JP2000245525A - Laser therapy instrument - Google Patents

Abstract

PROBLEM TO BE SOLVED: To set optimal laser irradiation condition according to the state of treatment site without depending the operator's experience by having a detecting means, which detects the thickness of hair within the laser irradiation for treatment, and a variable means for irradiation, which is able to change the condition of laser irradiation for treatment based on the detected result. SOLUTION: In advance, week output laser for treatment is diffused and irradiated as detection to the predetermined region of surface of skin that is the region of laser irradiation on treatment time, and then the temperature distribution of the area is imaged with a thermograph 6. The position of each pore is changed to the coordinate position, and the information of position and the information of size at each position are stored in a control part 20. When the command signal of the laser for depilation, a scanner controller 24 drives driving motors 14a and 14b based on the stored information of position, and the control part 20 controls the driving of laser source 21 to irradiate each one with changing the irradiating condition of laser irradiation output and irradiation time to be optimal according to the thickness of hair.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a laser treatment apparatus for performing treatment by irradiating a treatment site with treatment laser light.

[0002]

2. Description of the Related Art There is known a laser hair removal treatment in which hair growing on a body is irradiated with a laser beam to cauterize a hair root to remove hair. Since the periphery of the hair root contains more melanin than the surrounding skin epidermis, by irradiating a laser beam having a wavelength that is easily absorbed by the melanin, the heat energy is radiated to the hair root and the hair root is cauterized.

[0003]

In the conventional laser hair removal treatment, irradiation conditions such as laser light output and irradiation time are set in consideration of differences in hair conditions depending on body parts. Depends greatly on the experience of the elderly. If the laser light output is too strong or the irradiation time is set too long, the possibility of damaging the skin other than the hair roots increases. On the other hand, if the output of the laser beam is too weak or the irradiation time is insufficient, hair removal in the laser irradiation range may not be performed reliably and efficiently.

[0004] In view of the above-mentioned drawbacks of the conventional apparatus, the present invention can set optimum laser irradiation conditions in accordance with the condition of the treatment site without depending on the experience of the operator, thereby suppressing damage to the skin. It is an object of the present invention to provide a device capable of efficiently performing treatment (hair removal).

[0005]

Means for Solving the Problems In order to solve the above problems, the present invention is characterized by having the following configuration.

(1) In a laser treatment apparatus for performing epilation treatment by irradiating a treatment laser beam from a laser light source, detection means for detecting the thickness of the hair in the irradiation range of the treatment laser beam, and based on the detection result. Irradiation varying means for varying irradiation conditions of the treatment laser light.

(2) The irradiation varying means of (1) is characterized in that at least one of irradiation conditions of a treatment laser beam or a laser output is varied.

(3) The detecting means of (1) includes an image pickup means for picking up an image of the irradiation range of the treatment laser beam, and determines the thickness of the hair at each pore position based on image data picked up by the image pickup means. It is characterized by detecting.

(4) The laser treatment apparatus according to (1), further comprising: detection laser light irradiation means for irradiating the irradiation area of the treatment laser light with a detection laser light which causes a change in temperature in response to melanin. The means has a thermograph that detects a temperature distribution that changes due to the irradiation of the detection laser light, and detects a pore position and a hair thickness at each position based on an output signal of the thermograph. .

(5) In the laser treatment apparatus according to (4), the detection laser light irradiation means irradiates the treatment laser light with an output weaker than an output required for treatment.

(6) The laser treatment apparatus according to (4), further comprising a selective irradiating means for selectively irradiating each of the pore positions with therapeutic laser light based on the pore position information detected by the detecting means. Features.

(7) The laser treatment apparatus according to any one of (1) to (6), wherein the emitted treatment laser light is an alexandrite laser.

(8) In a laser treatment apparatus for irradiating a treatment site with a treatment laser beam from a laser light source, a detection means for detecting a size of the treatment site in an irradiation range of the treatment laser beam, and based on the detection result, And an irradiation variable unit that changes irradiation conditions of the treatment laser light.

[0014]

Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic external view of a laser treatment apparatus for hair removal according to an embodiment.

Reference numeral 1 denotes a laser device main body, in which a control unit, a laser light source for hair removal, and the like, which will be described later, are housed. Reference numeral 7 denotes a control panel for inputting various setting conditions such as laser irradiation conditions, and reference numeral 8 denotes a foot switch for transmitting a trigger signal for irradiating a laser beam. Key switch 9 is provided.

Reference numeral 2 denotes an optical fiber for guiding laser light emitted from the apparatus main body 1, and reference numeral 3 denotes a handpiece unit having a laser irradiation port. Handpiece unit 3
There is a thermograph 6 of a CCD camera sensitive to infrared rays
The thermograph 6 is used to recognize the position of the pores (hair roots) and the thickness of the hair based on the temperature difference on the skin surface before performing the hair removal treatment (this recognition method will be described later in detail). ).

