JPWO2015115420A1 - applicator - Google Patents

Abstract

An applicator according to an embodiment has a support surface that supports an inclined microneedle, and the support surface is rotated in the direction of the tip of the microneedle before and after the microneedle pierces the skin, and the movement range is limited. Rotation mechanism.

Description

  One aspect of the present invention relates to an applicator used to assist in the administration of an active ingredient.

  Conventionally, a microneedle for administering an active ingredient through the skin and a device including the microneedle are known. For example, the following Patent Document 1 describes an apparatus including a micro intruder generated by punching a series of protrusions on the surface of a thin sheet. The following Patent Document 2 describes an apparatus having a sheet member provided with a plurality of minute protrusions.

  A technique of puncturing a microneedle into the skin after stretching the skin is also known. For example, Patent Document 3 below describes that the device positioned on the skin is pressed downward, and the stretching device stretches the skin in the target area of the skin penetrating member, thereby enabling even skin penetration. ing. In the following Patent Document 4, by moving these extension parts so as to separate the two internal extension parts, the skin is stretched and then the microprojections are inserted into the skin, and then the extension parts are further moved. It is described that the microprojections cut the skin. Patent Document 5 listed below describes a technique for extending a skin by pushing an extensible cone toward the skin and then puncturing the skin with a microneedle disposed in the cone.

Japanese translation of PCT publication No. 2002-510982 Special table 2001-525231 gazette Special table 2003-534881 gazette US Patent No. 7087035 US Pat. No. 6,743,211

  If the force transmitted to the microneedle is affected by the user's force when performing puncture after deforming the skin, the degree of puncture will vary from user to user, resulting in reproducibility of puncture. There is a possibility of lowering. Therefore, no matter who uses it, it is required to maintain the degree of puncture of the microneedle at a certain level, that is, to improve puncture reproducibility.

  An applicator according to an aspect of the present invention includes a support surface that supports an inclined microneedle, a support surface that rotates in the direction of the tip of the microneedle before and after the microneedle pierces the skin, and has a range of movement. And a restricted rotation mechanism.

  In such a side surface, when the support surface rotates, the inclined microneedle deforms the skin by a certain range and then pierces the skin. Since the rotation mechanism for rotating the support surface has a limited movement range, the rotation range of the support surface can be made the same regardless of who operates the applicator. Therefore, the puncture degree of the microneedle can be kept at a certain level regardless of who uses it.

  According to one aspect of the present invention, the puncture degree of the microneedle can be maintained at a certain level regardless of who is using it.

It is a perspective view of the microneedle device used with the applicator which concerns on each embodiment. It is a perspective view of the applicator which concerns on 1st Embodiment. It is a top view, a side view, and a bottom view of the applicator according to the first embodiment. It is the IV-IV sectional view taken on the line of FIG. It is a perspective view which shows the mode of an action | operation of the applicator shown in FIG. It is a perspective view of the applicator which concerns on 2nd Embodiment. It is a perspective view of the applicator which concerns on 3rd Embodiment. It is a perspective view of the applicator which concerns on 4th Embodiment. It is a perspective view of the applicator which concerns on 5th Embodiment. It is a perspective view of the applicator which concerns on 6th Embodiment. It is a perspective view of the applicator which concerns on the modification of 6th Embodiment.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same or equivalent elements are denoted by the same reference numerals, and redundant description is omitted.

  An applicator is an auxiliary device used when a microneedle device for administering an arbitrary active ingredient (for example, a drug) into a living body is applied to the skin. Several aspects of the applicator are shown below, but the following description assumes that any applicator is used with the microneedle device 1 shown in FIG.

  The microneedle device 1 is an instrument for transdermally administering an active ingredient by puncturing the skin. The microneedle device 1 is completed by punching a sheet 20 to form a large number of microneedles 11 and raising the microneedles 11 obliquely from the sheet surface.

  The shape of the sheet 20 (that is, the overall shape of the microneedle device 1) is not limited, and may be a circle, an ellipse, a rectangle, a pentagon, a hexagon, a star, or any other polygonal shape, or other than these. The shape may be acceptable. The sheet 20 shown in FIG. 1 is circular.

  As shown in FIG. 1, all the microneedles 11 are raised on one surface side of the sheet 20, and this surface is indicated as a main surface 20a in this specification. The angle formed between each microneedle 11 and the main surface 20a (that is, the inclination angle) may be any number as long as it is an acute angle. By setting the angle to an acute angle, each microneedle 11 is inclined with respect to the main surface 20a. The main surface 20a is a surface facing the skin when the microneedle device 1 is used. The back surface (not shown) of the sheet 20 is the back surface of the main surface 20a and is a surface that a part of the applicator touches when the microneedle device 1 is used.

  In this specification, a group of the plurality of formed microneedles 11 is shown as a microneedle array 10. It can be said that the microneedle array 10 is a set of a plurality of rows 12 each extending along the radial direction of the sheet 20. Each row 12 is composed of a plurality of microneedles 11. Of course, the microneedle array 10 is part of the microneedle device 1.

  The material of the sheet 20 and the microneedle 11 is not limited. For example, the sheet 20 and the microneedle 11 may be made of any of stainless steel, polyethylene terephthalate (PET), other metals, other resins, biodegradable materials, ceramics, or bioabsorbable materials. Or you may produce the sheet | seat 20 and the microneedle 11 combining these materials.

  The microneedle array 10 can be formed by etching. If the sheet is a metal, a number of microneedles 11 can be formed by punching the sheet with a chemical solution, and the microneedle array 10 can be formed by raising the microneedles in an oblique direction. If the sheet is non-metallic, a large number of microneedles 11 are formed by punching the sheet with a laser, and the microneedles 11 may be raised as in the case of a metal sheet. When etching is used as described above, a gap is generated around each microneedle 11. Of course, the microneedle array 10 may be formed by any method other than etching.

