KR102216937B1 - Minimally invasive kit evaluating skin oil degree including microneedle patch and biomarker for evaluating skin oil degree - Google Patents

Abstract

According to one embodiment of the present invention, a minimally invasive kit for evaluating a skin oil degree comprises a device capable of quantifying an expression level of an RNA gene from a specimen extracted from the skin of a subject and a microneedle patch including a plurality of microneedles having a solid structure with a biodegradable polymer hyaluronic acid. While the microneedle patch is applied to the skin of the subject and is separated after maintaining a predetermined time, the specimen from the skin of the subject, which has been adsorbed on a microneedle surface of the microneedle patch or the extract therefrom, is quantitatively analyzed by the device. The device carries out an evaluation of skin oil degree by quantifying an expression level of skin oil-related RNA biomarker genes from the specimen from the skin of the subject, which has been adsorbed on the microneedle surface of the microneedle patch or the extract therefrom.

Description

Minimally invasive skin oil level evaluation kit including microneedle patch and biomarker for skin oil level evaluation {MINIMALLY INVASIVE KIT EVALUATING SKIN OIL DEGREE INCLUDING MICRONEEDLE PATCH AND BIOMARKER FOR EVALUATING SKIN OIL DEGREE}

The present invention relates to a minimally invasive skin oil level evaluation kit including a microneedle patch and a biomarker for evaluating the skin oil level.

Sebum, which is involved in skin oil, is a substance secreted by the sebaceous glands, and its main components are triglycerides, wax esters, and squalene. The sebaceous gland is an accessory gland of hair and exists in the dermis layer, and the secreted sebum covers the skin surface and prevents moisture from being released to the outside. In addition, it neutralizes alkali, has sterilizing power, and is an important factor in preventing skin dryness and delaying skin aging.

Therefore, it can be said to be healthy skin only when an appropriate level of sebum secretion is maintained.Sebum secretion is excessive due to environmental and genetic factors such as increased sebum secretion by male hormones, hyperkeratosis of the hair follicle wall, inflammation by acne bacteria, stress, etc. If the increase is increased, it may block pores and cause skin problems, and related diseases include acne and seborrheic dermatitis.

Sebum secretion varies according to age and sex, but it is less secreted in infancy, then increases in adolescence, and then decreases with age. In addition, hormone-induced sebum secretion increases in men rather than women. In general, the opposite of dryness is referred to as oily with a lot of sebum secretion. The forehead, glabellar and nose areas where the sebaceous glands are mainly distributed are referred to as the T zone. The area from both cheeks to the chin is called the U zone, and in general, the distribution of sebaceous glands is low in this area. The U zone is dry and the T zone is oily skin. For oily skin, it is important to choose a face wash and moisturizer accordingly.

Appropriate methods for evaluating the effectiveness of skin oil are needed in determining the condition of skin oil and studying the mechanism of the secretion disorder or excessive secretion of skin oil. The same applies to the development of cleansing agents and treatments that can correct or treat skin oil disorders, and skin care methods.

On the other hand, as the distribution and sale of cosmetics that have been tested on animals, cosmetics made using raw materials that have been tested on animals, and imported cosmetics made using ingredients that have been tested on animals or tested on animals are completely banned, there is currently a problem with skin oil problems. B. Research on the mechanism of hypersecretion and the effectiveness of functional cosmetics related to this are being conducted through efficacy evaluation using a human body application device, tape stripping, skin tissue biopsy, or ex vivo efficacy evaluation using 3D skin.

There is Sebumeter of Courage+Khazaka Electronic Co., Ltd. as a human body application device for skin oil measurement. After contacting the skin with a sebum collection tape having a thickness of 0.1 mm, the absorbed sebum is measured. When the tape becomes transparent by the sebum, the amount of oil is measured on the principle that the light transmittance increases.

Since such a human body-applied device is sensitive, it is highly influenced by the measuring environment and the measurer, so that reliable results can be obtained only by an experienced measurer while exposed to constant temperature and humidity conditions for a certain period of time. In addition, since this method simply measures the secreted sebum on the skin surface, it is not suitable for use in the study of specific mechanisms of skin oil secretion. In addition, changes in certain factors cannot be scientifically explained, and specific data on sebaceous gland changes present in the dermis are not provided.

In addition, a non-invasive stripping method using a tape that analyzes a skin specimen attached to the tape by attaching and attaching a tape to the lesion site also cannot reflect changes in the dermal layer related to skin oil because the specimen collection area is limited to the stratum corneum.

