JP2008178572A - Optical regulation apparatus for body hair growth - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical regulation apparatus for body hair growth in which irradiation can be safely performed even from a location apart from a skin surface. <P>SOLUTION: The optical regulation apparatus for body hair growth has: a photoirradiation part 1 for body hair growth regulation which irradiates light accommodating the growth of body hair to the photoirradiation object section 5 of the human body; a water content measurement section 2 which measures the water content of the water content metering object section 4 of the human body; and a judgment section 3 which judges the propriety of the photoirradiation of the photoirradiation part 1 for body hair growth regulation from the result of the water content measurement section 2. Further, the water content measurement section 2 is provided with: a photoirradiation part 6 for metering which irradiates light containing 1,300 nm or more and 2,000 nm or less wavelength components to a water content metering object section 4; a light-intercepting element 7 which intercepts reflected light from the water content metering object section 4 to convert into an electric signal; and a signal analysis section 8 which analyzes an electric signal from the light-intercepting element 7 to determine the wavelength distribution of the reflected light and presumes water content from this wavelength distribution. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a light body hair regulating device that regulates the growth of body hair by light irradiation.

2. Description of the Related Art Conventionally, there has been known a laser light irradiation probe that performs treatment such as hair removal and hair growth by irradiating a skin with laser light as disclosed in Japanese Patent Application Laid-Open No. 2002-177405 (Patent Document 1). This laser beam irradiation probe incorporates a control circuit that controls the laser beam irradiation time by a timer and a power source, and projects a head part from the front of the case, opens the tip, and inserts a ball lens. An adjuster is detachably attached to the outer periphery of the. A contact sensor is attached to the tip of the adjuster to detect contact with the skin surface, and the irradiation switch is turned on only when the contact is made with the skin surface. As a result, it was possible to prevent an accident in which a laser beam irradiated from a distant place was seen and damaged.
JP 2002-177405 A

  However, since the laser light irradiation probe described in Patent Document 1 can irradiate laser light only when it comes into contact with the skin surface, the user must always bring the tip of the adjuster into contact with the skin surface during use. Lack of convenience. Further, in a state where the tip of the adjuster is in contact with the skin around the eye or the like, it is possible to irradiate the eye with laser light, and there is a possibility that the eye may be damaged if used by an infant by mistake.

  The present invention has been invented in view of the above-mentioned conventional problems, and provides a light hair growth control device that is highly convenient and has a low risk of damaging eyes even when an infant uses it incorrectly. It is in.

  In order to solve the above-mentioned problems, in the invention according to claim 1 of the present application, a light irradiation unit for adjusting hair growth that irradiates the light irradiation target part of the human body with light for adjusting the growth of body hair, and a water content measurement target part of the human body A moisture content measurement unit that measures the moisture content of the hair without measuring the moisture content measurement target unit, and a determination unit that determines whether or not the light irradiation unit for body hair growth adjustment light irradiation is possible based on the result of the moisture content measurement unit; It is characterized by having.

  Further, in the invention according to claim 2 of the present application, in the light body hair growth regulating apparatus according to claim 1, the moisture content measurement unit is configured to irradiate the moisture content measurement target unit with light containing a wavelength component of 1300 nm to 2000 nm. Light receiving part, light receiving element that receives reflected light from the moisture content measurement target part and converts it into an electrical signal, and analyzes the electrical signal from the light receiving element to determine the wavelength distribution of the reflected light, and from this wavelength distribution And a signal analysis unit for estimating the moisture content.

  The invention described in claim 3 of the present application is characterized in that, in the optical hair growth control apparatus described in claim 2, a plurality of light receiving elements are two-dimensionally arranged.

  The invention according to claim 4 of the present application is characterized in that, in the optical hair growth control apparatus according to claim 2 or 3, a polarizing filter is provided in the measurement light irradiation unit and the light receiving element.

  In the light body hair growth regulating device of the present invention, since it has a moisture content measurement unit that measures the moisture content of the moisture content measurement target part of the human body without contacting the moisture content measurement target part, it contacts the moisture content measurement target part. Even if not, it is possible to determine whether or not light irradiation is possible by estimating whether or not the light irradiation unit for controlling hair growth is skin. Therefore, when the moisture content measurement target part is skin, the light irradiation part for body hair growth adjustment can be safely irradiated even from a position away from the skin, and convenience is increased. In addition, since it is not necessary to bring a part of the light hair growth regulating device into contact with the skin, the user does not feel uncomfortable.