  The dimension of the sheet 20 is not limited, and may be arbitrarily set according to the purpose of use or the use site. For example, the lower limit of the diameter of the sheet 20 is determined in consideration of the dose of the active ingredient, and the upper limit of the diameter is determined in consideration of the size of the living body. For example, the lower limit of the diameter may be 0.1 cm or 1 cm, and the upper limit of the diameter may be 60 cm, 50 cm, 30 cm, or 20 cm. In this embodiment, since the microneedles 11 are formed by punching the sheet 20, the thickness of the sheet 20 is determined in consideration of the puncture performance of the microneedles 11. For example, the lower limit of the thickness may be 5 μm or 20 μm, and the upper limit of the thickness may be 1000 μm or 300 μm.

The parameters related to the microneedle 11 are not limited. For example, the lower limit of the height of the microneedle 11 may be 10 μm or 100 μm, and the upper limit of the height may be 10,000 μm or 1000 μm. As described above, in the present embodiment, the thickness of the microneedle 11 depends on the thickness of the sheet 20. The lower limit of the density of the microneedles 11 may be 0.05 / cm ² or 1 / cm ² , and the upper limit of the density may be 10,000 / cm ² or 5000 / cm ² . The lower limit of density is a value converted from the number and area of needles to which 1 mg of active ingredient can be administered, and the upper limit of density is a limit value in consideration of the shape of the needle.

  When the entire microneedle array 10 is viewed, the direction in which all the microneedles 11 face is unified in the clockwise direction or the counterclockwise direction. In the example of FIG. 1, when the microneedle device 1 is viewed from the main surface 20a side, each microneedle 11 faces in the counterclockwise direction. When the microneedle device 1 is viewed from the back side, each microneedle 11 is directed in the clockwise direction as a whole.

  Next, several embodiments of an applicator for assisting the use of the microneedle device 1 will be described.

(First embodiment)
The applicator 30 according to the first embodiment will be described with reference to FIGS. FIG. 2 is a perspective view of the applicator 30. FIG. 3 is a plan view, a side view, and a bottom view of the applicator 30. Appearance of the applicator 30 from the front, back, and both sides is the same. Therefore, the side view shown in FIG. 3 is a front view, a rear view, a right side view, and a left side view. 4 is a sectional view taken along line IV-IV in FIG. FIG. 5 is a perspective view showing the operation of the applicator. 2 and 5, the applicator 30 is shown so that a cross section of a connecting portion 33 described later can be seen.

  The applicator 30 includes a support plate 31 that supports the microneedle device 1, an outer frame 32 that surrounds the outer periphery of the support plate 31, and a plurality of connection portions 33 that connect the support plate 31 and the outer frame 32. The overall shape of the applicator 30 and the shape of at least some of the components of the applicator 30 may be determined according to the shape of the microneedle device 1. For example, the overall shape of the applicator 30 may be a circle, an ellipse, a rectangle, a pentagon, a hexagon, a star, or any other polygon, or other shapes. In the present embodiment, the applicator 30 has a circular or disk shape as a whole.

  The material of the applicator 30 is not limited. For example, the applicator 30 may be manufactured using a synthetic or natural resin material such as ABS resin, polystyrene, polypropylene, or polyacetal (POM). Alternatively, the applicator 30 may be manufactured using silicon, silicon dioxide, ceramic, or metal (stainless steel, titanium, nickel, molybdenum, chromium, cobalt, or the like).

  The support plate 31 is a plate material on which the microneedle device 1 is located on the back surface 31a. In the present embodiment, the support plate 31 is circular according to the shape of the microneedle device 1, but as described above, the shape of the support plate 31 is not limited. The back surface 31a of the support plate 31 is a surface facing the skin of the user of the microneedle device 1 when the applicator 30 is used, and is a surface represented in the bottom view in FIG.

  In this embodiment, the back surface 31a side of the support plate 31 is defined as the lower side of the applicator 30, and the surface 31b side of the support plate 31 that is the surface opposite to the back surface 31a (see the plan view of FIG. 3). Reference) is defined as the upper side of the applicator 30.

  The outer frame 32 is a component that surrounds the outer periphery of the support plate 31. In the present embodiment, the outer frame 32 has a ring shape in accordance with the shape of the support plate 31, but the shape of the outer frame 32 is not limited to this. For example, the shape of the outer frame 32 may be determined according to the contour of the support plate 31. Alternatively, it may be determined regardless of the outline of the support plate 31. For example, a rectangular outer frame 32 may be adopted for the circular support plate 31.

  The connecting portion 33 is a component that connects the outer peripheral portion of the support plate 31 and the inner peripheral portion of the outer frame 32, and plays a role as a rotating mechanism. The “rotation mechanism” in the present specification is a mechanism for rotating the support plate 31 in the direction of the tip of the microneedle 11 before and after the microneedle 11 is stuck in the skin. The connecting portions 33 are provided at predetermined intervals along the outer periphery of the support plate 31. In the example of FIGS. 2 to 5, the applicator 30 includes five connection parts 33, but the number of connection parts 33 is not limited to this, and may be any number of two or more.

  The individual connection portions 33 are provided so as to extend along the tangential direction of the outer periphery of the support plate 31. One end of the connecting portion 33 is connected to the outer peripheral portion of the support plate 31, and the other end of the connecting portion 33 is connected to the inner peripheral portion of the outer frame 32. The connecting portion 33 has a mountain fold 33a and a valley fold 33b. The length between the mountain-folded portion 33a and the valley-folded portion 33b in each connecting portion 33 is set so that the connecting portion 33 can be bent even after the support plate 31 contacts the skin. The mountain-folded portion 33a closer to the outer frame 32 is formed by cutting the upper surface of the connecting portion 33 along a direction substantially orthogonal to the longitudinal direction of the connecting portion 33 (that is, the width direction of the connecting portion 33). The On the other hand, the valley fold portion 33 b closer to the support plate 31 is formed by making a cut in the lower surface of the connection portion 33 along the width direction of the connection portion 33.