Skin biopsy is used to compensate for these shortcomings, but this requires a skilled surgeon's skill, and because it is a very invasive method, there is a disadvantage that a feeling of rejection occurs due to the pain of the patient, and a scar at the biopsy site remains after the test. . For this reason, it is difficult to perform a skin biopsy before and after each use of the test drug for efficacy evaluation in the actual human body, and the compliance of patients is very poor.

The ex vivo test using 3D artificial skin shows the most advanced structure that mimics the skin, including the cells of the human epidermis and dermis, but the price is high and the structure of blood vessels, hair follicles, subcutaneous fat, etc. Since it does not contain various immune cells present in the dermis, it cannot be completely replaced by a skin biopsy because it may differ from actual skin changes.

Therefore, there is currently no alternative to animal testing or skin biopsy in the study of the secretion status of skin oil and the mechanism of skin oil secretion or the study on the effectiveness of skin oil, and it is non-invasive and can measure changes in the dermal layer of the skin. I need a way to do it.

Microneedle is a drug delivery technology that effectively delivers drugs by piercing the stratum corneum with minimal invasion and creating microscopic holes in the skin. Recently, microneedles are used only for the delivery of drugs and physiologically active substances. Rather, the scope of its use is expanding to acquire temporary specimens in the body and diagnose diseases. In particular, it can be used for detecting and diagnosing biomarkers by collecting human body fluids or blood, etc. through micropores formed of microneedles. For example, a hollow microneedle has a capillary tube inside the needle, and is used for the purpose of extracting blood through the capillary tube after being attached to the skin. It has the advantage of being able to detect glucose and cholesterol in the blood or diagnose biomarkers by extracting blood relatively safely while minimizing the patient's pain.However, if the needle breaks in the skin, side effects are high and side effects such as bleeding may occur. have.

A swellable microneedle is a principle that absorbs interstitial fluid in the skin after being attached to the skin, swells, and seals the perforated area and adheres to the skin without adhesive.Separating the absorbed body fluid is used for biomarker detection, monitoring and diagnosis. have. However, there is a limitation in that it is difficult to stably attach the patch according to various environmental factors because the patch must be attached for a long time to absorb the body fluid required for analysis.

The dissolving microneedles used in the present invention are prepared by mixing a polymer material that is soluble in a living body and an active ingredient, and then solidifying them with microneedles. When such soluble microneedles are attached to the skin, they are efficiently dissolved by body fluids, and drugs can be easily delivered into the skin. In addition, soluble microneedles are not made of metal or plastic, so there is no risk of breaking in the skin, so it is safe. The applicant of the present invention intends to utilize the soluble microneedle for a new purpose. This is the first collection of skin samples (RNA, DNA, protein) using soluble microneedles, RNA microarray analysis using the samples, discovery of skin oil biomarkers based on the analysis results, evaluation of skin oil levels using the biomarkers, and It is an evaluation of the effectiveness of drugs or cosmetics to improve the degree of skin oil.

Recently, research on analyzing skin types is being actively conducted by providing a direct-to-consumer (DTC) service, which is a service that provides information on analyzing single nucleotide polymorphism (SNP) of genetic DNA related to skin. Usually, oral epithelium is collected and DNA sequence is analyzed, and the risk is presented by comparing whether the sequence of a specific gene is different from that of a normal person. Skin genes can be tested using a non-invasive method, but there are limitations. Because DNA exists identically in all cells and is immutable, it does not reflect actual skin conditions that change due to various environmental factors. Even if you were born with a specific SNP, the result cannot be reflected in the SNP analysis in the case of recovery through acquired management or treatment. Due to these characteristics, SNP analysis is difficult to apply to discovery of new effective substances, research on mechanisms, and evaluation of efficacy. In addition, the SNP analysis using the current oral epithelium cannot reflect the actual degree of oiliness of the skin in that the sample collection site is the oral epithelium rather than the skin. On the other hand, RNA is a material that can be translated into a protein that works in real cells, and since it shows a specific expression level for each cell, it can reflect the actual skin characteristics that change due to various factors. Therefore, it can be said that observing the expression at the level of RNA and protein in actual skin cells is essential for accurate skin condition analysis.

Unlike DNA genomic analysis, RNA transcript analysis can detect genes that are specifically expressed only in skin cells or whose expression varies depending on environmental conditions such as drug exposure, and can confirm the difference in gene expression levels between the test group and the control group. Therefore, it can be applied to efficacy evaluation, mechanism research, and discovery of candidate substances that require comparison before and after tests. In addition, microarray technology can be used to compare the expression of more than 40,000 genes in one sample, which is very useful in diagnosing diseases or discovering therapeutic biomarkers. However, as described above, there is a limitation in the method of collecting RNA and protein in a non-invasive manner. The inventors of the present invention attempt to propose a method capable of overcoming the above-described limitations in the present invention.

