the frame (20) composed of the plate member (21) having the bending portion (21b) that can bend and stretch is configured in a pantograph shape in cross section, but is shown in FIG. As described above, the frame (20) may be configured such that the top of the bent portion (21b) that can bend and stretch is directed to the inner side (microneedle (1) side).

  As shown in FIGS. 7B and 7C, the frame body (20) is usually provided so as to surround the entire side portion of the plate (2). That is, in FIGS. 7B and 7C, a frame body (20) including a plate member (21) is provided so as to surround the four sides of the plate (2) having a substantially square planar shape. For example, the frame (20) is attached to one opposite side of the two opposite sides of the plate (2) having a substantially square or rectangular plane shape, and the frame (20) is attached to the other opposite side. The structure which does not provide may be sufficient.

  Further, one end portion (21a) of the plate member (21) on the side away from the plate (2) in the frame body (20) is formed in an annular flat plate shape as shown in FIG. 7B. It is preferable from the viewpoint of the fixation of the skin surface.

  7 and 16, for the sake of simplification, a configuration for fixing the microneedle (1) to one side (2 ') of the plate (2) is not shown, but such a plate (2 In the auxiliary device of the type using the frame body (20) composed of the plate member (21) having the bent portion (21b) that can be bent and stretched on the side periphery of the adhesive), the double-sided adhesive as shown in FIGS. A method of fixing the microneedles (1) using the tape (6) is employed.

  The microneedle is inserted into the skin using an auxiliary device of a type using a frame (20) composed of a plate member (21) having a bent portion (21b) that can bend and stretch on the side periphery of the plate (2). First, as shown in FIG. 7A, one end (21a) of the plate member (21) on the side separated from the plate (2) of the frame (20) is attached to the skin surface (50). Press to fix the skin surface. Next, for example, one side (2 ″) of the plate (2) opposite to the fixed surface of the microneedle (1) is pressed with a human finger (applying an external force), and the plate (2) is pushed down. Then, the bending angle of the V-shaped bent portion (21b) of the plate member (21) capable of bending and stretching of the frame (20) becomes smaller, and the plate (2) moves in the axial direction of the microneedle (1). Then, the microneedle (1) on the plate (2) is inserted into the skin by pressure-bonding to the skin surface (50). In addition, the arrow in Fig.7 (a) has shown the external force.

  In order to prevent the movement direction of the plate (2) from deviating from the axial direction of the microneedle (1) due to improper directionality of pressing (pressing) by a human finger, as shown in FIG. A protruding portion (3 ′) can be erected on one surface (2 ″) of the plate (2) opposite to the fixed surface of the microneedle (1). By pressing (pressing) the protruding portion (3 ') with a finger, it becomes easy to match the direction of pressing (pressing) with the axial direction of the microneedle (1).

  FIG. 17 includes a frame (20) made of a plate member (21) having a bent portion (21b) that can bend and stretch on the side periphery of the plate (2) as shown in FIG. ) Is a further improvement of a type of auxiliary device in which a protruding portion (3 ′) is formed on one surface (2 ″) opposite to the fixing surface of the microneedle (1). That is, the auxiliary instrument 100 shown in FIG. 17 includes the frame (20) separately from the frame (20) provided on the side periphery of the plate (2) that is a fixing base of the microneedle (1). An outer case (30) provided with a concave portion (31) is formed, and a through hole (30B) is formed in the bottom plate (30A) of the outer case (30), and the through hole (30B) is formed. The peripheral wall portion (30C) surrounding the recess (31) of the outer case (30) while inserting the protruding portion (3 ') formed on the other side of the plate (2) to which the microneedle (1) is fixed The end (21a) of the plate member (21) on the side away from the plate (2) of the frame (20) made of the plate member (21) having a bent portion (21b) that can bend and stretch at the tip of By fixing (reference numeral 22 in FIG. 10 is an adhesive), In the recess (31) of the instrumentation case (30) accommodates a plate microneedles (1) is fixed (2).

  The opening of the recess (31) containing the microneedle (1), the plate (2), and the frame (20) in the outer case (30) is closed with a peelable protective film (36). Until the operation of inserting (1) into the skin is performed, the microneedle (1) is isolated from the outside. Therefore, it is possible to prevent a problem that the needle tip breaks due to some external force applied to the needle tip of the micro needle while the micro needle is being stored. An operation film (37) for protecting the back side of the outer case (30) and facilitating the peeling operation of the protective film (36) is attached to the rear surface of the outer case (30). The operation film (37) extends to one side of the outer case (30) and is joined to the end of the protective film (36). In addition, the code | symbol 40 in FIG. 17 is the adhesion layer formed in the film for operation (37).