  Prior to the operation of the applicator 30, the mountain-folded portion 33 a and the valley-folded portion 33 b are not folded, and therefore the individual connecting portions 33 extend so as to be parallel to the surface of the support plate 31. When the applicator 30 is operated, the connecting portion 33 is in the state shown in FIG. That is, when the applicator 30 is operated, the mountain fold portion 33 a is folded so that the fold is relatively directed to the upper side of the applicator 30, and the valley fold portion 33 b is relatively folded to the lower side of the applicator 30. Fold like so. Therefore, when the applicator 30 is viewed from the side when the applicator 30 is operated, the connection portion 33 bends as if forming a mountain at the mountain fold portion 33a, and the connection portion at the valley fold portion 33b. 33 appears to be bent to form a valley. As described above, the connecting portion 33 that extends linearly before the operation (see FIG. 2) is deformed to have a step shape after the operation (see FIG. 5). When the connecting portion 33 has a step shape, the end portion of the connecting portion 33 connected to the inner peripheral portion of the outer frame 32 is higher than the end portion of the connecting portion 33 connected to the outer periphery of the support plate 31. Or the state in a low position. In the example of FIG. 5, the end connected to the inner periphery of the outer frame 32 is at a higher position than the end connected to the outer periphery of the support plate 31.

  Next, how to use the applicator 30 and the microneedle device 1 will be described. First, the user attaches the back surface of the microneedle device 1 to the back surface 31 a of the support plate 31. For this attachment, an adhesive layer may be provided on at least one of the back surface of the microneedle device 1 and the back surface 31 a of the support plate 31. When the microneedle device 1 is attached to the back surface 31a of the support plate 31, the inclined microneedle 11 is supported by the back surface 31a. Therefore, the back surface 31 a functions as a support surface for the microneedle 11.

  Subsequently, the user places the applicator 30 where the active ingredient is applied. At this time, an adhesive layer may be provided on the lower surface of the outer frame 32 in order to fix the applicator 30 to the application location. Next, the user pushes the surface 31b of the support plate 31 toward the skin. Then, the mountain-folded portion 33a and the valley-folded portion 33b of each connection portion 33 are bent, and the support plate 31 (support surface) is lowered toward the skin while rotating in either the clockwise direction or the counterclockwise direction. Since the microneedle device 1 is attached to the support plate 31, the microneedle device 1 is lowered toward the skin while the microneedle device 1 is rotated.

  The length between the mountain-folded portion 33a and the valley-folded portion 33b in each connecting portion 33 is set so that the support plate 31 rotates even after the microneedle 11 comes into contact with the skin. When the connection portion 33 set in this way is deformed in a step shape as shown in FIG. 5, the microneedle device 1 attached to the support plate 31 also continues to fall toward the skin while rotating. As a result, each microneedle 11 is stuck into the skin while rotating and moving along the surface of the skin. At this time, each microneedle 11 stretches or contracts the skin between the time when it hits the skin and the time when it penetrates the skin. Accordingly, each microneedle 11 pierces the skin while deforming the skin by itself. Instead of removing the microneedle device 1 from the skin immediately after the puncture, the user may keep pressing the microneedle device 1 with a hand or an auxiliary tool such as a tape while maintaining the puncture state for a predetermined time.

  Since the moving range of each connecting portion 33 (the angle at which the mountain fold portion 33a and the valley fold portion 33b are bent) is limited, the rotation angle of the support plate 31 is also limited. The rotation angle may be set to an arbitrary value by considering the material of the connection portion 33 or adjusting the cuts in the mountain fold portion 33a and the valley fold portion 33b.

  The depth of puncture can be controlled by increasing the thickness of the support plate 31 toward the skin or by inserting a spacer between the support plate 31 and the microneedle device 1. By thickening the support plate 31 or the spacer, the microneedle 11 can be deeply punctured by bringing the microneedle 11 into contact with the skin immediately after the support plate 31 starts to rotate.

  In addition, the preparation method of an active ingredient is not limited. For example, the active ingredient may be previously applied to the microneedles 11. Alternatively, the user may first apply the active ingredient to the skin and then apply the microneedle device 1 to the skin using the applicator 30 in the manner described above. Alternatively, the user may first apply the microneedle device 1 to the skin using the applicator 30 by the method described above, and then apply the active ingredient to the application site.

  As described above, according to the present embodiment, when the support surface (the back surface 31a of the support plate 31) rotates, the inclined microneedle 11 deforms the skin by a certain range and then pierces the skin. . Since the range of movement of the connecting portion 33 that rotates the support surface is limited, the rotation range of the support surface can be made the same regardless of who operates the applicator 30. Therefore, the puncture degree of the microneedle 11 can be maintained at a certain level regardless of who uses it.

  Moreover, according to this embodiment, since nothing is provided in the upper part of the support plate 31 which fixes the microneedle device 1, the height of the applicator 30 can be suppressed.

  Further, according to the present embodiment, the user can stab the skin while turning each microneedle 11 simply by pressing the support plate 31. That is, the usage method of the applicator 30 is very simple.

(Second Embodiment)
With reference to FIG. 6, the applicator 30A according to the second embodiment will be described. FIG. 6 is a perspective view of the applicator 30A. In addition, in FIG. 6, applicator 30A is shown so that the cross section of the connection part 34 mentioned later may be understood.

  The applicator 30A is a modification of the applicator 30 in the first embodiment, and includes a support plate 31, an outer frame 32, and a connection portion. That is, the difference between the applicator 30A and the applicator 30 is the structure of the connecting portion. The point that the overall shape of the applicator 30, the shape of the support plate 31, and the shape of the outer frame 32 are not limited are the same as in the first embodiment. Below, the connection part 34 is demonstrated in detail, and description is abbreviate | omitted about the same support plate 31 and outer frame 32 as 1st Embodiment.

  The connecting portion 34 is a component that connects the outer peripheral portion of the support plate 31 and the inner peripheral portion of the outer frame 32, and serves as a rotating mechanism. The connecting portions 34 are provided at predetermined intervals along the outer periphery of the support plate 31. In the example of FIG. 6, the applicator 30 includes six connection portions 34, but the number of connection portions 34 is not limited to this, and may be any number greater than or equal to two.

  The individual connection portions 34 are provided so as to extend along the tangential direction of the outer periphery of the support plate 31. One end of the connecting portion 34 is connected to the outer peripheral portion of the support plate 31, and the other end of the connecting portion 34 is connected to the inner peripheral portion of the outer frame 32. The connecting portion 34 has a mountain fold portion 34a and a valley fold portion 34b. The position of the support plate 31 in the height direction of the applicator 30A is adjusted in advance so that the connection portion 34 can be bent even after the support plate 31 contacts the skin.