An object of the present invention is to solve the problems of the conventional methods for evaluating skin oil levels as described above. Among the conventional methods, for example, a tissue biopsy requires an expert skill of an operating surgeon, suffers a patient's pain, which causes a feeling of rejection, and has a disadvantage in that a scar at the biopsy site remains after the test. Another conventional method, tape stripping, has a drawback in that the material adhering to the tape is limited to the stratum corneum, so that it can only be used as an auxiliary inspection method, and does not provide a complete result. In addition, the conventional SNP array uses DNA from a human specimen, and has a disadvantage in that it is difficult to reflect the actual skin condition that changes due to various environmental factors as DNA that is determined and unchanged from birth.

It is an object of the present invention to increase the reliability of analysis results compared to conventional tape stripping by collecting skin factors inside the stratum corneum while having little pain and no scars compared to the existing tissue biopsy, and the convenience of use of the patient. It is to provide a new minimally invasive skin oil level evaluation kit that can reflect the actual skin condition that changes due to various environmental factors.

In addition, it is an object of the present invention to provide a biomarker for evaluating the degree of skin oil using a skin specimen as a biological sample.

In addition, an object of the present invention is to provide the following together with the achievement of the above object.

-Composition for predicting skin oil level

-Test method for predicting skin oil level and classification method for skin type

-A method of screening candidate substances for induction or inhibition of skin oil and evaluating the effectiveness of skin oil improvement treatment

-A method for evaluating the efficacy of human body application in place of animal testing such as general cosmetics, functional cosmetics, medical devices, and pharmaceuticals to improve skin oil level

The kit for evaluating the degree of minimally invasive skin oil according to an embodiment of the present invention comprises a device capable of quantifying the expression level of RNA genes from a temporary specimen extracted from the skin of a subject, and a plurality of microstructures comprising a biodegradable polymer hyaluronic acid. It includes a microneedle patch containing a needle. In a state where the microneedle patch is applied to the skin of the subject and separated after maintaining for a predetermined time, a temporary specimen from the subject skin adsorbed on the microneedle surface of the microneedle patch or an extract therefrom is quantitatively analyzed by the equipment. . The device quantifies the expression level of the skin oil-related RNA biomarker gene from a temporary specimen from the skin of the subject adsorbed on the microneedle surface of the microneedle patch or an extract therefrom, and evaluates the degree of skin oiliness based on the quantification value. Is made.

The biomarker for evaluating the degree of skin oil according to an embodiment of the present invention is an RNA gene biomarker using a skin sample as a biological sample, MFAP2, IGF1, HSD11B1, GPAM, CPT1C, AR, MPZL3, AQP3, SREBF2 and HSD17B2 Include any one or two or more of.

In addition, an additional configuration may be further provided in the minimally invasive skin oil level evaluation kit or a biomarker for skin oil level evaluation according to the present invention.

The usefulness of MFAP2, IGF1, HSD11B1, GPAM, CPT1C, AR, MPZL3, AQP3, SREBF2 and HSD17B2 as biomarkers for evaluating the degree of skin oil according to the method of obtaining a minimally invasive skin specimen peculiar to the present invention was found.

These biomarkers are markers capable of evaluating the degree of skin oiliness of an individual, and may measure the level of mRNA or protein thereof of one or more genes. Since it was confirmed that the level of the gene or its protein was increased or decreased in the subject of the skin oil level evaluation, it may be usefully used in the evaluation of the skin oil level by measuring the level thereof.

According to the present invention, the problem of the conventional SNP array method of skin type diagnosis method using DNA of a human specimen can be solved. Conventional SNP arrays use DNA from human specimens, but the DNA, which is determined and unchanged from birth, has a disadvantage in that it is difficult to reflect actual skin conditions that change due to various environmental factors. In addition, according to the present invention, problems of the conventional human body application device measurement, tape stripping, tissue biopsy, and 3D artificial skin ex vivo test method of evaluating the degree of skin oil can be solved.

Conventional human body application measurement is a method of measuring the surface of the skin in a tomographic manner, and thus has a disadvantage in that it is difficult to scientifically explain changes in specific factors or used for research on specific mechanisms.

Conventional tape stripping has a disadvantage in that the material adhering to the tape is limited to the stratum corneum, so that it can only be used as an auxiliary inspection method, and it does not provide a complete result.

Conventional tissue biopsy requires a skilled surgeon's skill, suffers from patient pain, and thus causes a feeling of rejection, and has a disadvantage of leaving a scar at the biopsy site after the test.