  Hereinafter, the present invention will be described based on embodiments shown in the accompanying drawings.

  FIG. 1 shows an optical hair growth control apparatus according to a first embodiment corresponding to claims 1 and 2 of the present application. The light body hair growth adjustment apparatus includes a body hair growth adjustment light irradiation unit 1, a moisture content measurement unit 2, and a determination unit 3.

  The hair growth adjusting light irradiation unit 1 uses a xenon flash lamp as a light source, and irradiates light irradiation target unit 5 including human skin and the like with light for adjusting the growth of body hair.

  The moisture content measurement unit 2 measures the moisture content of the moisture content measurement target unit 4 including human skin, and irradiates the moisture content measurement target unit 4 with light containing a wavelength component of 1300 nm to 2000 nm. Measuring light irradiating unit 6, light receiving element 7 that receives reflected light from moisture content measurement target part 4 and converts it into an electrical signal, and analyzes the electrical signal from light receiving element 7 to determine the wavelength distribution of the reflected light And a signal analysis unit 8 that obtains and estimates the water content from the wavelength distribution. The light receiving element 7 receives light from the incident direction with respect to the moisture content measurement target unit 4 of the measurement light irradiation unit 6 and a direction of 45 °.

  In this way, light in the near infrared region, which is light including a wavelength component of 1300 to 2000 nm, is applied to the skin of the human body, which is the moisture content measurement target part 4 containing moisture, and water content is determined from the reflectance of the near infrared rays. Since the rate is measured, it can be instantaneously measured without contact with the moisture content measurement target unit 4. In addition, the light emitted from the measurement light irradiating unit 6 can measure the moisture content even when using low-power light, and even if this light is accidentally irradiated to the eye, it is damaged. Never give. Therefore, the moisture content can be measured nondestructively, and safety can be ensured even if an infant uses it by mistake.

  Based on the result of the moisture content measuring unit 2, the determining unit 3 determines whether or not the light irradiation unit 1 for adjusting hair growth can be irradiated.

  FIG. 2 shows a flowchart for determining whether or not the light irradiation unit 1 for adjusting hair growth can be irradiated.

  First, a spectral absorption value (L1) in a wavelength band that absorbs moisture is obtained. Specifically, the measurement light irradiation unit 6 irradiates the human skin that is the moisture content measurement target unit 4 with light including a wavelength component of 1300 nm or more and 2000 nm or less, and the light receiving element 7 reflects the reflected light from the human skin. The light is received and converted into an electrical signal, and the signal analysis unit 8 analyzes the electrical signal from the light receiving element 7 to obtain a spectral absorption value (L1) of 1450 nm ± 5 nm, which is a wavelength band for absorbing moisture (S1).

  Next, a spectral absorption value (L0) of 570 nm ± 5 nm which is a wavelength band depending on melanin is obtained. Specifically, the measurement light irradiation unit 6 irradiates the human skin, which is the moisture content measurement target unit 4, with light including a wavelength component of 1300 to 2000 nm, and the light receiving element 7 receives the reflected light from the human skin. Then, the signal is converted into an electric signal, and the signal analysis unit 8 analyzes the electric signal from the light receiving element 7, and obtains a spectral absorption value (L0) of 570 nm ± 5 nm which is a wavelength band depending on melanin (S2).

  Next, the signal analysis unit 8 calculates the ratio of the spectral absorption value (L1) of 1450 nm ± 5 nm which is a wavelength band for absorbing moisture and the spectral absorption value (L0) of 570 nm ± 5 nm which is a wavelength band depending on melanin. The moisture content (K) is output. Specifically, the value of the moisture content (K) is obtained from the equation “K = L1 / L0” (S3).

  Next, the determination unit 3 determines whether the moisture content (K) output from the signal analysis unit 8 is a value within the set range (S4). As a result, if the moisture content (K) is a value within the set range, it is determined that the moisture content measurement target unit 4 is human skin (S5). If the moisture content (K) is not a value within the set range, it is determined that the moisture content measurement target unit 4 is not human skin (S6).