  As shown in FIG. 6, before the operation of the applicator 30A, the mountain fold portion 34a is folded so that the fold is relatively directed toward the upper side of the applicator 30, and the valley fold portion 34b is relatively folded. It is bent so that it may go to the lower side of the T30. Therefore, when the applicator 30A is viewed from the side before the operation of the applicator 30A, the connection portion 34 bends as if forming a mountain at the mountain fold portion 34a, and the connection at the valley fold portion 34b. The part 34 appears to be bent so as to form a valley. When the applicator 30A is operated, the bending angles at the mountain folds 34a and the valley folds 34b are both reduced, and finally the individual connection parts 34 are substantially parallel to the main surface of the support plate 31. It will be in the state extended to. As described above, the connecting portion 34 having a step shape before the operation is deformed so as to extend linearly after the operation.

  The user can stab the microneedle 11 in the skin by using the applicator 30A as in the case of the applicator 30 in the first embodiment. This embodiment is different from the first embodiment only in the mode of deformation of the connecting portion when the user presses the surface of the support plate 31 toward the skin. In the first embodiment, the connecting portion 33 extending in a straight line is deformed in a step shape, so that the support plate 31 (support surface) is lowered toward the skin while rotating, and each microneedle 11 is placed on the surface of the skin. Stings into the skin while rotating along. On the other hand, in the present embodiment, the connecting portion 33 having a step shape is deformed so as to extend in a straight line, so that the support plate 31 is lowered toward the skin while rotating, and each microneedle 11 is moved to the skin. Stings into the skin while rotating along the surface.

  As described above, the same effects as those of the first embodiment can be obtained in this embodiment. That is, since the range of movement of the connecting portion 34 that rotates the support surface (the back surface 31a of the support plate 31) is limited, the rotation range of the support surface can be made the same regardless of who operates the applicator 30A. Therefore, the puncture degree of the microneedle 11 can be maintained at a certain level regardless of who uses it. Moreover, since nothing is provided in the upper part of the support plate 31 which fixes the microneedle device 1, the height of the applicator 30 can be suppressed. Further, the user can turn each microneedle 11 by a simple operation of simply pressing the support plate 31.

(Third embodiment)
With reference to FIG. 7, the applicator 40 which concerns on 3rd Embodiment is demonstrated. FIG. 7 is a perspective view of the applicator 40.

  The applicator 40 includes a support plate 41 that supports the microneedle device 1, two knobs 42 attached to the support plate 41, and a housing 43 that houses the support plate 41. The overall shape of the applicator 40 and the shape of at least some of the components of the applicator 40 may be determined according to the shape of the microneedle device 1. For example, the overall shape of the applicator 40 may be a circle, an ellipse, a rectangle, a pentagon, a hexagon, a star, or any other polygon, or other shapes. In the present embodiment, the applicator 40 has a disk shape as a whole.

  The material of the applicator 40 is not limited. For example, the applicator 40 may be manufactured using a synthetic or natural resin material such as ABS resin, polystyrene, polypropylene, or polyacetal (POM). Alternatively, the applicator 40 may be manufactured using silicon, silicon dioxide, ceramic, or metal (stainless steel, titanium, nickel, molybdenum, chromium, cobalt, or the like).

  The support plate 41 is a plate material on which the microneedle device 1 is located on the back surface. In the present embodiment, the support plate 41 is circular according to the shape of the microneedle device 1, but as described above, the shape of the support plate 41 is not limited. The back surface of the support plate 41 is a surface that faces the skin of the user of the microneedle device 1 when the applicator 40 is used. The back surface of the support plate 41 is exposed without being covered with the housing 43. In FIG. 7, only the outer edge of the support plate 41 is shown in a simplified manner.

  In this embodiment, the back surface side of the support plate 41 is defined as the lower side of the applicator 40, and the surface side of the support plate 41 that is the surface opposite to the back surface is defined as the upper side of the applicator 40.

  Two knobs 42 are provided on the upper surface (the surface opposite to the back surface) of the support plate 41. The two knobs 42 are provided on the support plate 41 at an interval of 180 degrees along the outer periphery of the support plate 41. In the present embodiment, the knob 42 serves as a rotation mechanism. The number of knobs 42 is not limited, and any number of knobs 42 may be provided as long as the user can easily turn the knob 42 by hand. In the present embodiment, the cross-sectional shape of the knob 42 parallel to the support plate 41 is a shape like an arrow in order to indicate the rotation direction of the support plate 41, but the cross-sectional shape is not limited.

  Two holes 43 a corresponding to the two knobs 42 are formed on the upper surface of the housing 43. Each knob 42 protrudes upward from the corresponding hole 43a. Each hole 43a is formed in consideration of the rotation angle of the support plate 41 necessary for piercing the microneedles 11 into the skin.

  Next, how to use the applicator 40 and the microneedle device 1 will be described. First, the user attaches the back surface of the microneedle device 1 to the back surface of the support plate 41. For this attachment, an adhesive layer may be provided on at least one of the back surface of the microneedle device 1 and the back surface of the support plate 41. When the microneedle device 1 is attached to the back surface of the support plate 41, the inclined microneedle 11 is supported by the back surface. Therefore, the back surface of the support plate 41 functions as a support surface for the microneedles 11.

  Subsequently, the user places the applicator 40 where the active ingredient is applied. At this time, an adhesive layer may be provided on the lower surface of the housing 43 in order to fix the applicator 40 to the application location. Next, the user turns the two knobs 42 along the circumferential direction of the casing 43 (in the example of FIG. 7, the counterclockwise direction when viewed from above the applicator 40) while holding the casing 43. Note that the user may turn the knob 42 using power such as a spring or a motor instead of a hand. When the knob 42 rotates, the microneedle device 1 attached to the support plate 41 also rotates, and each microneedle 11 pierces the skin while rotating along the surface of the skin. In this embodiment, since the support plate 41 does not move along the vertical direction (that is, the vertical direction) of the applicator 40, the support plate 41 (support surface) rotates without being lowered toward the skin. At this time, each microneedle 11 stretches or contracts the skin between the time when it hits the skin and the time when it penetrates the skin. Accordingly, each microneedle 11 pierces the skin while deforming the skin by itself. Since the movement range of the two knobs 42 is limited by the hole 43a (in other words, the moving knob 42 stops at the edge of the hole 43a), the rotation angle of the support plate 41 is also limited.