Ex vivo tests using conventional 3D artificial skin are expensive and do not include structures such as blood vessels, hair follicles, and subcutaneous fat that exist in the skin, so they cannot be considered to reflect changes in the actual skin. Can't.

According to the present invention, compared to the existing tissue biopsy, there is little pain, no scars are left, and the convenience of use of the patient can be improved, and at the same time, the reliability of the analysis result compared to the existing tape stripping can be improved by collecting skin factors inside the stratum corneum. A new minimally invasive skin oil level assessment kit and biomarkers for skin oil level assessment can be provided.

By using the kit or biomarker provided according to the present invention, it is possible to develop and screen skin oil-inducing or inhibiting substances more efficiently compared to the prior art, and provide information on accurate skin types for individuals, Through this, an individual's skin type can be scientifically classified and used in the development of customized cosmetics.

In addition, according to the present invention, in the development of general cosmetics, functional cosmetics, medical devices, and pharmaceuticals for improving skin oil, a new human body application efficacy evaluation method capable of replacing animal experiments can be provided.

1 is a diagram showing a conventional skin biopsy method.
2 is a diagram conceptually showing a skin biopsy method according to the present invention.
3 is a table showing the results of a Pro-Collagen 1 detection test for patient groups in their 30s and 60s using a blank patch, a low molecular weight hyaluronic acid patch, and a high molecular weight hyaluronic acid patch, respectively.
FIG. 4 is a table showing the results of Pro-Collagen 1 detection tests for a 30s-age patient group and a 60s-age patient group, respectively, using a blank patch, a low molecular weight hyaluronic acid patch, and a high molecular weight hyaluronic acid patch. (OD) is the table.
5 is a table showing measurement results of length change of a low molecular weight hyaluronic acid microneedle patch and a high molecular weight hyaluronic acid microneedle patch before and after applying a biopsy.
6 is a diagram showing a microarray procedure.
7 is a diagram showing the result of gene alignment.
FIG. 8 is a table summarizing the values of gene expression, which is a microarray test result of genes found to be related to skin oil through a literature search.
9 shows the results of heatmap analysis in order to visually compare and analyze the expression levels of skin oil biomarker candidates selected through RNA microarray analysis.
10 and 11 show the results of performing a bivariate correlation analysis to confirm the correlation between the skin oil-related biomarker candidate genes selected through RNA microarray analysis and the measurement result of a human body application device (Sebumeter).

DETAILED DESCRIPTION OF THE INVENTION The detailed description of the present invention to be described later refers to the accompanying drawings, which illustrate specific embodiments in which the present invention may be practiced. These embodiments are described in detail sufficient to enable those skilled in the art to practice the present invention. It is to be understood that the various embodiments of the present invention are different from each other, but need not be mutually exclusive. For example, a detailed description of the present invention to be described later that is different from one embodiment without departing from the spirit and scope of the present invention without departing from the spirit and scope of the present invention, specific embodiments in which the present invention may be practiced Reference is made to the accompanying drawings showing examples as examples. These embodiments are described in detail sufficient to enable those skilled in the art to practice the present invention. It is to be understood that the various embodiments of the present invention are different from each other, but need not be mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be changed from one embodiment to another and implemented without departing from the spirit and scope of the present invention. In addition, it should be understood that the positions or arrangements of individual elements in each embodiment may be changed without departing from the spirit and scope of the present invention. Therefore, the detailed description to be described below is not made in a limiting sense, and the scope of the present invention should be taken as encompassing the scope claimed by the claims of the claims and all scopes equivalent thereto.

Hereinafter, various preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to enable those skilled in the art to easily implement the present invention.

Minimally invasive skin specimen collection using microneedle patch

1 is a diagram showing a conventional skin biopsy method, and FIG. 2 is a diagram conceptually showing a skin biopsy method according to the present invention.

2 is a diagram conceptually showing a skin biopsy method according to the present invention.

In the upper left of FIG. 2, a commercially available microneedle patch under the product name "Therapass" is shown. This product is a high molecular weight hyaluronic acid microneedle patch with a molecular weight of 1000kDa, as a product on the market by the applicant's company. In the lower left of FIG. 2, the microneedle patch is applied to the skin, and more specifically, the microneedle of the patch penetrates to the dermal layer of the skin. In the right part of FIG. 2, a representative technical idea of the present invention in which a biopsy is performed using a protein in the skin buried in the microneedle of the patch after the microneedle patch is applied to a dermatitis patient is conceptually shown. The term “Bio-Mining”, which is the term indicated here, is used to mean that proteins in the skin of a subject are extracted for biopsy.