FIG. 2 is a view showing the configuration of the handpiece unit 3. The handpiece unit 3 is the scanner unit 1
1 and a handpiece head 12. A lens 10 (see FIG. 3) for forming the laser beam for hair removal, which has passed through the optical fiber 2, into a small spot having a diameter of about 2 mm on the irradiation site in the scanner unit 11.
Drive mirrors 13a and 13 for scanning in the Y direction
b, drive motors 14a and 14b, and a lens 15 inserted into and removed from the optical path of laser light. The lens 15 is inserted into the optical path when recognizing the position of the pore, and diffuses the laser light on the skin surface. The drive motor 1 inserts and removes the lens 15
6 is performed. The handpiece head 12 is
A head tip 17 is provided for abutting the skin and stabilizing the handpiece unit.

FIG. 3 is a main block diagram showing the configuration of the control system and the optical system. A control unit 20 controls the entire apparatus. Reference numeral 21 denotes a laser light source for hair removal. In this embodiment, an alexandrite laser (wavelength: 755 nm) is used. The laser light from the laser light source 21 is
After being reflected at 2 and 23, the light is condensed and incident on the optical fiber 2 by the lens 28. Reference numeral 24 denotes a scanner controller which controls driving of the drive motors 14a and 14b. A control signal from the scanner controller 24 is transmitted to the scanner unit 11 via the connector unit 5 and the cable 4, and the drive mirrors 13a and 13b are controlled to swing. Reference numeral 25 denotes an image processing unit for processing the image obtained by the thermograph 6 to detect the position of the pore and its size (the thickness of the hair).

A method for detecting the position and size of pores from an image obtained by the thermograph 6 will be described.

In the laser hair removal treatment, the skin is irradiated with laser light having a wavelength easily absorbed by melanin, and the heat energy of the laser light absorbed by the melanin is radiated to the hair root, thereby cauterizing the hair root and performing hair removal. Therefore, the place where a large amount of melanin is collected absorbs the thermal energy of the laser beam, so that the temperature of that part is temporarily increased.
Melanin is distributed along the skin surface (epithelium), hair roots, and pores, but its distribution density is much higher in the hair root than in other areas, and more energy is absorbed. Also,
In general, the thicker the hair, the greater the amount of melanin around the hair root, so that when laser light is irradiated, a thicker portion of the hair has a larger calorific value than a thinner portion of the hair. By taking advantage of this, a predetermined area of the skin surface, which is a laser beam irradiation area during treatment, is irradiated with a therapeutic laser beam of a weak output (to the extent that does not cause damage to the skin) for detection in advance. In advance, the temperature distribution in that region is imaged by the thermograph 6. If the place where the temperature is high is identified based on this image, the position of the pore can be specified, and the thickness and size of the hair at each position can be detected based on the size of the central temperature area.

FIG. 4 shows the thermograph 6 in the image processing unit 25.
FIG. 5 is a diagram schematically showing a state of a temperature distribution obtained by processing an image according to FIG. Reference numeral 30 denotes a laser beam irradiation range.
Numeral 31 is an isotherm, and the inner isotherm has a higher temperature. Therefore, in this example, the centers A,
B, C, and D are detected as pore positions. Further, from the size of the isothermal area at the center, the pore thicknesses E, F, G, and H at each position are detected as shown in the figure.

When the thermograph 6 is used, it is desirable that the imaging is performed within the thermal relaxation time of the follicles after the irradiation of the laser beam. The thermal relaxation time means that when a target (in this case, melanin) is irradiated with a laser beam, the temperature distribution around the target becomes a Gaussian distribution having a width determined by its diameter, but the central temperature of the distribution drops to 50%. It is time until.

Generally, the thermal relaxation time of melanin is about 10 ns.
ec to 1 μsec, the thermal relaxation time of the hair root is 20 mm
It is about 40 msec to 100 msec at 0 to 400 μm. After irradiating the target with the laser beam, the temperature of melanin rises rapidly until the thermal relaxation time, but when the thermal relaxation time is exceeded, the temperature changes to a gradual rise in temperature while releasing heat. At this time, the thermal energy radiated from the melanin is transmitted to the hair root, and the temperature rises similarly until the thermal relaxation time of the hair root. As a result, while the thermal relaxation time of the hair root continues, a temperature difference from the surroundings tends to occur. If the heat relaxation time of the hair root is exceeded, a rise in temperature at the hair root is suppressed, and at the same time, heat is conducted to the surroundings. For this reason, after exceeding the thermal relaxation time of the hair root for a very long time, it is difficult for the temperature difference between the pore and the surrounding area to appear, and it is considered that the recognition of the pore becomes difficult.