  Instead of removing the microneedle device 1 from the skin immediately after the puncture, the user may keep pressing the microneedle device 1 with a hand or an auxiliary tool such as a tape while maintaining the puncture state for a predetermined time. In addition, the preparation method of an active ingredient is not limited like 1st and 2nd embodiment.

  As described above, according to the present embodiment, when the support surface (the back surface of the support plate 41) rotates, the inclined microneedles 11 deform the skin by a certain range and then pierce the skin. Since the movement range of the knob 42 for rotating the support surface is limited, the rotation range of the support surface can be made the same regardless of who operates the applicator 40. Therefore, the puncture degree of the microneedle 11 can be maintained at a certain level regardless of who uses it.

  Moreover, according to this embodiment, the microneedle 11 can be stabbed into skin with the simple mechanism of turning the knob 42 attached to the support plate 41.

  In this embodiment, the knob 42 is provided on the upper surface of the support plate 41, but the position of the knob is not limited as long as the support plate can be rotated. For example, the knob may be provided on the side surface of the support plate. In this modification, the hole corresponding to the knob is formed on the side surface of the housing.

(Fourth embodiment)
With reference to FIG. 8, the applicator 50 which concerns on 4th Embodiment is demonstrated. FIG. 8 is a perspective view of the applicator 50.

  The applicator 50 includes a support plate 51 that supports the microneedle device 1, a plurality of small claws 52 and two protrusions 53 provided on the support plate 51, and a housing that houses the support plate 51 and the claws 52. 54 and a switch 55 that covers the central portion of the support plate 51. The overall shape of the applicator 50 and the shape of at least some of the components of the applicator 50 may be determined according to the shape of the microneedle device 1. For example, the overall shape of the applicator 50 may be a circle, an ellipse, a rectangle, a pentagon, a hexagon, a star, or any other polygon, or other shapes. In the present embodiment, the applicator 50 has a disk shape as a whole.

  The material of the applicator 50 is not limited. For example, the applicator 50 may be manufactured using a synthetic or natural resin material such as ABS resin, polystyrene, polypropylene, or polyacetal (POM). Alternatively, the applicator 50 may be manufactured using silicon, silicon dioxide, ceramic, or metal (stainless steel, titanium, nickel, molybdenum, chromium, cobalt, or the like).

  The support plate 51 is a plate material on which the microneedle device 1 is located on the back surface. In the present embodiment, the support plate 51 is circular according to the shape of the microneedle device 1, but as described above, the shape of the support plate 51 is not limited. The back surface of the support plate 51 is a surface that faces the skin of the user of the microneedle device 1 when the applicator 50 is used. The back surface of the support plate 51 is exposed without being covered with the housing 54. In FIG. 8, only the outer edge of the support plate 51 is shown in a simplified manner.

  In this embodiment, the back surface side of the support plate 51 is defined as the lower side of the applicator 50, and the surface side of the support plate 51 that is the surface opposite to the back surface is defined as the upper side of the applicator 50.

  A plurality of claws 52 are provided in the vicinity of the center of the upper surface (surface opposite to the back surface) of the support plate 51. The number of claws 52 is not limited. Each claw 52 is substantially triangular. When the applicator 50 is viewed from above, the surface 52 a of the claw 52 that faces clockwise or counterclockwise is inclined with respect to the upper surface of the support plate 51. That is, each claw 52 has an inclined surface 52a. In the example of FIG. 8, the inclined surface 52 a faces in the clockwise direction when the applicator 50 is viewed from above. The shape of the nail is not limited to a triangle, and any shape of nail may be adopted as long as the inclined surface is formed.

  The two protrusions 53 are provided on the support plate 51 with an interval of 180 degrees along the outer periphery of the support plate 51.

  A central hole for providing a switch 55 to be described later and two holes 54 a corresponding to the two protruding portions 53 are formed in the central portion of the upper surface of the housing 54. Each protrusion 53 protrudes upward from the corresponding hole 54a.

  The switch 55 has a substantially cylindrical shape. A plurality of outer ribs 55 a are formed on the outer wall of the switch 55, and a plurality of inner ribs 55 b corresponding to the plurality of claws 52 are formed on the inner wall of the switch 55. The number of outer ribs 55a and inner ribs 55b is not limited, but the number of inner ribs 55b is the same as the number of claws 52. The outer rib 55 a is a rail-like protrusion that extends along the height direction of the switch 55. By fitting the outer rib 55a into the groove formed in the central hole of the housing 54, the switch 55 does not rotate along the circumferential direction of the applicator 50, but moves only along the height direction of the applicator 50. . The inner rib 55 b is also a rail-like protrusion that extends along the height direction of the switch 55. The switch 55 functions as a rotation mechanism by including the inner rib 55b. The movement of the switch 55 is limited to a range along the height direction of the claw 52.

  Next, how to use the applicator 50 and the microneedle device 1 will be described. First, the user attaches the back surface of the microneedle device 1 to the back surface of the support plate 51. For this attachment, an adhesive layer may be provided on at least one of the back surface of the microneedle device 1 and the back surface of the support plate 51. When the microneedle device 1 is attached to the back surface of the support plate 51, the inclined microneedle 11 is supported by the back surface. Therefore, the back surface of the support plate 51 functions as a support surface for the microneedles 11.