The matters related to FIGS. 3 to 5 to be described below are the results of testing the skin protein extraction performance of the biodegradable high molecular weight hyaluronic acid microneedle patch by the present inventors before reaching the present invention. This experimental result is the reason why the present inventors used a biodegradable high molecular weight hyaluronic acid microneedle patch as a means for collecting skin specimens among the components of the skin oil level evaluation kit in the present invention. The biodegradable high molecular hyaluronic acid microneedle patch (commercialized product name "Therapass") used as a means for collecting skin temporary specimens in the present invention has a solid structure, and was manufactured by the present inventor's unique Droplet Extension (DEN) process. However, the scope of the present invention should not be construed as precluding the use of microneedle patches manufactured in other ways, such as molding methods. Regardless of the manufacturing method, the microneedle patch of the same material and structure is evaluated to be the same in terms of the performance of collecting temporary skin specimens.

3 is a table showing the results of a Pro-Collagen 1 detection test for patient groups in their 30s and 60s using a blank patch, a low molecular weight hyaluronic acid patch, and a high molecular weight hyaluronic acid patch, respectively. On the x-axis of FIG. 3, empty patches, low molecular weight hyaluronic acid patches, and high molecular weight hyaluronic acid patches are indicated. The y-axis shows the detected mass per unit volume of Pro-Collagen 1 in picograms per milliliter. The notation ELISA shown in FIG. 3 refers to a method used in modern biotechnology as a method of quantitatively measuring the intensity and amount of an antigen-antibody reaction by labeling an enzyme on an antibody or antigen and measuring the activity of the enzyme. It was used throughout the experiment of the present invention.

What should be looked at carefully in the table of FIG. 3 is whether or not it is substantially different from the blank patch, which is the first control group. The empty patch is a prior art that existed before the filing of the present invention, and if the detection result is not substantially differentiated from the empty patch, the present invention does not contribute to improving the biometric detection effect. 3, the detection amount of Pro-Collagen 1 in the low molecular weight (110 kDa) hyaluronic acid patch was not substantially differentiated from that of the empty patch. However, it can be seen that the detection amount of Pro-Collagen 1 in the high molecular weight (1000 kDa) hyaluronic acid patch was significantly increased compared to that of the empty patch and the low molecular weight hyaluronic acid patch.

Another experimental result is shown in FIG. 4. FIG. 4 is a table showing the results of a Pro-Collagen 1 detection test for a 30-year-old patient group and a 60-year-old patient group using the three control groups described above, and the y-axis is a table in which absorbance (OD) is indicated. In the table of FIG. 3, there is a difference in that the y-axis is the detected mass per unit volume of Pro-Collagen 1 in that the table of FIG. 4 is absorbance (OD). Based on the calibration curve using standard substances, the quantification from which living tissue is extracted can be inferred. Therefore, the quantity of Pro-Collagen 1 can be inferred by measuring the absorbance (OD) value of each group. 4 shows a result that the absorbance value in the low molecular weight hyaluronic acid patch is somewhat distinct from the empty patch, but the results in the empty patch and the low molecular weight hyaluronic acid patch are still roughly the same, and the high molecular weight hyaluronic acid patch The results are markedly differentiated.

The present inventors continued the experiment and analyzed the cause of how the difference of the remarkable results appeared according to the molecular weight of hyaluronic acid, which is a component of the microneedle patch, and the cause was dissolved into the skin according to the difference in molecular weight. I found it at speed. The microneedle component of the microneedle patch that is currently commercially available is biocompatible, and biodegradable polymer materials are the mainstream. "Biocompatible substance" means a substance that is not toxic to the human body and is chemically inert. And, "biodegradable material" refers to a material that can be degraded by body fluids, enzymes or microorganisms in a living body. In addition, among biodegradable substances, it is known that the lower the molecular weight, the faster the dissolution rate in the living body, and the higher the molecular weight, the lower the dissolution rate in the living body is known. Meanwhile, the following materials are known as biocompatible polymers:

