ANTI-HAIR LOSS AND HAIR GROWTH INTEGRATED CORE-SHELL MICRONEEDLE PATCH

Abstract

The present invention discloses an anti-hair loss and hair growth integrated core-shell microneedle patch, comprising a backing and a core-shell microneedle array attached to one side of the backing, the core-shell microneedle array comprises a plurality of microneedles arranged on the backing to form an array, each microneedle comprises a shell substrate material and an internal core, and the shell substrate material is loaded with nano-enzyme for removing excessive active oxygen. The present invention uses an anti-hair loss and hair growth integrated core-shell microneedle patch of the above mentioned structure, wherein the shell substrate material is rapidly degraded after the microneedle patch is applied to the skin, the nano-enzyme loaded by the shell substrate material can be passively released to remove active oxygen and promote angiogenesis in the microenvironment around hair follicles, the internal core of the microneedle is loaded with mesenchymal stem cell-derived exosomes, and the internal exosomes are released and conveyed to hair follicle niches after the shell substrate material is degraded, so that improvement of pigmentation and promotion of hair regrowth are possible.

Claims

1. An anti-hair loss and hair growth integrated core-shell microneedle patch, characterized in that: it comprises a backing and a core-shell microneedle array attached to one side of the backing, the core-shell microneedle array comprises a plurality of microneedles arranged on the backing to form an array, each microneedle comprises a shell substrate material and an internal core, the shell substrate material is loaded with nano-enzyme for removing excessive active oxygen, and the internal core comprises mesenchymal stem cell-derived exosomes; a preparation method of anti-hair loss and hair growth integrated core-shell microneedle patch, comprising the following steps: (1) preparation of a microneedle shell structure: dissolving nano-enzyme in an aqueous solution of the shell substrate material to form a mixture, centrifuging the mixture to remove air and depositing the mixture on a female microneedle mold, then centrifuging the female microneedle mold so that the mixture flows into forming holes of the female microneedle mold, using and pressing a male microneedle mold matched with the female microneedle mold into the female microneedle mold, putting it into a drier for drying at room temperature, and then unloading the male microneedle mold, so that the microneedle shell structure is prepared; the female microneedle mold is a polydimethylsiloxane (PDMS) micromold, the spacing between tips and the tip height of the male microneedle mold are the same as those of the female microneedle mold, and the base area of the female microneedle mold is twice as much as that of the male microneedle mold; (2) preparation of a microneedle core structure: culturing human bone marrow mesenchymal stem cells, isolating the mesenchymal stem cell-derived exosomes from a cell culture medium with an exosome isolation reagent, adding a keratin solution containing cysteine and exosomes into a groove of the microneedle shell structure, removing excessive keratin solution through a plastic scraper, and putting the keratin solution in a drier for drying at room temperature; (3) preparation of the backing: applying a solution containing a backing material to the surface of the bottom end of the microneedle and the upper surface of the female microneedle mold not covered by the microneedle to form backing solution layers, the backing material is crosslinked to form a continuous backing, and finally the microneedle is attached to the backing; (4) preparation of the anti-hair loss and hair growth integrated core-shell microneedle patch: drying and curing the core-shell microneedle array on the backing, and unloading the female microneedle mold to form the anti-hair loss and hair growth integrated core-shell microneedle patch; the anti-hair loss and hair growth integrated core-shell microneedle patch is used to alleviate and treat androgenic hair loss with hair follicle niche imbalance caused by excessive active oxygen and insufficient vascularization of the microenvironment around hair follicles, and used to promote head hair follicle regeneration.

2. The anti-hair loss and hair growth integrated core-shell microneedle patch according to claim 1, characterized in that: the shell substrate material is a soluble polymer and comprises one or more of polyvinyl alcohol, trehalose, hyaluronic acid, polylactic acid, galactose, polyvinylpyrrolidone, polyethylene glycol diacrylate, silk fibroin, methacrylate gelatin and carboxy methyl cellulose.

3. The anti-hair loss and hair growth integrated core-shell microneedle patch according to claim 1, characterized in that: the backing comprises one or more of polyethylene glycol diacrylate, silk fibroin, methacrylate gelatin, carboxy methyl cellulose, trehalose, hyaluronic acid, polylactic acid-glycolic acid copolymer, polylactic acid, galactose, polyvinylpyrrolidone and polyvinyl alcohol.

4. The anti-hair loss and hair growth integrated core-shell microneedle patch according to claim 1, characterized in that: the nano-enzyme comprises one or more of monoatomic nano-enzyme, complex nano-enzyme, catalase-like enzyme and peroxidase-like enzyme.

5. The anti-hair loss and hair growth integrated core-shell microneedle patch according to claim 1, characterized in that: each microneedle has a tip end and a bottom end, the tip end is far away from the backing, and the microneedle is attached to the backing via the bottom end.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0026] FIG. 1 is a side view of the core-shell microneedle patch of the embodiment of the present invention;

[0027] FIG. 2 is a side view of the female microneedle mold of the embodiment of the present invention;

[0028] FIG. 3 is a schematic diagram of the preparation process of the core-shell microneedle patch of the embodiment of the present invention.