  Subsequently, the user pulls up the switch 55 by moving the protrusion 53 in the circumferential direction, and positions the inner rib 55b on the claw 52 as shown in FIG. Subsequently, the user places the applicator 50 where the active ingredient is applied. At this time, an adhesive layer may be provided on the lower surface of the housing 54 in order to fix the applicator 50 to the application location. Next, the user presses the switch 55 toward the skin. Then, the switch 55 (more specifically, each inner rib 55b) pushes the inclined surface 52a of each claw 52 from above along the height direction of the applicator 50, so that the support plate 51 is circumferential (FIG. 8). In this example, the applicator 50 rotates in the counterclockwise direction when viewed from above. As a result, the microneedle device 1 attached to the support plate 51 rotates, and each microneedle 11 pierces the skin while rotating and moving along the surface of the skin. In this embodiment, since the support plate 51 does not move along the vertical direction (that is, the vertical direction) of the applicator 50, the support plate 51 (support surface) rotates without being lowered toward the skin. At this time, each microneedle 11 stretches or contracts the skin between the time when it hits the skin and the time when it penetrates the skin. Accordingly, each microneedle 11 pierces the skin while deforming the skin by itself. Since the moving range of the switch 55 is limited to the height of the claw 52, the rotation angle of the support plate 51 is also limited.

  Instead of removing the microneedle device 1 from the skin immediately after the puncture, the user may keep pressing the microneedle device 1 with a hand or an auxiliary tool such as a tape while maintaining the puncture state for a predetermined time. In addition, the preparation method of an active ingredient is not limited like 1st-3rd embodiment.

  As described above, according to the present embodiment, when the support surface (the back surface of the support plate 51) rotates, the inclined microneedle 11 deforms the skin by a certain range and then pierces the skin. Since the movement range of the switch 55 that rotates the support surface is limited, the rotation range of the support surface can be made the same regardless of who operates the applicator 50. Therefore, the puncture degree of the microneedle 11 can be maintained at a certain level regardless of who uses it.

  Further, according to this embodiment, the user can stab the skin while turning each microneedle 11 only by pressing the switch 55. That is, the usage method of the applicator 50 is very simple.

(Fifth embodiment)
With reference to FIG. 9, the applicator 60 which concerns on 5th Embodiment is demonstrated. FIG. 9 is a perspective view of the applicator 60.

  The applicator 60 includes a support plate 61 that supports the microneedle device 1 and an outer frame 62 that surrounds the outer periphery of the support plate 61. A plurality of claws 63 are provided on the side surface of the support plate 61. On the other hand, a plurality of grooves 62 a corresponding to the plurality of claws 63 are formed inside the outer frame 62. FIG. 9 shows an applicator 60 having three claws 63 and three grooves 62a, but the number of claws and grooves may be any number as long as it is two or more. For example, the number may be two, four, or six. Similar to the above embodiment, the overall shape of the applicator 60 and the shape of at least some components of the applicator 60 are not limited. Moreover, the point that the material of the applicator 60 is not limited is the same as that of said embodiment.

  The support plate 61 is a plate material on which the microneedle device 1 is located on the back surface. The back surface of the support plate 61 is a surface that faces the skin of the user of the microneedle device 1 when the applicator 60 is used.

  In this embodiment, the back surface side of the support plate 61 is defined as the lower side of the applicator 60, and the surface side of the support plate 61 that is the surface opposite to the back surface is defined as the upper side of the applicator 60.

  The support plate 61 is attached to the outer frame 62 by fitting the respective claws 63 into the corresponding grooves 62a. Each claw 63 is movable along the groove 62a. Each groove 62 a does not extend along the vertical direction of the outer frame 62 but extends obliquely from the top to the bottom of the outer frame 62. The groove 62a may extend linearly, or may have an arc shape that is convex downward (in the direction toward the skin) of the outer frame 62. Accordingly, the support plate 61 rotates only within a predetermined angle range while being lowered (or raised). That is, the claw 63 and the groove 62a serve as a rotation mechanism.

  Next, how to use the applicator 60 and the microneedle device 1 will be described. First, the user attaches the back surface of the microneedle device 1 to the back surface of the support plate 61. For this attachment, an adhesive layer may be provided on at least one of the back surface of the microneedle device 1 and the back surface of the support plate 61. When the microneedle device 1 is attached to the back surface of the support plate 61, the inclined microneedle 11 is supported by the back surface. Therefore, the back surface of the support plate 61 functions as a support surface for the microneedles 11.

  Subsequently, the user places the applicator 60 in a state where the support plate 61 is raised (the state shown in FIG. 9) at the application position of the active ingredient. At this time, an adhesive layer may be provided on the lower surface of the outer frame 62 in order to fix the applicator 60 at the application location. Further, a mechanism for more reliably maintaining the state where the support plate 61 is raised may be provided in the claw 63 or the groove 62a. Next, the user presses the upper surface of the support plate 61 toward the skin while pressing the outer frame 62. Then, each nail | claw 63 falls along the groove | channel 62a, and while the support plate 61 (support surface) rotates in the circumferential direction (the counterclockwise direction seeing from the upper direction of the applicator 60 in the example of FIG. 9), the skin Go down. As a result, the microneedle device 1 attached to the support plate 61 also rotates, and each microneedle 11 pierces the skin while rotating and moving along the surface of the skin. At this time, each microneedle 11 stretches or contracts the skin between the time when it hits the skin and the time when it penetrates the skin. Accordingly, each microneedle 11 pierces the skin while deforming the skin by itself. Since the movement range of the claw 63 is limited by the length of the groove 62a, the rotation angle of the support plate 61 is also limited.

  Similarly to the above embodiment, the user may keep pressing the microneedle device 1 for a predetermined time. Moreover, the point which the preparation method of an active ingredient is not limited is the same as that of said embodiment.

  As described above, according to the present embodiment, when the support surface (the back surface of the support plate 61) rotates, the inclined microneedle 11 deforms the skin by a certain range and then pierces the skin. Since the movement range of the claw 63 for rotating the support surface is limited, the rotation range of the support surface can be made the same regardless of who operates the applicator 60. Therefore, the puncture degree of the microneedle 11 can be maintained at a certain level regardless of who uses it.

  Moreover, according to this embodiment, it is possible to stab the skin while turning each microneedle 11 simply by pressing the support plate 61. That is, the usage method of the applicator 60 is very simple.