Hyaluronic acid (HA), gelatin, chitosan, collagen, alginic acid, pectin, carrageenan, chondroitin (sulfate), dextran (sulfate), polylysine, carboxymethyl titine, Fibrin, agarose, pullulan, cellulose, polyvinylpyrrolidone (PVP), polyethylene glycol (PEG), polyvinyl alcohol (PVA), hydroxypropylcellulose (HPC), hydroxyethylcellulose (HEC), hydroxy Propylmethylcellulose (HPMC), sodium carboxymethylcellulose, polyalcohol, gum arabic, alginate, cyclodextrin, dextrin, glucose, fructose, starch, trehalose, glucose, maltose, lactose, lactulose, fructose, turanose, Melitos, melesitos, dextran, sorbitol, xylitol, palatinite, polylactic acid, polyglycolic acid, polyethylene oxide, polyacrylic acid, polyacrylamide, polymethacrylic acid, poly Maleic acid, polyethylene glycol-polyester copolymer (poly(ethyleneglycol)/polyester), chitosan-glycerol phosphate, polyphosphazene, polycaprolactone, polycarbonate , Poly(ethylene glycol)/poly(propylene glycol), polycyanoacrylate, polyorthoester, polyhydroxyethyl methacrylamide lactate (Poly(N- (2-hydroxyethyl) methacrylamide-lactate), poly(propylene phosphate), etc.

When the microneedle patch is attached to the skin, proteins can adhere to and be extracted from the biocompatible microneedle structure during the process of entering the dermal layer of the patch and maintaining it after the patch's microneedles. However, the low molecular weight hyaluronic acid microneedle has a relatively high dissolution rate even if a protein in a living body adheres to the surface, so if it is attached to the skin for a long time, the protein attached to the surface may be lost as it dissolves itself. For this reason, it was analyzed that the experimental results of FIG. 3 were obtained. The results supporting this are shown in FIG. 5.

FIG. 5 is a table showing measurement results of length change before and after application of a biopsy of a low molecular weight hyaluronic acid microneedle patch and a high molecular weight hyaluronic acid microneedle patch among the three control groups described above.

According to the results of FIG. 5, the microneedles of the low molecular weight hyaluronic acid microneedle patch of 110 kDa showed a length reduction of approximately 30% while attached to the human skin. On the other hand, the microneedles of the 1000kDa high molecular weight hyaluronic acid microneedle patch showed a decrease in length of only about 10% while attached to the skin. These experimental results show that the low molecular weight hyaluronic acid microneedles have a relatively high dissolution rate even if a protein in a living body adheres to the surface, so if it is attached to the skin for a long time, the protein attached to the surface may be lost as it dissolves itself. It supports that it is the cause of the experimental results shown in FIGS. 3 and 4. In the experiments shown in FIGS. 3 to 5, the skin adhesion time of each control group was 5 minutes.

Selection of clinical trial subjects

The present inventors conducted an experiment on 33 healthy subjects aged 20 to 70 years to discover a biomarker for evaluating the degree of skin oil and to develop a kit for evaluating the degree of skin oil using the same (Table 1).

Number of samples (persons) 33 Male (person) 19 Women (people) 14 Age (mean ± SD) 37.12 ± 12.90

At this time, ① those who did not agree to this study voluntarily after IRB approval, ② those who did not consent to the provision of human derivatives, ③ pregnant or lactating women, and those of childbearing age who do not agree with the method of contraception specified in the protocol. Women, ④ People who use steroid-containing skin formulations for more than 1 month for the treatment of skin diseases, ⑤ Users of oral steroids, oral antibiotics, and immunosuppressants for the last month, ⑥ Infections in the target lesion (fungi, bacteria, and viruses) Infection), ⑦ receiving ultraviolet treatment, ⑧ having serious systemic disease, ⑨ subjects who cannot read and understand the consent form (illiteracy, etc.), and ⑩ other judges who are not suitable for the test Those who were thought to be able to do so were excluded from the test subjects.

Classification of test subjects according to skin oil content, medical examination by specialist, evaluation of human body devices, and collection of temporary skin specimens

After waiting in constant temperature and humidity conditions for 30 minutes after washing the face, a questionnaire evaluation and a dermatologist interview were conducted on the subjects, and the skin oil on both nostrils was measured. Specifically, it was measured using Sebumeter® SM815 equipment, and the μg/cm ² value was analyzed.

The physical findings of the subject's skin oil were provided by visual judgment by a dermatologist, based on the relevant literature ( Reprod Biol Endocrinol. 2017 Homburg et al ).

Table 2 summarizes the results of evaluating skin oil by classifying 5 control groups with low skin oil and 5 test groups with high skin oil among all test subjects.

Test group (Oily) Control (Non-oily) Number of samples (persons) 5 5 Age (mean ± SD) 38.40 ± 12.93 37.60 ± 18.15 Physical findings (score) 1.80 ± 0.84 1.40 ± 0.55 Skin oil content (μg/cm2) 223.70 ± 65.96 53.90 ± 33.52

In addition, after attaching the microneedle patch to the face for 15 minutes, a temporary skin specimen was collected.

