JP2005334199A - Measuring method of melanin monomer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a measuring method of melanin monomer capable of specifying its presence by visualizing the melanin monomer which is not visualized yet in a previous step of becoming the melanin. <P>SOLUTION: UVAII (ultraviolet ray of wavelength 320-360 nm) is illuminated to capture the image of the skin, UVB (ultraviolet ray of wavelength 280-320 nm) is illuminated to capture the image of the skin, and a visible light is illuminated to capture the image of the skin. The captured image 14a by the UVAII, the captured image 14 by the UVB and the captured image 14c by the visible light are compared to specify the melanin monomer from components 15-18 emerged by the respective illumination lights. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a method for measuring a melanin monomer that visualizes and measures a melanin monomer that is a source of melanin for producing spots, freckles, and the like.

Spots and freckles are caused by an increase in black-brown melanin pigment. In order to create fair skin with no stains, it is considered not only to remove the created stains but also to prevent the formation of stains. In other words, it is an idea to prevent the production of eumelanin.
On the other hand, research has progressed and the generation mechanism of the melanin has been understood as shown in FIG. That is, tyrosine in the skin is changed to dopa and dopaquinone by tyrosinase and then changed to dopachrome, and further, DHI (5,6-dihydroxyindole) or a derivative thereof (5-hydroxy-6) is changed by dopachrome tomerase. -Methoxyindole, 6-hydroxy-5-methoxyindole) and DHICA (5,6-dihydroxyindole-2-carboxylic acid) or derivatives thereof (5-hydroxy-6-methoxyindole-2-carboxylic acid, 6-hydroxy- 5-methoxyindole-2-carboxylic acid) and eumelanin by tyrosinase and oxidase, respectively. And since the said enzyme raises activity with an ultraviolet-ray, a color becomes black as a result of a sunburn.

The above-mentioned DHI and DHICA and their derivatives are called melanin monomers, and are substances that are the source of black-brown eumelanin. Although the characteristics of each melanin monomer have not been elucidated, excessive production of eumelanin from the melanin monomer causes stains and the like.
Therefore, it is considered that the generation of stains should be able to be suppressed by taking some care at the stage up to the melanin monomer.
JP 2003-055260 A

However, at the stage of the melanin monomer, there is a problem that it does not look like melanin. That is, it is difficult to measure where and how much melanin monomer is produced.
Therefore, it is not possible to specify when, where, and what kind of treatment should be performed even if an attempt is made at the melanin monomer stage. For example, even when a whitening cosmetic product that has a function of preventing the transition from melanin monomer to eumelanin is developed, there is no other way to use it effectively at the stage where no stains or freckles are generated. could not.

In addition, when developing whitening cosmetics that act on melanin monomers or suppress the generation of melanin monomers, it is difficult to identify melanin monomers, so the effects of cosmetics under development can be reduced. It was not possible to evaluate accurately.
The objective of this invention is providing the measuring method of the melanin monomer which can pinpoint the presence of the melanin monomer which is not melanin.

The first invention is characterized in that the skin is imaged by irradiating with ultraviolet rays, and the melanin monomer is specified from the photographed image.
The second invention is premised on the first invention, and is characterized in that the ultraviolet rays irradiated to the skin are ultraviolet rays having a wavelength of 320 (nm) to 360 (nm) (hereinafter referred to as UVAII).

The third invention is premised on the first or second invention, and is characterized in that the ultraviolet rays applied to the skin are ultraviolet rays having a wavelength of 280 (nm) to 320 (nm) (hereinafter referred to as UVB).
The fourth invention is based on the first to third inventions described above, irradiates the skin with visible light, performs imaging with visible light, and compares the captured image with visible light with the captured image with ultraviolet light. Thus, it is characterized by specifying the melanin monomer.

  5th invention irradiates UVAII to the skin and shoots by UVAII, irradiates UVB and shoots by UVB, and compares the shot image by UVAII and the shot image by UVB to identify the melanin monomer It is characterized in that

According to the first to fifth inventions, it has become possible to visualize and measure the presence of a melanin monomer that could not be seen in the past.
Such a method for measuring a melanin monomer can be used for confirming or developing the effect of a whitening cosmetic product that acts on a melanin monomer to suppress melanization.

According to the second invention, among melanin monomers, in particular, DHICA and its derivatives can be visualized.
According to the third invention, DHI and DHICA and derivatives thereof can be visualized.

According to the fourth invention, it is possible to distinguish between a melanin monomer visualized by ultraviolet rays and a melanin visualized by visible light. That is, melanin and a melanin monomer can be distinguished and specified.
According to the fifth aspect, melanin, DHI or a derivative thereof, and DHICA or a derivative thereof can be distinguished and specified.