  Through such a safety confirmation step, the photohair growth control apparatus sets the moisture content measurement target part 4 as the light irradiation target part 5 only when the moisture content measurement target part 4 is skin, and this light irradiation target. The unit 5 is irradiated with light from the body hair growth adjusting light irradiation unit 1. By the above procedure, eyes and skin having different moisture contents can be distinguished, and even if an infant misuses, there is a low risk that the eyes will be irradiated with intense light emitted from the light irradiation unit for hair growth control. Become.

  Here, a plurality of the light receiving elements 7 may be arranged two-dimensionally. When a plurality of light receiving elements 7 are arranged two-dimensionally, the moisture content can be measured over a wide range. For this reason, it can be estimated whether it is the skin of a human body about the moisture content measurement object part of a wider range, and safety improves.

  In addition to the water content measurement method described above, the same use and effect can be achieved by measuring the water content using a microwave method or a dielectric constant method.

  FIG. 3 shows an optical hair growth control apparatus which is a second embodiment corresponding to claims 1 to 4 of the present application.

  Here, only matters (configuration, operational effects, etc.) that are different from those in the first embodiment will be described, and the other items are the same as those in the first embodiment, and the description thereof will be omitted.

  The optical hair growth control apparatus of this embodiment is provided with polarizing filters 9 and 9 ′ in front of the measurement light irradiation unit 6 and the light receiving element 7, respectively. Whereas the object whose moisture content is to be measured is inside the skin, when the skin is irradiated with light from the measurement light irradiation unit 6, the skin surface reflects about 70% of the irradiated light. For this reason, most of the light received by the light receiving element 7 is reflected light from the skin surface, and the reflected light from the inside of the skin cannot be measured accurately. However, the light transmitted through the skin changes in polarization angle, whereas the reflected light on the skin surface has the same polarization angle as the irradiation light. Here, if the measurement light irradiation unit 6 emits light polarized at a predetermined polarization angle and the light receiving element 7 can receive only light polarized at the polarization angle of the reflected light inside the skin, By excluding the reflected light from the measurement target, only the light transmitted and reflected inside the skin can be measured.

  The optical hair growth control apparatus of the present embodiment is provided with a polarizing filter 9 in front of the measurement light irradiation unit 6 so that light polarized at a predetermined polarization angle can be irradiated. Further, in front of the light receiving element 7, a polarizing filter 9 ′ that transmits only light polarized at the polarization angle of the reflected light inside the skin is installed. By doing so, the light receiving element 7 can receive only the light transmitted and reflected inside the skin and can not receive the reflected light on the skin surface. As a result, the moisture content inside the skin can be accurately measured, and safety is improved.

  Hereinafter, the light irradiation unit 1 for body hair growth adjustment in the light body hair growth regulation apparatus of each embodiment will be described in detail.

  In the case of Japanese, the spectral reflectance of the skin is reduced in the vicinity of 400 to 600 nm, as can be seen from the spectral reflectance distribution of the three shown in FIG. 4, and absorbs light in this wavelength range. It has the characteristic that it is easy to do. This is greatly influenced by melanin present in the skin. FIG. 5 shows the spectral characteristics of the absorbance of melanin alone, which absorbs 39% of the irradiation light at 567 nm.

  For this reason, when irradiating light from the body hair growth adjusting light irradiating unit 1, light having a wavelength band of 400 to 600 nm that is easily absorbed by the skin can be used to stimulate the hair with low-power light. . Note that ultraviolet rays having a wavelength of 400 nm or less harmful to the skin may be cut by providing a UV cut filter or the like in front of the light irradiation unit 1 for controlling hair growth.

  As the amount of light emitted from the light source, which is a xenon flash lamp, light of 1.5 million to 7 million lux is irradiated for a flash time (half value of peak power) of 100 to 700 μs.

  Further, the irradiation energy (J / cm 2) is a product of the irradiation power (W) and the irradiation time (second), and the irradiation power (W) and the irradiation so that the irradiation energy K becomes, for example, 0.1 J / cm 2. By controlling the time (seconds), it is possible to reliably suppress the occurrence of side effects due to light irradiation. Accordingly, the latter is lower when the irradiation is performed once / day at intervals of several days and when the irradiation is repeated continuously for about 5 to 10 days. A power light source can be used.