RNA collection from skin samples

The skin specimen obtained from the test subject was provided to RNeasy® Plus Mini Kit (Qiagen), and high-purity RNA was extracted using the kit. Then, RNA microarray analysis was performed after checking the QC (Quality Control) of the RNA sample using the NanoDrop device and the 2100 Bioanalyzer device.

RNA microarray analysis

The RNA isolated by the above-described method was microarrayed according to the manual of the GeneChip® Human Gene 2.0 ST Array (Affymetrix) platform. 6 shows the microarray procedure introduced in the manual of the platform, and the present inventors performed the microarray in the same procedure. Table 3 below summarizes the RNA microarray analysis protocol of the platform.

Sample type Total RNA Platform GeneChip® Human Gene 2.0 ST Array cDNA synthesize cDNA was synthesized using the GeneChip WT (Whole Transcript) Amplification kit as described by the manufacturer. Label protocol The sense cDNA was then fragmented and biotin-labeled with TdT (terminal deoxynucleotidyl transferase) using the GeneChip WT Terminal labeling kit Hybridization protocol Approximately 5.5 μg of labeled DNA target was hybridized to the Affymetrix GeneChip Array at 45°C for 16hour Scan protocol Hybridized arrays were washed and stained on a GeneChip Fluidics Station 450 and scanned on a GCS3000 Scanner (Affymetrix). Data processing Array data export processing and analysis was performed using Affymetrix® GeneChip Command Console® Software (AGCC)

After that, the entire data was summarized and normalized through the Robust Multi-Average (RMA) method of Affymetrix® Power Tools (APT), the results were summarized at the gene level, and Differentially Expressed Gene (DEG) analysis was performed. Statistical significance of the data was analyzed using independent t-test and fold change change, the false discovery rate (FDR) was adjusted using the Benjamini-Hochberg algorithm, and the DEG set was analyzed using linkage and Euclidean distance. Hierarchical cluster analysis was performed. In addition, all data analysis and visualization work to confirm the difference in gene expression was performed using the R 4.0.0 program.

Selection of skin oil biomarker candidates through bioinformatics analysis and significant correlation analysis

After the RNA microarray test, in order to confirm the difference in expression of about 40,000 genes between the test group and the control group, gene alignment was performed using the R 4.0.0 program. 7 is a diagram showing the result of gene alignment. The gene alignment of FIG. 7 is also called heatmap analysis. Heatmap analysis is a term that combines heat, meaning heat, and map, meaning map, and is an analysis method that displays various information that can be expressed in color as a heat distribution diagram on an image. In the heatmap analysis described in the present specification, red expression indicates a larger gene expression value, and blue expression indicates a smaller gene expression value. In FIG. 7, when hundreds of genes were analyzed, it was confirmed that the expression values of a number of genes were specifically different in the test group and the control group.

Thereafter, the present inventors selected genes related to skin oil through a literature search (FIG. 8). The present inventors conducted a microarray test of genes confirmed to be related to skin oil through the literature search. As a result, the numerical values for the confirmed gene expression are summarized in the table of FIG. 8.

It is useful as a biomarker for skin oil only when there is a difference in the numerical value of gene expression obtained by performing microarray between the test group with high skin oil level and the control group without microarray. To determine this, the present inventors used fold change and p -value. Fold change is a value showing how many times the measured value in the test group is higher or lower than the measured value in the control group, and p -value is a statistically significant difference between the test group and the control group in statistical processing. It is a value for visibility. The normalized signal value (expression value) of each sample obtained through the RNA microarray test is shown in the table of FIG. 8, and the fold change is a value obtained by calculating a 1:1 expression difference using the normalized signal value between the test group and the control group. The p- value is the degree to which the data is compatible with the null hypothesis, expressed as a value between 0 and 1, which usually means that the null hypothesis is rejected if it is less than 0.05.

As a result, genes with fold change of 1.2 or -1.2 times or more or p-value of 0.05 or less among the skin oil-related genes were identified as MFAP2, IGF1, HSD11B1, GPAM, CPT1C, AR, MPZL3, AQP3, SREBF2 and HSD17B2.

9 shows the results of heatmap analysis to visually compare and analyze the expression levels of skin oil biomarker candidates selected through RNA microarray analysis as described above. As in the case of FIG. 7, the heatmap analysis result of FIG. 9 also indicates that the expression value of the gene increases as indicated in red, and the expression value of the gene decreases as indicated in blue. From the results of FIG. 9, it was visually confirmed that the expression of specific genes selected through literature search in the test group appeared higher in red or lower in blue compared to the control group.