An embodiment of the present invention will be described with reference to FIGS.
The melanin monomer used as the measuring object of the measuring method of this invention is demonstrated.
As described above, the melanin monomer is a substance at the stage before becoming eumelanin (see FIG. 8), and there are two types, DHI and its derivatives and DHICA and its derivatives. The light absorption characteristics are shown in FIG. In FIG. 1, only DHI and DHICA are shown, but the respective derivatives also show similar light absorption characteristics.
Among ultraviolet rays of 400 nm or less, ultraviolet rays having a wavelength of 320 nm or more are referred to as UVA. Among them, the long wavelength side is referred to as UVAI and the short wavelength side is referred to as UVAII at 360 nm. 280 (nm) to 320 (nm) is referred to as UVB, and 280 (nm) or less is referred to as UVC.
DHI and its derivatives absorb wavelengths of about 320 (nm) or less, and DHICA and its derivatives absorb wavelengths of about 320 (nm) to 360 (nm) in addition to the above UVB and UVC.

None of the above melanin monomers are visible under visible light because they do not absorb in the visible region above 400 nm. In other words, the existence cannot be confirmed. These melanin monomers can be confirmed as a dark brown substance under visible light when the enzyme is activated by ultraviolet rays or melanin is formed by oxidation.
Melanin absorbs both visible light and ultraviolet light.

Since the above DHI and its derivatives and DHICA and its derivatives absorb ultraviolet rays in a specific wavelength region, when they are irradiated with ultraviolet rays in the absorption region, they absorb light and become dark, and their presence can be confirmed. The results of confirming this by experiment are shown in FIGS.
In this experiment, samples a, b, and c containing DHI, DHICA, and melanin are placed in a plurality of recesses 2 provided on the plate 1, and UVAII, UVB, and visible light are irradiated to the plate 1 for photographing. went. 2 to 4 are schematic diagrams of captured images obtained by the respective light beams.
Here, UVA II having a wavelength of 320 (nm) to 360 (nm) is irradiated as the ultraviolet light of the present invention, but ultraviolet light containing UVAI of 360 (nm) or more may be irradiated. However, since the above DHI and DHICA do not absorb the wavelength of UVAI, it is meaningless to irradiate only UVAI.

That is, FIG. 2 is a photographed image of UVAII on the plate 1, DHICA sample b that absorbs UVAII and melanin sample c appear black, but DHI sample a that does not absorb UVAII does not appear black. On the other hand, in the UVB photographed image of FIG. 3, all samples a, b, and c appear black.
Further, in the visible light of FIG. 4, only the melanin sample c appears black.
From these images, it was confirmed that DHI and DHICA, which cannot be seen with visible light, can be visualized by ultraviolet rays, and further, it has been confirmed that the type of melanin monomer visualized differs depending on the wavelength of ultraviolet rays to be irradiated.

However, since melanin looks black in both visible light and ultraviolet light, melanin monomer and melanin cannot be distinguished only from an ultraviolet image.
By comparing captured images with different wavelengths including visible light, the visualized melanin monomer and melanin can be distinguished and specified.

  Table 3 in FIG. 5 is a table showing melanin monomers or melanins that can be specified by combinations of irradiation light at the time of photographing. In this table, in the column corresponding to both the irradiation light arranged in the vertical direction and the irradiation light arranged in the horizontal direction, a melanin monomer or melanin that can be specified when the captured images by these irradiation lights are compared. Is displayed. However, in the column on the diagonal line, information related to an image by one type of irradiation light is displayed.

For example, in the column 4, what can be specified from the photographed image by UVAII is displayed. In UVAII, since the DHICA and melanin are displayed in black (see FIG. 2), both DHICA and melanin can be seen. However, the two cannot be distinguished.
In column 5, it is displayed that the DHI can be specified from the UVAII image (FIG. 2) and the UVB image (FIG. 3). That is, if there is something that does not appear in the UVAII image (FIG. 2) but appears in the UVB image (FIG. 3), it is DHICA.

Furthermore, as shown in column 6, DHICA and melanin can be identified and identified from UVAII and visible light images, and as shown in column 7, individual distinctions can be made from UVB images (FIG. 3). It is not possible to display all of DHI, DHICA, and melanin.
As in the column 8, DHI and DHICA and melanin can be distinguished from the UVB image (FIG. 3) and the visible light image (FIG. 4). It can be seen that what appears in the UVB image and does not appear in the visible light image is a melanin monomer. However, DHI and DHICA cannot be distinguished.
Moreover, only melanin can be specified with visible light (column 9).
As shown in FIG. 5 above, since the relationship between the combination of wavelengths of light rays used for photographing and the components that can be specified has been clarified, the state of the melanin monomer in the human skin can be measured based on this relationship.
It should be noted that, under the condition where the DHI is visualized, the DHI derivative is also visualized, and under the condition where the DHICA is visualized, the DHICA derivative is also visualized. Accordingly, as shown in Table 3 of FIG. 5, DHI can be read as a DHI derivative, and DHICA can be read as a DHICA derivative.

A method for actually measuring melanin monomer in a human face will be described with reference to FIGS.
6 includes a light source 10, a camera 11, and a controller 12 that is connected to the light source 10 and the camera 11 and controls them. The light source 10 is provided with an irradiation unit 13 for irradiating the subject 14 with light rays.
The light source 10 is configured to irradiate the subject 14 with visible light and ultraviolet light whose wavelengths are adjusted by operating the controller 12 via the irradiating unit 13.