  Further, one side of the backing film (33) is bonded to one side (2 ′) of the plate (2) via a weakly adhesive layer (32), and the other side of the backing film (33) is attached to the other side. A strong adhesive layer (34) is formed, and the microneedles (1) are fixed on the strong adhesive layer (34). As will be described later, the backing film (33) is used to fix the microneedle (1) to the skin surface after the microneedle (1) is inserted into the skin.

  An adhesive layer (35) for adhesion to the skin is attached to the end (21a) of the plate member (21) constituting the frame (20), which is fixed to the tip of the peripheral wall (30C) of the outer case (30). The adhesive layer (35) is also used as an adhesive layer for fixing the protective film (36) that closes the opening of the recess (31).

  In the auxiliary instrument (100) of the embodiment shown in FIG. 17, when the microneedle (1) is inserted into the skin, first, as shown in FIGS. 18 and 19, the operation film (37) is attached to the exterior case. It peels from the back surface of (30), and also peels off the protective film (36). After peeling off these films, the peripheral wall portion (30C) of the outer case (30) is placed on the skin surface (50) as shown in FIG. In addition, since the adhesive layer (35) for adhesion | attachment to skin is formed in the edge part (21a) of the board member (21) adhere | attached on the front end surface of the surrounding wall part (30C), skin surface (50) The outer case (30) is fixed to the outer case (30), and the outer case (30) is positioned. In this state, as shown in FIG. 21, by pushing down the protruding portion (3 ′) of the plate (2), the microneedle (1) is bonded to the backing film (2 ′) of the plate (2). 33) is pressed against the skin surface (50), and then the outer case (30) is pulled up from the skin surface (50). As shown in FIG. 21, the microneedle (1) is inserted into the skin. In the state, the backing film (33) covers the back surface of the microneedle (1), the adhesive layer (34) having strong adhesiveness adheres to the skin surface (50), and the microneedle (1) is fixed to the skin surface ( Detained) (FIG. 22). In addition, the arrow in FIG. 21 has shown the external force.

  Thus, since the auxiliary device (100) of this aspect has the exterior case (30), it is easy to position and fix the auxiliary device on the skin surface (50), and the skin surface (50). Since the plate (2) holding the microneedle (1) can be lowered to the skin surface (50) with the auxiliary device fixed thereon, the microneedle (1) can be inserted into the skin reliably and easily. Even a microneedle made of biodegradable resin with relatively low strength can puncture the microneedle on the skin surface without causing or reducing breakage of the needle tip of the microneedle Can do. Further, since the microneedle (1) is pressed against the skin surface (50) together with the backing film (33), the insertion of the microneedle into the skin and the retention (indwelling) of the microneedle on the skin surface are substantially simultaneously performed. Can be done. Therefore, it is not necessary to fix the microneedle inserted into the skin with an adhesive tape or the like, and it is possible to eliminate the occurrence of problems such as the microneedle dropping or breaking during the microneedle fixing operation.

  Further, since the microneedle (1) is inserted into the skin in a state where the microneedle (1) is included in the exterior case (30), the needle tip of the microneedle (1) is inadvertently inserted during the insertion operation. It is possible to reliably prevent problems such as the needle tip from being broken by colliding with other objects or articles.

  FIG. 23 shows a modification of the auxiliary instrument (100) shown in FIG. In the auxiliary instrument (101) shown in FIG. 23, the protruding portion (3 ′) of the plate (2) which is a fixing base of the microneedle (1) and the protruding portion (3 ′) are loosely fitted. While the through hole (30B) provided in the bottom plate (30A) of the outer case (30) is widened, a frame (20 ′) made of a plate member (21) having a bendable / extendable bending portion (21b) is attached to the plate (2 ) And a backing film (33) adhered to the frame (20 ′), and on the strong adhesive layer (34) formed on one side of the backing film (33). The microneedle (1) is fixed.

  In this auxiliary instrument (101), the backing film (33) is bent along the corner between the back surface and the side surface of the microneedle (1), and the bent state of the backing film (33) is maintained. As described above, the weak adhesive layer interposed between the backing film (33) and the frame (20 ′) is a thin adhesive layer (32A) on the part facing the back surface of the microneedle (1). The adhesive layer (32B) having a large thickness is formed on both sides of the microneedle (1). The protective film (36) that closes the opening of the recess 31 of the outer case (30) is affixed to the outer side of the peripheral wall (30C) of the outer case (30) with the gripping margin (36A) protruding, It extends to the back side of the exterior case (30) and is attached to the back surface of the exterior case (30) and the projecting portion (3 ′) of the plate (2).