The correlation between the skin oil-related biomarker candidates MFAP2, IGF1, HSD11B1, GPAM, CPT1C, AR, MPZL3, AQP3, SREBF2, and HSD17B2 genes selected through the RNA microarray analysis above and the results of measurement of a human body application device (Sebumeter) To confirm, a bivariate correlation analysis was performed. The results are shown in FIGS. 10 and 11.

The present inventors show that the results of a bivariate correlation analysis experiment related to FIGS. 10 and 11, MFAP2, GPAM, and IGF1 genes show a statistically significant positive correlation with skin oil content (measured value by Sebumeter), and MPZL3 and AQP3 genes are It was confirmed that there was a statistically significant negative correlation with the oil content ((measured value by Sebumeter).

When the results of the skin oil evaluation experiment performed by the present inventors as described above were comprehensively analyzed, when the skin oil biomarker is in the widest range, MFAP2, IGF1, HSD11B1, GPAM, CPT1C, AR, MPZL3, AQP3, SREBF2 And HSD17B2, a total of 10 genes can be selected. Using this selection result, it will be possible to quantitatively evaluate the degree of skin oil by using any one or two or more genes of the 10 RNA genes as biomarkers. Furthermore, the above research results of the present inventors are in the development of a skin oil evaluation method or evaluation kit, development and screening of skin oil inducing or inhibiting substances, provision of skin type information for individuals, development of customized cosmetics, and evaluation of the effectiveness of skin oil substitute for animal experiments Therefore, it is expected to provide a very useful tool.

In the above examples, a method of quantifying the expression level of each RNA gene by extracting RNA from a skin specimen extracted using a microneedle from the skin of a subject and providing it to an RNA microarray quantitative analysis device has been described. However, the present invention should not be interpreted as being limited to this specific quantification method. Any method capable of quantifying the level of RNA expression using a skin test sample of a subject should be understood to be within the scope of the present invention. For example, a measurement method at the protein level such as an ELISA method can be applied. The RNA biomarker is expressed and produced. By specifying the type of protein and quantifying the protein, the level of expression of each RNA gene can be quantified. That is, the quantification equipment or kit used in the practice of the present invention may be an ELISA, RT-PCR kit, RNA chip, DNA chip, or protein chip kit. The measurement of the protein level may be performed by at least one method selected from ELISA, western blotting, magnetic bead-antibody immunoprecipitation, immunochemical histostaining, and mass spectrometry. In addition, the measurement of the mRNA level is RT-PCR, competitive RT-PCR, real-time RT-PCR, RNase protection assay (RPA: RNase Protection Assay), Northern blotting (Northern blotting) and DNA chips can be selected from one or more methods.

In the above, the present invention has been described by specific matters such as specific elements and limited embodiments and drawings, but this is provided only to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , Anyone with ordinary knowledge in the technical field to which the present invention pertains can make various modifications and variations from these descriptions.

Therefore, the spirit of the present invention is limited to the above-described embodiments and should not be defined, and all modifications that are equally or equivalent to the claims as well as the claims to be described later fall within the scope of the spirit of the present invention. I would say.

Claims (8)

Equipment capable of quantifying the expression level of RNA genes from a temporary specimen extracted from the skin of a subject,
Comprising a microneedle patch comprising a plurality of microneedles having a solid structure and consisting of a biodegradable polymer hyaluronic acid,
In a state where the microneedle patch is applied to the skin of the subject and separated after maintaining for a predetermined time, a temporary specimen from the subject skin adsorbed on the microneedle surface of the microneedle patch or an extract therefrom is quantitatively analyzed by the equipment. , The equipment quantifies the expression level of the skin oil-related RNA biomarker gene from a temporary specimen from the skin of the subject adsorbed on the microneedle surface of the microneedle patch or an extract therefrom, and based on the quantification value, Evaluation is made,
The skin oil-related biomarkers are MPZL3, GPAM, and IGF1,
Minimally invasive skin oil level evaluation kit. delete The method of claim 1, further comprising an equipment for extracting RNA from a temporary specimen from the skin of a subject, wherein the RNA obtained by the RNA extraction equipment is provided to the quantification equipment.
Minimally invasive skin oil level evaluation kit. The method of claim 3, wherein the quantification device is an RNA microarray kit,
Minimally invasive skin oil level evaluation kit. The method of claim 4, wherein the predetermined time is determined in advance in consideration of the dissolution rate according to the molecular weight of hyaluronic acid.
Minimally invasive skin oil level evaluation kit. The method of claim 5, wherein as the molecular weight of hyaluronic acid constituting the microneedle increases, biodetection performance is improved,
Minimally invasive skin oil level evaluation kit. delete delete

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