  Here, it is known that hair (body hair) has a hair cycle that changes in a cycle from a growth phase to a regression phase and a resting phase. If the skin is irradiated with light under the irradiation conditions, there is no change in cell morphology as seen with existing medical lasers, no cell destruction occurs, and the hair cycle The present inventors have confirmed through mouse experiments that hair growth is effectively suppressed if light irradiation is carried out during the growth period. It has also been confirmed that if light is irradiated during the rest period of the hair cycle, the hair growth proceeds rapidly in the growth phase of the hair cycle. It has also been confirmed that there are no side effects such as burns.

  It is not clear why the growth of hair is suppressed when light irradiation is performed at a level that does not cause changes in cell morphology during the growth phase, but the analysis results at the RNA level indicate that the activity of inflammatory cytokines is due to the light irradiation. It is considered that the activation of the inflammatory cytokine brings about the suppression of hair growth described above.

In addition, the said irradiation power shall be changed according to the change rate of the spectral reflectance of the skin of light irradiation object on the basis of the spectral reflectance of 500-600 nm which produced the effect in the change of the hair cycle. Assuming that the reflectance of the reference specific wavelength is R0, the reflectance of the skin to be irradiated is R1, and the power of the light source that has achieved the activity of inflammatory cytokines on the skin of R0 is P0, the required irradiation power P is:
P = Rl / R0 × P0
Can be obtained. Since the energy affecting the hair cycle is a constant value, when the spectral reflectance of the skin is high, the irradiation time may be shortened by increasing the irradiation power.

  In addition, since each period of the growth period, regression period, and rest period in the hair cycle differs depending on the place such as the arm, hair, etc., it was determined whether or not it is in the growth period depending on the place where hair growth suppression is desired. Above, light irradiation is performed.

  Here, in embodiment of this invention, although the different irradiation part is used for the light irradiation part 1 for body hair growth adjustment, and the light irradiation part 6 for measurement, it is also possible to use the same irradiation part. By doing so, the number of parts can be reduced and the cost can be reduced. However, in this case, when the irradiation unit is used as the measurement light irradiation unit, the irradiation power of the irradiation light is lowered, and when the irradiation unit is used as the body hair growth adjustment light irradiation unit, the irradiation light It is necessary to increase the irradiation power.

It is a block diagram which shows the optical hair growth control apparatus which is 1st embodiment of this invention. It is a flowchart which shows operation | movement of the optical body hair growth control apparatus same as the above. It is a block diagram which shows the optical hair growth control apparatus which is 2nd embodiment of this invention. It is a graph which shows the measurement result of the spectral reflectance of three people's skin. It is a graph which shows the light absorbency of a melanin single-piece | unit.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Light irradiation part for body hair growth adjustment 2 Moisture content measurement part 3 Judgment part 4 Moisture content measurement object part 5 Light irradiation object part 6 Measurement light irradiation part 7 Light receiving element 8 Signal analysis part 9, 9 'Polarization filter

Claims (4)

  Moisture content that measures the moisture content of a human hair growth control light irradiation unit that irradiates the light irradiation target part of the human body with light that regulates the growth of body hair and the moisture content measurement target part of the human body without contacting the moisture content measurement target part An optical hair growth control apparatus comprising: a rate measurement unit; and a determination unit that determines whether or not the light irradiation unit for body hair growth adjustment can be irradiated based on a result of the moisture content measurement unit.   The moisture content measuring unit receives a measurement light irradiating unit that irradiates light containing a wavelength component of 1300 nm or more and 2000 nm or less to the moisture content measuring target unit, and receives reflected light from the moisture content measuring target unit and converts it into an electrical signal. And a signal analyzing unit for analyzing the electrical signal from the light receiving element to obtain a wavelength distribution of the reflected light and estimating a moisture content from the wavelength distribution. The light hair growth control apparatus according to 1.   The light body hair growth regulating apparatus according to claim 2, wherein a plurality of the light receiving elements are two-dimensionally arranged.   The optical hair growth control apparatus according to claim 2 or 3, wherein a polarizing filter is provided in the measurement light irradiation unit and the light receiving element.

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