  The operation of inserting the microneedle (1) into the skin using the auxiliary device (101) is basically the same as that of the auxiliary device (100) of FIG. 10 described above, and as shown in FIG. After peeling the film (36), the peripheral wall part (30C) of the outer case (30) is placed on the skin surface (50) (that is, for adhesion to the skin provided at the tip of the peripheral wall part (30C)). Adhesive layer (35 ') is adhered to skin surface (50)), and projection part (3') of plate (2) is pushed down so that microneedle (1) is attached to one side (2 ') of plate (2). When the outer case (30) is pulled up from the skin surface (50) together with the bonded backing film (33), the microneedle (1) is brought into contact with the skin surface (50) as shown in FIG. Inserted into the skin In the state, the backing film (33) covers the back surface of the microneedle (1), the adhesive layer (34) having strong adhesiveness adheres to the skin surface (50), and the microneedle (1) is fixed to the skin surface ( Detained).

  On the other hand, in FIG. 26, a through hole (30B) is formed in the bottom plate (30A) of the exterior case (30) having the recess (31), and a plug member (38) that is loosely fitted in the through hole (30B) is provided. Furthermore, by attaching a weakly supporting projecting member (39) to the inner surface of the peripheral wall (30C) surrounding the recess (31) of the outer case (30), use a plate that is a base material for fixing the microneedle. The auxiliary instrument (102) is configured to hold the microneedle (1) in the outer case (30). The weakly supporting projecting member (39) is formed by bending a thin plastic film and fixing it to the inner surface of the peripheral wall portion (30C) of the outer case (30).

  That is, in the auxiliary device (102), the microneedle (1) is fixed on the strong adhesive layer (34) on one side of the backing film (33), and the other side of the backing film (33). One side is directly adhered to the bottom plate (30A) and the plug member (38) of the outer case (30) by the adhesive layer (32) having weak adhesiveness, and the periphery of the backing film (33) is the peripheral wall of the outer case (30). The microneedle (1) is held in the outer case (30) by being supported by the weakly supporting projecting member (39) attached to the inner surface of the portion (30C).

  The operation of inserting the microneedle (1) into the skin using the auxiliary device (102) is basically the same as that of the auxiliary device (101) of FIG. 23 described above, and as shown in FIG. After peeling the film (36), the peripheral wall part (30C) of the outer case (30) is placed on the skin surface (50) (that is, for adhesion to the skin provided at the tip of the peripheral wall part (30C)). By sticking the adhesive layer (35) to the skin surface (50) and pushing down the plug member (38), the microneedles (1) are pressed against the skin surface (50) together with the backing film (33). At this time, the end portion of the backing film (33) is slipped by deforming the weakly supporting projecting member (39) attached to the inner surface of the peripheral wall portion (30C) by its own weight (FIG. 28). 29, with the microneedle (1) inserted into the skin, the backing film (33) covers the back of the microneedle (1), and the strong adhesive layer (34) is the skin. Adhering to the surface (50), the microneedle (1) is fixed (placed) on the skin surface. In addition, the arrow in FIG. 28, 29 has shown the external force.

  Hereinafter, materials, components, and the like of the constituent elements of the microneedle applicable to the present invention and the auxiliary device of the present invention will be described.

  The microneedle (1) applicable to the present invention is not limited, and known microneedles of various materials and uses can be used. For example, in addition to silicon and ceramics, for example, metal microneedles such as stainless steel, tungsten steel, nickel alloy, molybdenum, chromium, cobalt, titanium and alloys thereof; for example, polylactic acid, polyglycolic acid, lactic acid / glycol Microneedles made of biodegradable resins typified by aliphatic polyester resins such as acid copolymers; for example, microneedles made of polysaccharides such as maltose, lactose, sucrose, mannitol, sorbitol, etc. Among them, aliphatic polyester resin microneedles and polysaccharide microneedles that are biodegradable materials tend to be relatively low in strength, weak against impact, and easy to break. By using the instrument, it is possible to reliably puncture the microneedle on the skin surface without causing or reducing the breakage of the needle tip of the microneedle. In the method of the present invention, since the microneedle (1) can be simply placed on the skin after puncturing the microneedle (1) on the skin surface, the microneedle (1) of the biodegradable material can be used. It is possible to effectively utilize the improvement in drug absorption and sustained release of the drug.