  In the present embodiment, the groove 62a extends obliquely, but the shape of the groove formed inside the outer frame is not limited to this. For example, the groove may have a substantially L shape. More specifically, the groove according to this modification includes a vertical portion extending in the vertical direction and a horizontal portion extending in the horizontal direction from the lower end (one end closer to the skin) of the vertical portion. In the case of operating the applicator in this modification, the user first places the nail of the support plate on the upper end (one end away from the skin) of the vertical portion, and first pushes the support plate toward the skin. Then, the microneedle is applied to the skin, and then the support plate is rotated to stab the microneedle into the skin. Thus, the support plate (support surface) rotates only after it has lowered toward the skin. In this modification as well, a mechanism for more reliably maintaining the state where the support plate is raised may be provided in the claw or groove.

(Sixth embodiment)
With reference to FIG. 10, the applicator 70 which concerns on 6th Embodiment is demonstrated. FIG. 10 is a perspective view of the applicator 70.

  The applicator 70 includes a support plate 71 that supports the microneedle device 1, a casing 72 that houses the support plate 71, and a switch 73 that is a rotation mechanism. Similar to the above embodiment, the overall shape of the applicator 70 and the shape of at least some components of the applicator 70 are not limited. Moreover, the point that the material of the applicator 70 is not limited is the same as that of said embodiment.

  The support plate 71 is a plate material on which the microneedle device 1 is located on the back surface. The back surface of the support plate 71 is a surface that faces the skin of the user of the microneedle device 1 when the applicator 70 is used. The back surface of the support plate 71 is exposed without being covered with the casing 72.

  In this embodiment, the back surface side of the support plate 71 is defined as the lower side of the applicator 70, and the surface side of the support plate 71 that is the surface opposite to the back surface is defined as the upper side of the applicator 70.

  Two grooves 74 are formed above the peripheral edge of the support plate 71 with an interval of about 180 °. The groove 74 has a tapered shape that narrows from the outer edge of the support plate 71 toward the center. As an example, in the present embodiment, the groove 74 has a substantially triangular shape. The shape of the switch 73 corresponds to the groove 74 and is therefore a tapered shape that narrows toward the center of the support plate 71. As an example, in this embodiment, the switch 73 is a thin triangular prism. The distal end portion of the switch 73 is inserted into a hole 72 a formed in the side surface of the housing 72 and is positioned in the groove 74. The switch 73 is movable within a predetermined distance along the substantially radial direction of the applicator 70, and therefore the movement of the switch 73 is limited.

  Next, how to use the applicator 70 and the microneedle device 1 will be described. First, the user attaches the back surface of the microneedle device 1 to the back surface of the support plate 71. For this attachment, an adhesive layer may be provided on at least one of the back surface of the microneedle device 1 and the back surface of the support plate 71. When the microneedle device 1 is attached to the back surface of the support plate 71, the inclined microneedle 11 is supported by the back surface. Therefore, the back surface of the support plate 71 functions as a support surface for the microneedles 11.

  Subsequently, the user moves the switch 73 toward the outside of the applicator 70, and brings the wall surface on the rotation direction side of the support plate 71 out of the two wall surfaces of the groove 74 into contact with the switch 73. FIG. 10 shows a state immediately after this operation is performed. Subsequently, the user places the applicator 70 where the active ingredient is applied. At this time, an adhesive layer may be provided on the lower surface of the housing 72 in order to fix the applicator 70 to the application location. Subsequently, the user pushes the switch 73 toward the center of the applicator 70. Then, since the switch 73 pushes the wall surface of the groove 74 toward the circumferential direction of the support plate 71, the support plate 71 rotates in that direction (in the example of FIG. 10, the clockwise direction when viewed from above the applicator 70). To do. As a result, the microneedle device 1 attached to the support plate 71 rotates, and each microneedle 11 pierces the skin while rotating along the surface of the skin. In this embodiment, since the support plate 71 does not move along the vertical direction (that is, the vertical direction) of the applicator 70, the support plate 71 (support surface) rotates without being lowered toward the skin. At this time, each microneedle 11 stretches or contracts the skin between the time when it hits the skin and the time when it penetrates the skin. Accordingly, each microneedle 11 pierces the skin while deforming the skin by itself. Since the movement range of the switch 73 is limited, the rotation angle of the support plate 71 is also limited.

  Similarly to the above embodiment, the user may keep pressing the microneedle device 1 for a predetermined time. Moreover, the point which the preparation method of an active ingredient is not limited is the same as that of said embodiment.

  As described above, according to the present embodiment, when the support surface (the back surface of the support plate 71) rotates, the inclined microneedle 11 deforms the skin by a certain range and then pierces the skin. Since the movement range of the switch 73 for rotating the support surface is limited, the rotation range of the support surface can be made the same regardless of who operates the applicator 70. Therefore, the puncture degree of the microneedle 11 can be maintained at a certain level regardless of who uses it.

  Further, according to the present embodiment, the user can stab the skin while turning each microneedle 11 only by pressing the switch 73. That is, the method of using the applicator 70 is very simple.

  The structure for rotating the support plate by the switch that moves toward the center of the applicator is not limited. For example, in the applicator 70A shown in FIG. 11, the support plate 71A rotates on the same principle as the applicator 70. The applicator 70 </ b> A is different from the applicator 70 in that a rod-like small protrusion 75 is provided instead of the groove 74. The two protrusions 75 are provided on the upper surface of the support plate 71A with an interval of about 180 °. The tip of the switch 73 is placed on the support plate 71A.

  When using the applicator 70A, the user moves the switch 73 toward the outside of the applicator 70A, and brings the protrusion 75 into contact with the side surface of the switch 73 on the rotational direction side. FIG. 11 shows a state immediately after this operation is performed. Thereafter, when the user pushes the switch 73 toward the center of the applicator 70A, the switch 73 pushes the projection 75 toward the circumferential direction of the support plate 71A, so that the support plate 71A moves in that direction (in the example of FIG. (Clockwise direction as viewed from above the top 70A). As a result, the microneedle device 1 attached to the support plate 71A rotates, and each microneedle 11 pierces the skin while rotating and moving along the surface of the skin.

  Although two switches 73 are provided in this embodiment, the applicators 70 and 70A may include only one switch 73. Accordingly, the number of grooves 74 and protrusions 75 may be one.