The position and size of the pores can be detected as follows. For example, a CCD camera having sensitivity in the visible region is used instead of a thermography CCD camera, and an actual skin condition irradiated with hair removal laser light is imaged. The position of the pores, the thickness of the hairs, and the like are recognized based on the color, shape, and the like obtained from the captured image. In addition, irradiation with light that emits fluorescence in response to melanin, or pre-administration of a fluorescent agent that reacts to melanin and causes no harm to the living body is imaged, and the state is imaged. Is detected.

Next, the operation in laser treatment will be described. Before irradiating the laser beam, the surgeon shaves the hair in an area where the hair is to be removed, and applies a cooling gel or the like to the skin.
Next, after performing various necessary settings on the device side with the control panel 7, the target treatment area is set to the handpiece head 1.
The head tip 17 of the handpiece unit 3 is brought into contact with the skin so that the head tip 17 is located below the skin 2. In this state, the handpiece unit 3 is stabilized, and a scan switch (not shown) for recognizing pore positions on the control panel 7 is pressed.

When the scan switch is pressed, the control unit 2
Reference numeral 0 denotes a state in which the drive motor 16 is driven to insert the lens 15 into the laser beam path, and then a laser beam having a weak output from the laser light source 21 (1/20 to laser output used for treatment).
(About 1/100) is emitted as laser light for pore position recognition. Generally, the output of laser light used for hair removal is 1
Since it is 0 to 40 J / cm ² , the output of the laser light for pore position recognition is preferably about 0.1 to ² J / cm ² .

The laser light emitted from the laser light source 21 for pore position recognition is guided to the handpiece unit 3 by the optical fiber 2. The laser light emitted from the optical fiber 2 is made to have a diameter of about 1 to 2 mm by the lens 10, but is diffused by the lens 15 to irradiate an area of about 2 cm in diameter at a time. In this case, the driving mirror 13
a and 13b are placed at the reference positions by initialization.

When the skin is irradiated with the laser beam, as described above, the thermal energy from the laser beam is accumulated in the melanin, and a temperature difference occurs between the hair root and the surrounding area. The region irradiated with the laser is imaged by the thermograph 6 at a timing within the thermal relaxation time of the hair root, and the temperature distribution information is obtained by the image processing unit 25. From the temperature distribution information, the position and size of the pore are detected as described above. The position of each pore is replaced with a coordinate position, and the position information and the size information at each position are stored in the control unit 20.

When the detection by the image processing means 25 is completed, the control section 20 notifies the operator of the completion of the pore position recognition by using an electronic sound or a monitor (not shown) provided on the control panel 7. At the same time, the lens 15 is retracted from the laser beam path, and irradiation by scanning of a hair removal laser beam having a diameter of 1 to 2 mm is enabled.

The surgeon presses the foot switch 8 while holding the handpiece unit 3 to issue a hair removal laser beam irradiation command to the apparatus. When the command signal is input,
The scanner controller 24 drives the drive motors 14a and 14b based on the stored position information,
Controls the timing of laser emission from the laser light source 21. In the example of FIG. 4, first, the scanner controller 2
Numeral 4 adjusts the angles of the drive mirrors 13a and 13b so that the pore position A is irradiated with the laser beam. The control unit 20 causes the laser light source 1 to emit laser light at the timing when the angle can be adjusted. Next, the laser light is emitted by adjusting the angles of the driving mirrors 13a and 13b so that the pore position B is irradiated with the laser light, and the laser light is sequentially transmitted to the pore positions C and D. In this way, by controlling the emission of the laser beam and the scanning thereof, the laser beam is selectively applied to each of the pore positions A to D, so that damage to surrounding tissues can be reduced.

At this time, the control unit 20 changes the laser light source 2 so as to irradiate each laser beam while changing the irradiation conditions and the irradiation time of the optimum laser beam according to the thickness of the hair at each pore position.
1 is controlled.

The laser irradiation output and irradiation time according to the thickness of the hair will be described. The principle of laser hair removal is that laser light is absorbed by melanin present around the hair root, and the stored heat is transmitted to the hair root to be destroyed. At this time, it is necessary to irradiate the laser with energy that does not destroy the melanin or epithelium and that is sufficient to burn the hair root for a time longer than the thermal relaxation time of the melanin or the skin and shorter than the thermal relaxation time of the hair root. The thermal relaxation time of melanin is about 10 nsec.
The heat relaxation time of the epithelium is 1 msec, the heat relaxation time of the epithelium is 3 to 10 msec, and the heat relaxation time of the hair root is about 40 msec to 100 msec. However, the above-mentioned thermal relaxation time differs depending on the thickness of the hair root (hair thickness). If the laser irradiation time is longer than that time, the stored energy is diffused to the surroundings, and the hair root breaking effect is reduced. Therefore, the laser irradiation time is adjusted in the range of 10 to 40 msec. Furthermore, in order to perform efficient hair removal without causing unnecessary rise in skin temperature, a laser having an output corresponding to the thickness of the hair root is irradiated. The optimum laser output and irradiation time according to the thickness of the hair root may be quantitatively determined in advance, and may be determined based on the data.