In addition, the camera 11 is a camera for photographing the face of the subject 14 at a timing when ultraviolet rays or visible light is emitted from the irradiation unit 13 to the face of the subject 14. The image is displayed on the image display device.
This measuring apparatus A is installed in a dark room so that light from other than the light source 10 does not strike the subject 14 during photographing.

Below, the procedure which measures the melanin monomer of the said subject 14 with the said measuring apparatus A is demonstrated.
First, the wavelength of the light source 10 is adjusted, the subject 14 is irradiated with UVAII, and an image is taken by the camera 11. Next, the wavelength of the light source 10 is adjusted, the subject 14 is irradiated with UVB, and the image is taken.
Further, the subject 10 is irradiated with visible light, for example, purple light, and photographed.
The UVAII photographed image, the UVB image, and the visible light image are captured and displayed on the image display device.

FIG. 7 is a diagram showing an example of an image displayed on the image display device.
The face image 14a of the subject 14 by UVAII, the face image 14b by UVB, and the face image 14c by purple light are displayed side by side.
In each of the face images 14a to 14c, black portions 15 to 18 that are darker than the other portions appear. Black portions 15 and 16 appear in the UVAII face image 14a, black portions 15, 16, 17, and 18 appear in the UVB face image 14b, and black portions 15 appear in the face image 14c in purple light. .
In FIG. 7, the black portion is indicated by an ellipse, but in reality, the melanin monomer or the like may be dotted.
And in each face image 14a-14c, the same code | symbol is attached | subjected to the black part which has appeared in the same part.

When such three face images 14a to 14c are displayed, these images are compared, and based on FIG. 5 described above, it is determined whether each of the black portions 15 to 18 is due to melanin monomer.
First, since the black portion 15 appearing in the face image 14c can be seen with visible light, it can be identified as melanin.
Next, black portions 15 and 16 appearing in the face image 14a are DHICA or a derivative thereof, or melanin (see FIG. 5), and the black portion 15 is melanin. Therefore, the black portion 16 is specified as being DHICA or a derivative thereof. Finally, it is known that among the black portions 15, 16, 17, and 18 appearing in the face image 14b, the black portion 15 is melanin, and the black portion 16 is DHICA or a derivative of DHICA. Therefore, the remaining black portions 17 and 18 can be specified as DHI or DHI derivatives.

By the above procedure, melanin monomers such as DHI and DHICA that cannot be seen under visible light can be measured on the face of the subject 14.
In the above embodiment, an example in which a human specifies a melanin monomer based on an image captured by a camera has been described. However, the captured image is automatically analyzed by an image analysis means such as a computer, A melanin monomer can be distinguished, or a melanin monomer can be further distinguished and specified as DHI and DHICA. It is also possible to assume the amount of melanin monomer by analyzing the density of the image.

  In addition, in the face images 14a-14c shown in FIG. 7, each black part 15-18 has shown the example which each consists of a single component, but actually, melanin and a melanin monomer, or different melanin monomers are shown. Often mixed. For example, there are cases where a lot of DHICA is gathered and formed into a planar shape, and part of it is oxidized to melanin.

It is the graph showing the light absorption characteristic of a melanin monomer and melanin. It is a picked-up image at the time of irradiating UVAII to the melanin monomer and the sample of melanin. It is a picked-up image at the time of irradiating UVB to the sample of melanin monomer and melanin. It is a picked-up image at the time of irradiating a melanin monomer and the sample of melanin with visible light. It is the table | surface which showed the component which can be specified from the picked-up image which changed the kind of irradiated light. It is a schematic diagram of the measuring apparatus used when performing the melanin monomer measuring method in this invention. It is a display figure which shows the state which displayed the image image | photographed with the melanin monomer measuring apparatus on the image display apparatus. It is the figure which showed the production | generation process of melanin.

Explanation of symbols

14a, 14b, 14c Face images 15, 16, 17, 18 Black parts

Claims (5)

  A method for measuring a melanin monomer, in which the skin is irradiated with ultraviolet rays and photographing is performed with ultraviolet rays, and the melanin monomer is specified from the photographed image.   The method for measuring a melanin monomer according to claim 1, wherein the ultraviolet rays applied to the skin are ultraviolet rays having a wavelength of 320 (nm) to 360 (nm) (hereinafter referred to as UVAII).   The method for measuring a melanin monomer according to claim 1 or 2, wherein the ultraviolet rays applied to the skin are ultraviolet rays having a wavelength of 280 (nm) to 320 (nm) (hereinafter referred to as UVB).   4. The melanin monomer is identified by irradiating the skin with visible light, performing imaging with visible light, and comparing the captured image with visible light with the captured image with ultraviolet light. Method for measuring melanin monomer.   A method for measuring melanin monomer that irradiates the skin with UVAII and shoots with UVAII, shoots with UVB and shoots with UVB, and compares the shot image with UVAII and the shot image with UVB to identify the melanin monomer .

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