[0029] In the figures: 100. core-shell microneedle patch; 110. microneedle; 120. backing; 200. female microneedle mold; 201. forming hole; 202. upper surface.

DESCRIPTION OF THE INVENTION

[0030] The technical solution of the present invention will be further described below through the drawings and embodiment.

[0031] The present invention provides an anti-hair loss and hair growth integrated core-shell microneedle patch, comprising a backing 120 and a core-shell microneedle array attached to one side of the backing 120, wherein the core-shell microneedle array comprises a plurality of microneedles 110 arranged on the backing 120 to form an array, each microneedle 110 comprises a shell substrate material and an internal core, and the shell substrate material is loaded with nano-enzyme for removing excessive active oxygen. The internal core comprises mesenchymal stem cell-derived exosomes. The nano-enzyme comprises one or more of monoatomic nano-enzyme, complex nano-enzyme, catalase-like enzyme and peroxidase-like enzyme. The shell substrate material and the internal core form a core-shell structure, and when the core-shell microneedle patch 100 is used, the shell substrate material and the internal core act on the scalp successively to promote hair growth.

[0032] Each microneedle 110 has a tip end and a bottom end, the tip end is far away from the backing, and the microneedle 110 is attached to the backing 120 via the bottom end. The three-dimensional shape of the microneedle 110 is not specifically limited, which is either cylindrical, conical, truncated cone shaped or a combination thereof, or in the shape of a regular or irregular cone, conoid, triangular pyramid, quadrangular pyramid or more advanced pyramid and other shapes, and the cone, conoid, triangular pyramid, quadrangular pyramid or more advanced pyramid may be a regular cone or oblique cone. As shown in FIG. 1, the diameter of the bottom end of the microneedle 110 is preferably not less than 100 μm, more preferably 100-500 μm; if the diameter is less than 100 μm, the mechanical strength of the microneedle is insufficient, the microneedle is easy to break; if the diameter is greater than 500 μm, the microneedles used in some parts on an animal body or human body will leave large holes on the skin and cause the problem of affecting the skin beauty and healing; the distance between the tip ends of adjacent microneedles is preferably 300-800 μm, and within this spacing, the core-shell microneedle patch 100 can achieve optimal effects in many aspects such as nano-enzyme and exosome release efficiency after penetrating to the depth of stratum corneum. During preparation of the microneedles, a template method is used, the female microneedle mold and the male microneedle mold are used, as shown in FIG. 2, the female microneedle mold 200 comprises an upper surface 202 and forming holes 201 extending downward on the upper surface 202, the forming holes 201 are matched with the shape of the microneedles 110, the forming holes 201 also have tip ends and bottom ends, the tip end of the female microneedle mold is far away from the upper surface, the bottom end of the female microneedle mold is flush with the upper surface, the height, bottom end width and tip end spacing of the forming holes are either the same as or greater than the height, bottom end width and tip end spacing of the microneedles, in the latter case, the forming holes 201 will not be filled up with the formed microneedles, and both the upper surface of the female microneedle mold and the inner surface of the forming holes can be coated with anti-adhesion layers to facilitate mold unloading.

[0033] Note that those skilled in the art have the ability to make appropriate choices on the shape, size and the like of the microneedles of the anti-hair loss and hair growth integrated core-shell microneedle patch 100 of the present invention according to the actual application.

[0034] The shell substrate material is a soluble polymer and comprises one or more of polyvinyl alcohol, trehalose, hyaluronic acid, polylactic acid, galactose, polyvinylpyrrolidone, polyethylene glycol diacrylate, silk fibroin, methacrylate gelatin and carboxy methyl cellulose. The shell substrate material in the present invention is a substrate material commonly used for preparing microneedle patches in the art, but polyvinyl alcohol is preferred in order to ensure that the microneedle prepared by the method of the present invention has a certain mechanical strength, polyvinyl alcohol has the function of skin protection, can be applied to acceleration of wound healing, has good solubility, biocompatibility and mechanical strength, and is selected as a substrate component of the microneedle patch. In addition, polyvinyl alcohol can be degraded by active oxygen to consume free radicals, thus mitigating oxidative stress in the microenvironment around follicles to protect cells from death.

[0035] The backing comprises one or more of polyethylene glycol diacrylate, silk fibroin, methacrylate gelatin, carboxy methyl cellulose, trehalose, hyaluronic acid, polylactic acid-glycolic acid copolymer, polylactic acid, galactose, polyvinylpyrrolidone and polyvinyl alcohol. The backing in the present invention can only be the backing commonly used in the preparation of microneedles in the art, but polyvinylpyrrolidone is preferred considering the mechanical strength and flexibility of the formed backing.