In the above description, an example in which laser light is selectively applied to each pore position has been described. However, a laser beam having a diameter of 10 to 20 mm is applied without a scanner mechanism, and hair follicles in the area are removed. Even in the case of batch irradiation in which all treatment (cauterization) is performed, the thickness of each hair within the area is detected, and the apparatus automatically sets the optimal irradiation conditions of the laser beam based on the information. Even a person with shallow skin can effectively treat (hair removal) by suppressing damage to the skin as much as possible.
That is, even in the case of batch irradiation, the laser output and irradiation time are set for each region in accordance with the place where the thickness of the hair is the thickest. Thus, appropriate laser irradiation is performed at least for each region. In the case where batch irradiation is performed by the apparatus of the present embodiment, the irradiation may be performed with the lens 15 inserted during irradiation of the hair removal laser beam.

In addition, although the thickness of the hair may differ depending on the area of the hand, the foot or the like, the batch irradiation is more suitable for the patient with less variation in the hair thickness in the same area. May be economically advantageous without complicating it.

Further, if a mechanism for switching between a mode for selectively irradiating and a mode for batch irradiating is provided and the mode is selectively used according to the judgment of the surgeon, the hair can be more efficiently removed.

As described above, in the present embodiment, an alexandrite laser beam is used as the laser beam. However, the present invention is not limited to this, and any laser beam having a wavelength that is easily absorbed by melanin and reaches melanin around hair roots may be used. Specific examples include a ruby laser and a diode laser.

[0037]

As described above, according to the present invention,
Since the laser irradiation conditions are set in accordance with the thickness of the hair in the laser irradiation area, the hair removal can be performed efficiently without depending on the experience of the operator and while reducing the damage to the skin. In addition, since appropriate laser irradiation conditions are set for each hair, hair removal can be performed more reliably. Furthermore, it is not necessary to increase the energy per unit time required for laser hair removal, and it is also possible to reduce the size of the apparatus and improve the hair removal processing ability.

[Brief description of the drawings]

FIG. 1 is a diagram showing an appearance of an apparatus.

FIG. 2 is a diagram showing details of a handpiece unit.

FIG. 3 is a block diagram showing an optical system and a control system.

FIG. 4 is a schematic diagram showing a temperature distribution on the skin when a laser beam is irradiated.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Device main body 3 Handpiece unit 6 CCD camera 7 Control panel 8 Foot switch 20 Control part 21 Laser light source 24 Scanner controller 25 Image processing part

Claims (8)

[Claims] 1. A laser treatment apparatus for irradiating a treatment laser beam from a laser light source to perform a hair removal treatment, wherein a detection means for detecting the thickness of the hair in an irradiation range of the treatment laser beam;
An irradiation varying means for varying irradiation conditions of the treatment laser light based on the detection result. 2. A laser treatment apparatus according to claim 1, wherein the irradiation variable means changes at least one of irradiation time of a treatment laser beam and laser output. 3. The detecting means according to claim 1, further comprising an image pickup means for picking up an image of an irradiation range of said therapeutic laser beam, and detecting a thickness of a hair at each pore position based on image data picked up by said image pickup means. A laser treatment apparatus characterized by performing the following. 4. The laser treatment apparatus according to claim 1, further comprising: a detection laser beam irradiation unit that irradiates a laser beam for detection, which generates a temperature change in response to melanin, to an irradiation range of the treatment laser beam, wherein the detection unit Has a thermograph that detects a temperature distribution that changes due to the irradiation of the detection laser light, and detects a pore position and a hair thickness at each position based on an output signal of the thermograph. Treatment device. 5. The laser treatment apparatus according to claim 4, wherein said detection laser light irradiation means irradiates said treatment laser light with an output weaker than an output required for treatment. 6. The laser treatment apparatus according to claim 4, further comprising a selective irradiating means for selectively irradiating each of the pore positions with therapeutic laser light based on pore position information detected by said detecting means. Laser treatment device. 7. The laser treatment apparatus according to claim 1, wherein the emitted treatment laser beam is an alexandrite laser. 8. A laser treatment apparatus for irradiating a treatment site with a treatment laser beam from a laser light source, a detecting means for detecting a size of the treatment site in an irradiation range of the treatment laser beam, and the treatment based on the detection result. A laser treatment device, comprising: irradiation varying means for varying irradiation conditions of laser light.