  The microneedle (1) is a member that is used as an auxiliary agent for transdermal administration of a drug. The drug at that time is not limited to a drug for treating a disease, but a general substance having biological activity in the body. For example, antibiotics, antiviral agents, analgesics, anesthetics, appetite suppressants, antiarthritic agents, antidepressants, antipsychotics, antihistamines, anti-inflammatory agents, antitumor agents, vaccines including DNA vaccines, adjuvants , Allergic antigens, biological preparations, proteins, peptides and fragments thereof, but not limited thereto. In addition, when a drug is administered as a solution (drug solution) dissolved or dispersed in a solvent, the solvent can be arbitrarily selected from any solvents that are compatible with the living body. Examples thereof include, but are not limited to, distilled water, physiological saline, aqueous glucose solution, alcohol, propylene glycol, vegetable oil, and the like, or combinations thereof. Furthermore, solubilizers (eg, polyethylene glycol, propylene glycol, D-mannitol, ethanol, etc.), surfactants (eg, sodium lauryl sulfate, etc.), isotonic agents (eg, sodium chloride, etc.), buffering agents (eg, , Phosphoric acid, acetic acid, etc.) and preservatives (eg, p-hydroxybenzoic acid ester, etc.) can also be added.

  Further, in the case of biodegradable resin microneedles or polysaccharide microneedles, a drug is mixed in the biodegradable resin or polysaccharide in advance, and the microneedle is produced by the method shown in Reference Example 1 described later. By doing so, a microneedle containing a drug (drug-containing microneedle) can be obtained. In such a drug-containing microneedle, it is possible to release the drug from the microneedle itself by piercing the living body (skin). Therefore, by fixing the drug-containing microneedles to the plate (2) of the auxiliary device of the present invention, a microneedle type preparation can be realized, and in particular, by using the auxiliary device having the backing film (33), the microneedle type A patch formulation can be realized.

  In the present invention, the plate (2) is a base material for fixing the microneedles, and is a microneedle support base that holds the microneedles and can move in the axial direction of the microneedles. The thickness of the plate (2) is generally about 0.5 mm to 10 mm. The material of the plate (2) is not particularly limited, and any of resin, metal, wood, etc. can be used, but from the viewpoint of processability, polyethylene, polypropylene, polyvinyl chloride, acrylic, polyethylene terephthalate, polystyrene, acrylonitrile, butadiene, Resins such as styrene copolymers, polycarbonates, polyamides, fluororesins, polybutylene terephthalates are suitable.

  The material of the piston (3), the cylindrical member (4), etc. is not particularly limited, and any of resin, metal, wood, etc. can be used, but from the viewpoint of workability, polyethylene, polypropylene, polyvinyl chloride, acrylic, polyethylene Resin such as terephthalate, polystyrene, acrylonitrile / butadiene / styrene copolymer, polycarbonate, polyamide, fluororesin, polybutylene terephthalate, and the like is preferable.

  The frame body (20) composed of the plate member (21) in which the bending portion (21b) that can be bent and stretched is usually made of resin in order to be able to bend and stretch. From the viewpoint of workability, polyethylene, polypropylene, poly Resins such as vinyl chloride, acrylic, polyethylene terephthalate, polystyrene, acrylonitrile / butadiene / styrene copolymer, polycarbonate, polyamide, fluororesin, and polybutylene terephthalate are suitable. Further, the weakly supporting projecting member (39) is also generally formed of the resin (plastic) exemplified here.

  The material of the exterior case (30) is not particularly limited, and any of resin, metal, wood, etc. can be used, but from the viewpoint of processability, polyethylene, polypropylene, polyvinyl chloride, acrylic, polyethylene terephthalate, polystyrene, acrylonitrile butadiene -Resins such as styrene copolymer, polycarbonate, polyamide, fluororesin, and polybutylene terephthalate are suitable.

  The backing film (33) is, for example, a plastic film made of polyester, nylon, polyethylene, polypropylene, polyvinyl chloride, ethylene-ethyl acrylate copolymer, polytetrafluoroethylene, or the like, and a laminated film of such plastic film and metal foil. Etc. Further, the backing film (33) can be substituted by the skin application cloth (17) mentioned in Example 4 described later, and a woven cloth, a knitted cloth, a non-woven cloth or the like can be used.