Embodiment 1

[0036] A preparation method of anti-hair loss and hair growth integrated core-shell microneedle patch, comprising the following steps,

[0037] (1) Preparation of a microneedle shell structure: dissolving nano-enzyme in an aqueous solution of the shell substrate material to form a mixture, centrifuging the mixture to remove air and depositing the mixture on a polydimethylsiloxane (PDMS) female microneedle mold, then centrifuging the PDMS female microneedle mold, so that the mixture flows into forming holes of the female microneedle mold, using and pressing a male microneedle mold matched with the PDMS female microneedle mold into the female microneedle mold, putting it into a drier and holding for 2 hours at room temperature, and using polyvinyl alcohol as the shell substrate material;

[0038] (2) Preparation of a microneedle core structure: culturing human bone marrow mesenchymal stem cells, isolating the mesenchymal stem cell-derived exosomes from a cell culture medium with an exosome isolation reagent, adding a keratin solution containing cysteine and exosomes into a groove of the microneedle shell structure, removing excessive keratin solution through a plastic scraper, and putting the keratin solution in a drier for drying at room temperature until the keratin solution is completely dry;

[0039] (3) Preparation of the backing: applying a solution containing a backing material to the surface of the bottom end of the microneedle and the upper surface of the female microneedle mold not covered by the microneedle to form backing solution layers, the backing material is crosslinked to form a continuous backing, finally the microneedle is attached to the backing, and using polyvinylpyrrolidone for the backing;

[0040] (4) Preparation of the anti-hair loss and hair growth integrated core-shell microneedle patch: drying and curing the core-shell microneedle array on the backing, and unloading the female microneedle mold to form the anti-hair loss and hair growth integrated core-shell microneedle patch.

[0041] As can be seen from FIG. 3, hydrophobic nano-enzyme treated by DSMP-mPEG2000 is transformed into hydrophilic nano-enzyme, and evenly dispersed in the microneedle shell structure formed by the shell substrate material.

Comparative Example 1

[0042] The difference from the above preparation process of Embodiment 1 is that the internal core in Comparative Example 1 does not contain exosomes.

[0043] The therapeutic effect of the anti-hair loss and hair growth integrated core-shell microneedle patch is tested, the mouse models with androgenic hair loss are built by topical administration of testosterone solution every day for 28 days, five groups of mouse models with androgenic hair loss are used to test the effect of the microneedle patch, one of the groups is a model group to which only testosterone solution is applied, the blank microneedle patch, the nano-enzyme microneedle patch (prepared in Comparative Example 1) and the core-shell microneedle patch (prepared in Embodiment 1) are used on the other three groups of mouse models with androgenic hair loss respectively, the patches are used for 15 days and replaced every three days, a Minoxidil solution is used for the last group and applied every day for 13 consecutive days. The measurement results are shown in Table 1, and the therapeutic effect of the anti-hair loss and hair growth integrated core-shell microneedle patch is judged by scoring the hair diameter, percentage of Ki67 positive cells and hair cycle.

TABLE-US-00001 TABLE 1 Therapeutic effect of anti-hair loss and hair growth integrated core-shell microneedle patch Blank Nano- Core- Micro- enzyme shell needle Micro- Micro- Model Patch Minoxidil needle needle Group group Group Patch Patch Hair diameter (μm) 6 6 11 11 11 Ki67 positive cells (%) 18 20 20 60 68 Hair cycle score 5 16 22 45 50

[0044] As can be seen from the data in Table 1, the core-shell microneedle patch of Embodiment 1 prepared in the present invention can achieve a good therapeutic effect for treating hair loss, the Ki67 positive cells are significantly increased, cell proliferation is accelerated, which are good for hair growth; compared with Minoxidil, a drug used to treat hair loss, the microneedles exhibit the effect of accelerating hair regeneration in the mouse models with androgenic hair loss at a low usage frequency, and will not lead to significant skin damage. After the core-shell microneedle patch is applied to the mice with androgenic hair loss, the tip ends of the microneedles firstly stimulate the hair loss area mechanically to remodel capillaries in the hair loss area, then the shell substrate material is rapidly degraded, the nano-enzyme loaded by the shell substrate material is passively released to remove active oxygen and promote angiogenesis in the microenvironment around hair follicles, thus promoting hair regeneration; then the exosomes are also released and transported to the hair follicle niches to improve pigmentation and promote hair regeneration, and therefore, the microneedle patch in the present invention can gradually improve the hair follicle environment in the hair loss area step by step and promote hair growth through the core-shell structure of the microneedle patch.

[0045] Therefore, the present invention uses the anti-hair loss and hair growth integrated core-shell microneedle patch in the above-mentioned structure, wherein the shell substrate material is rapidly degraded after the microneedle patch is applied to human skin, the nano-enzyme loaded by the shell substrate material can be passively released to remove active oxygen and promote angiogenesis in the microenvironment around hair follicles, the internal core of the microneedle is loaded with mesenchymal stem cell-derived exosomes, and the internal exosomes are released and conveyed to hair follicle niches after the shell substrate material is degraded, so that improvement of pigmentation and promotion of hair regrowth are possible.

[0046] Finally, it should be specified that: the above embodiment is only used to illustrate rather than to limit the technical solution of the present invention, the present invention is described in detail with reference to a better embodiment, but those of ordinary skill in the art should understand that: they can still make modifications or equivalent replacements of the technical solution of the present invention, and these modifications or equivalent replacements cannot make the modified technical solution depart from the spirit and scope of the technical solution of the present invention either.