  As described above, the applicator according to one aspect of the present invention rotates the support surface in the direction of the tip of the microneedle before and after the support surface that supports the inclined microneedle and the microneedle pierces the skin. And a rotation mechanism with a limited movement range.

  In such a side surface, when the support surface rotates, the inclined microneedle deforms the skin by a certain range and then pierces the skin. Since the rotation mechanism for rotating the support surface has a limited movement range, the rotation range of the support surface can be made the same regardless of who operates the applicator. Therefore, the puncture degree of the microneedle can be kept at a certain level regardless of who uses it.

  In the applicator according to another aspect, the support surface may be lowered toward the skin while rotating. By moving the support surface in this manner, the inclined microneedle can be more reliably pierced into the skin.

  The applicator according to another aspect further includes an outer frame that surrounds the outer periphery of the support surface, the rotation mechanism is a plurality of connection portions that connect the outer frame and the outer periphery of the support surface, and each connection portion is a mountain-folded portion And you may have a trough part.

  The applicator according to another aspect further includes an outer frame that surrounds the outer periphery of the support surface, and the rotation mechanism is formed obliquely with a plurality of claws provided at the periphery of the support surface and the inner side of the outer frame. A plurality of extending grooves, and each of the plurality of claws may be fitted in the corresponding groove and movable along the groove.

  In the applicator according to another aspect, the support surface may rotate without being lowered toward the skin. In this case, since it is not necessary to move the support surface in the vertical direction of the applicator (in a direction substantially perpendicular to the skin), the height of the applicator can be suppressed, which further reduces the size of the applicator. To contribute.

  In the applicator according to another aspect, the rotation mechanism may be a knob provided on the support surface.

  In an applicator according to another aspect, a claw having an inclined surface may be provided above the support surface, and the rotation mechanism may be a switch that pushes the claw along a direction orthogonal to the support surface.

  In the applicator according to another aspect, a tapered groove that narrows toward the center of the support surface is formed at the peripheral portion of the support surface, and the rotation mechanism moves toward the center of the support surface to move the groove. A switch that presses the wall surface may be used.

  In the applicator according to another aspect, a protrusion is provided above the support surface, and the rotation mechanism is a switch that moves toward the center of the support surface and pushes the protrusion toward the circumferential direction of the support surface. Good.

  In an applicator according to another aspect, the support surface may rotate after falling toward the skin. In this case, since the step of applying the microneedle to the skin is also performed using the rotation mechanism, the individual difference in the contact of the microneedle with the skin is compared with the case where the user directly applies the microneedle to the skin. Can be small. Therefore, the puncture degree of the microneedle can be kept at a certain level regardless of who uses it.

  The applicator according to another aspect further includes an outer frame that surrounds the outer periphery of the support surface, and the rotation mechanism is formed with a plurality of claws provided at the peripheral edge of the support surface and the inner side of the outer frame. The plurality of claw-shaped grooves may be provided, and each of the plurality of claws may be fitted into the corresponding groove and movable along the groove.

  The present invention has been described in detail based on the embodiments. However, the present invention is not limited to the above embodiment. The present invention can be variously modified without departing from the gist thereof.

  DESCRIPTION OF SYMBOLS 1 ... Microneedle device, 10 ... Microneedle array, 11 ... Microneedle, 20 ... Sheet, 30 ... Applicator, 30A ... Applicator, 31 ... Support plate, 32 ... Outer frame, 33 ... Connection part (rotation mechanism ), 33a ... mountain fold, 33b ... valley fold, 34 ... connection, 34a ... mountain fold, 34b ... valley fold, 40 ... applicator, 41 ... support plate, 42 ... knob (rotation mechanism), 50 ... applicator, 51 ... support plate, 52 ... claw, 52a ... inclined surface, 55 ... switch (rotation mechanism), 55b ... inner rib, 60 ... applicator, 61 ... support plate, 62 ... outer frame, 62a ... groove ( Rotating mechanism), 63 ... Claw (rotating mechanism), 70, 70A ... Applicator, 71, 71A ... Support plate, 72 ... Housing, 73 ... Switch (rotating mechanism), 74 ... Groove, 75 ... Projection.

Claims (11)

A support surface for supporting the inclined microneedles,
An applicator comprising: a rotation mechanism that rotates the support surface in the direction of the tip of the microneedle before and after the microneedle pierces the skin and has a limited movement range. The support surface is lowered toward the skin while rotating;
The applicator according to claim 1. An outer frame surrounding the outer periphery of the support surface;
The rotating mechanism is a plurality of connecting portions that connect the outer frame and the outer peripheral portion of the support surface;
Each connecting portion has a mountain fold and a valley fold,
The applicator according to claim 2. An outer frame surrounding the outer periphery of the support surface;
The rotation mechanism includes a plurality of claws provided on a peripheral edge of the support surface, and a plurality of obliquely extending grooves formed on the inner side of the outer frame,
Each of the plurality of claws fits in the corresponding groove and is movable along the groove.
The applicator according to claim 2. The support surface rotates without lowering towards the skin;
The applicator according to claim 1. The rotation mechanism is a knob provided on the support surface;
The applicator according to claim 5. A claw having an inclined surface is provided above the support surface;
The rotation mechanism is a switch that presses the claw along a direction orthogonal to the support surface.
The applicator according to claim 5. A tapered groove that is narrowed toward the center of the support surface is formed at the periphery of the support surface,
The rotation mechanism is a switch that moves toward the center of the support surface and pushes the wall surface of the groove.
The applicator according to claim 5. A protrusion is provided above the support surface,
The rotation mechanism is a switch that moves toward the center of the support surface and pushes the protrusion toward the circumferential direction of the support surface;
The applicator according to claim 5. The support surface rotates after being lowered toward the skin;
The applicator according to claim 1. An outer frame surrounding the outer periphery of the support surface;
The rotating mechanism includes a plurality of claws provided at a peripheral edge of the support surface, and a plurality of substantially L-shaped grooves formed inside the outer frame,
Each of the plurality of claws fits in the corresponding groove and is movable along the groove.
The applicator according to claim 10.

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