  The weak adhesive layer (32) used for adhesion to the plate (2) or the outer case (30) formed on one side of the backing film (33) has various known adhesives (for example, Acrylic adhesives, rubber adhesives, silicone adhesives, etc.) can be applied to reduce the thickness of the adhesive layer and form an adhesive layer in a pattern (adhesive application area is a spot, stripe, mesh) A weak adhesion treatment such as forming a shape). Of course, weak adhesiveness may be obtained by a known method such as adjustment of the pressure-sensitive adhesive composition or addition of an additive for reducing the adhesive strength.

  The strong adhesive layer (34) used for fixing the microneedle (1) and adhering the backing film (33) to the skin surface, which is formed on the other surface of the backing film (33), Any so-called medical pressure-sensitive adhesive having skin adhesiveness can be used without particular limitation. Specifically, an acrylic pressure-sensitive adhesive made of an acrylic polymer; a styrene-diene-styrene block copolymer (for example, a styrene-isoprene-styrene block copolymer, a styrene-butadiene-styrene block copolymer, etc.), poly Rubber adhesives such as isoprene, polyisobutylene and polybutadiene; silicone adhesives such as silicone rubber, dimethylsiloxane base and diphenylsiloxane base; vinyl ether adhesives such as polyvinyl methyl ether, polyvinyl ethyl ether and polyvinyl isobutyl ether; vinyl acetate -A vinyl ester adhesive such as ethylene copolymer; a polyester comprising a carboxylic acid component such as dimethyl terephthalate, dimethyl isophthalate or dimethyl phthalate and a polyhydric alcohol component such as ethylene glycol. Ether-based pressure-sensitive adhesives, and the like. These pressure-sensitive adhesives may be used alone or in combination of two or more.

  In addition, “weak adhesive (18)” and “strong adhesive (16)” described in Example 4 described later are “weak adhesive layer (32)” and “strong adhesive layer (34)”. Is synonymous with.

  Hereinafter, the present invention will be described more specifically with reference to examples. However, the present invention is not limited to the following examples.

Example 1 Microneedle Insertion Test Using a Cylindrical Insertion Aid Device
The microneedles (12 × 12, 7 mm × 7 mm square chips) of Reference Example 1 described later were fixed to the plate (2) of the auxiliary device shown in FIG. 1 with double-sided tape. A 7-week-old nude rat was anesthetized, and the insertion aid of FIG. 1 was pressed against its abdomen or thigh. As for the insertion assisting device, a thumb was placed on the plate-like piece (5) at the top of the piston (3), and the cylinder was held with the remaining fingers. When strongly pressed, the rat skin in the cylinder rises slightly, but even if the cylinder is moved slightly, it moves in synchronization with it, so it is relatively fixed to the microneedle.

  When the plate-like piece (5) on the upper part of the piston (3) is pressurized with the thumb, the microneedle (1) moves to the skin of the rat and is crimped. After press-fitting to the skin for about 5 seconds, the piston (3) was pulled up, and the state of insertion into the rat's skin and the state of damage to the microneedles of the microneedles were confirmed. In addition, since the state which inserted the blue pigment | dye (gentian violet solution) on the surface of a microneedle is used for the insertion condition in skin, a blue pigment | dye remains in the location where skin was punctured with the microneedle. Therefore, the efficiency of the insertion into the skin is clearly shown by looking at the dyeing state of the rat skin after the microneedle is crimped. Further, the microneedle damage state is clearly shown by comparing microscopic photographs of the microneedles before and after pressure bonding.

Table 1 shows the results of the insertion into the rat skin and the microneedle damage situation of the microneedle. As a result, when the insertion assisting instrument is used, the microneedles can easily enter the skin vertically due to the following effects 1) to 3), thereby improving the durability of the microneedles and inserting the microneedles into the skin without breaking. It became clear.
1) Improvement of vertical approachability (vertical mobility) by the cylindrical member included in the plate.
2) Axial fixation of the microneedle by fixing the microneedle using a plate and maintaining the perpendicularity of the microneedle to the skin.
3) Fixing the movement of the skin surface surrounded by the cylindrical member by pressing the cylindrical member against the skin.

(Example 2: Microneedle insertion test using pantograph-type insertion assisting device)
As the insertion aid for the microneedle, the one shown in FIG. 7 ((a) to (c)) was used, and the insertion device was placed on the abdomen of the nude rat in the same manner as in Example 1. Under pressure, the microneedle was crimped and inserted into the abdomen of the rat. The result showed a good insertion situation similar to Example 1, and the damage situation of the microneedles did not change significantly.

(Example 3: Influence test of deviation between axial direction of microneedle and moving direction of plate)
A sheet (13) having an inclination of 5 degrees or 10 degrees was attached to a plate (2) of a cylindrical auxiliary device (FIG. 13), and the microneedle (1) was fixed thereon.
In the same manner as in Example 1, the insertion device was placed on the abdomen of a nude rat, pressurized with a finger, and a microneedle was crimped and inserted into the abdomen of the rat. The results are shown in Table 2 below.
According to this result, it was shown that most of the microneedles did not pierce the skin and the portion where the load was applied was bent due to the deviation of 5 degrees.

(Example 4: Microneedle retention test on skin)
The microneedle (1) of Reference Example 1 described later is held on the skin application cloth (17) with a strong adhesive (16), and the cloth (17) is weakly applied to the plate (2) of the cylindrical insertion aid. It was fixed to with an adhesive (18). The situation is shown in FIG.

  In the same manner as in Example 1, the auxiliary device shown in FIG. 1 was placed on the abdomen of the nude rat, pressurized with a finger, and the microneedle was crimped and inserted into the abdomen of the rat. After insertion, the microneedle was held on the rat abdomen together with the skin patching cloth. The same procedure was performed on the inner side of the human upper arm. After insertion, the microneedle was held on the skin on the inner side of the human upper arm together with the skin application cloth.

(Reference Example 1: Production of microneedle)
Silicon microneedles (a jig in which 12 × 12 microneedles having a square column shape with a side of 100 μm and a length of 300 μm are arranged in an array on a square substrate part with a plane of 7 mm length × 7 mm width) ) Is placed on a hot plate and heated at 80 ° C.
A sheet of polylactic acid (Mw: 10,000) is placed downward on the support of a Shimadzu rheometer (EZ-TEST), the support is pulled down, the jig is brought into contact with the sheet, and held at that position for 5 seconds. Then, the support | pillar was pulled up upwards at the speed | rate of 5 mm / min.
When the resin sheet was pulled up, a resin microarray (microneedle) having needle-like protrusions (microneedles) having a length of approximately 300 μm was obtained.

Industrial applicability

  The auxiliary device for inserting the microneedle of the present invention into the skin can be expected to be used as an auxiliary device for applying a so-called patch preparation in which an adhesive tape or an adhesive layer of a sheet contains a drug.

  This application is based on Japanese Patent Application No. 2008-051335 filed in Japan, the contents of which are incorporated in full herein.

Claims (8)

One side is a fixed surface of the microneedle (1), and the other side is a plate (2) in which a piston (3) is erected;
A cylindrical member (4) for loosely fitting and holding the plate (2) therein, the end surface on one side in the axial direction being pressed against the skin surface ;
A protrusion (11) provided on the side surface of the piston (3) and capable of contacting the inner surface of the cylindrical member (4) and / or a plate (2) provided on the inner surface of the cylindrical member (4) A rail-like guide (12) that engages with
The piston (3) is pressurized with a finger,
When the piston (3) is pressurized with a finger, the plate (2) moves in the axial direction of the microneedle (1) fixed to the fixed surface of the plate (2) . Auxiliary device for insertion into the. The end surface of the axial one side of the tubular member (4) is a surface of the tubular member flange formed at the end portion in the axial direction one side of (4) (4 '), the auxiliary of claim 1 Symbol placement Instruments. Plate one-sided to the low adhesive agent (2) (18) skin patch cloth bonded via a strong adhesive agent (17) (16) microneedles (1) through a is fixed, claims Auxiliary device according to 1 or 2 . Microneedles (1), the plate (2) adhesion of the microneedles (1) side is fixed to the plate (2) via a weak double-sided adhesive tape (6) than the side, according to claim 1 or 2, wherein Auxiliary equipment. A double-sided adhesive tape (6) having a lower adhesive strength on the microneedle (1) side than the plate (2) side covers the entire surface of the plate (2), and the microneedle (1) is interposed via the double-sided adhesive tape (6). The auxiliary device according to claim 1 or 2 , wherein the auxiliary device is fixed to the plate (2). The adhesive tape (6) having an adhesive surface only on one side on the microneedle side is held on one side of the plate (2), and the microneedle (1) is fixed to the adhesive tape (6). Auxiliary device according to 1 or 2 . The auxiliary device according to any one of claims 1 to 6 , wherein the microneedles (1) are biodegradable resin microneedles or polysaccharide microneedles. Microneedles (1) is a drug-containing microneedle aid according to any one of claims 1-6.