Multi-Beam Laser for Skin Treatment

[0001] This invention relates to lasers and in particular to lasers for cosmetic treatments.

BACKGROUND OF THE INVENTION

[0002] Use of lasers for medical purposes is well established. Lasers are used extensively for purposes such as hair removal, vein treatment, skin rejuvenation and treatment of port wine stain. Each of these treatments is preferably performed by medical practitioners with a laser producing laser pulses at a wavelength chosen to be most effective for the particular treatment. Some wavelengths are very preferentially absorbed in a particular type of tissue. Some wavelengths are highly absorbed in skin tissue with penetration depths of only a few microns. Other wavelengths have absorption coefficients substantially less than I/cm and penetrate substantial depths in skin and other tissue. FIGS. 4 and 5 show absorption coefficients as a function of wavelengths for blood, human skin and melanin. A Nd: YAG laser operating at 1320 nm (with high absorption in skin tissue) may be used for skin rejuvenation and micro skin surgery. Treatment of port wine stains is usually performed using a dye laser operating at a wavelength of 577 nm and 585 nm where the absorption in blood hemoglobin is high but absorptionin the skin tissue is relatively low.

[0003] Use of a laser beam matched to a peak or relatively high absorption in tissue to treat the tissue is referred to as "selective thermolysis". When wavelengths which penetrate deeply and are absorbed relatively uniformly in tissue are used to treat the tissue, the treatment is referred to as "non-selective thermolysis".

[0004] Beautiful young looking skin is very important to most people, especially women. They spend billions of dollars each year in their efforts of look their best. Skin treatments often provide only temporary help and need to be repeated. Laser treatments at medical and cosmetic facilities are expensive.

[0005] What is needed is a skin treatment laser device suitable for home use.

SUMMARY OF THE INVENTION

[0006] The present invention provides a skin treatment laser device suitable for home use. The device includes an array of at least two types of laser units. A first type of laser units operates at a wavelength chosen to heat the skin generally and a second type of laser units operates at a wavelength chosen to produce tissue damage in extremely small and separated regions of the skin. No skin damage occurs in tissue surrounding the regions of skin transformation or destruction. Natural healing processes originating in the surrounding tissue heal the damaged tissue and produce general rejuvenation effects in the skin tissue. Laser beams from at least the second type of laser units are focused into the small regions to be damaged. A preferred focusing technique utilizes cold sapphire cylindrical rods. Preferably, the skin to be treated is shaved or abraded prior to or simultaneously with the laser treatment to remove portion of the stratum corneum so to improve laser beam penetration. In preferred embodiments the device includes shaving blades so that skin hair and or a thin layer of skin can be removed simultaneously with the laser treatment. In other embodiments an abrading feature is included. Uses include skin rejuvenation and hair removal.

BRIEF DESCRIPTION OF THE DRAWINGS

[0007] FIGS. IA, IB and 1C are drawings of a preferred embodiment of the present invention.

[0008] FIGS. ID and IE show beam paths into the skin and features for removing a portion of the stratum corneum. [0009] FIGS. 2 and 3 are drawings showing human skin features.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0010] Preferred embodiments of the present invention may be described by reference to the drawings.

First Preferred Embodiment

[0011] A first preferred embodiment of the present invention may be described by reference to FIGS. IA, IB, 1C and ID. This device 2 includes twelve diode lasers 4 operating at a wavelength chosen to heat the skin generally to temperatures a few degrees below temperatures at which damage begins to occur at depths down to about 2 millimeters. Device 2 also includes six diode lasers 6 operating at wavelengths chosen to produce skin damage in very small regions of the skin. The device also includes three cylindrical sapphire focusing lenses 8 aligned with the lasers as shown in FIG. IB, 1C and ID. Light from diode lasers 6 is tightly focused into a small region of the skin since at wavelengths of lasers 6 is very absorptive in skin and produces relatively little scattering. However, light from lasers 4 are not focused tightly by lenses 8 since light at its wavelengths are scattered widely by skin tissue. This first preferred embodiment also includes blades 10 for cutting hair on the skin. Preferably the blades are replaceable, The blades serve two purposes (1) they remove any hair at the skin surface and (2) they remove a portion to the stratum corneum which improves the transmission of the laser beams into the skin. Preferably, a translucent refractive index matching shaving cream is used as shown at 12 in FIG. ID to make shaving easier and also improve beam penetration.

Second Preferred Embodiment

[0012] A second preferred embodiment is shown in FIG. IE. This embodiment is very similar to the first embodiment except shaving blades 10 are replaced by skin abrading blades 14.

Third Preferred Embodiment

[0013] A known technique for subsurface collagen remodeling using a Perovskite 1341 nm laser involves a space partial thermolysis of papillary and reticular dermis to produce a high absorption of infrared light in upper layers of the skin. Its multi beam output at 1341 nm is combined with the output of a YAPerovskite:Nd, 1079 nm laser using multi- beams combining optical fibers connected to a hand piece.

[0014] The YAPerovskite:Nd laser at 1079 nm is used to improve selective thermolysis at 1341 nm by using non-selective thermolysis at 1079 nm. The 1079 nm laser light of YAP:Nd laser has no specific absorption in epidermis or dermis of the skin. The 1079 nm light is very highly scattered in skin and is fairly uniformly absorbed down to depths of a few millimeters. The 1079 nm light thus heats skin though all layers of skin creating a heated epidermis, dermis and subcutaneous fat. This enhanced heating when added to the heating produced in the upper dermis enhances a tissue transformation and modification effect produced by the 1341 nm beam alone. Therefore care must be taken to be certain that excessive transformation or destruction of the surrounding skin does not occur. To prevent an excessive damage and to control a tissue transformation process a ratio between fluences of 1079 and 1341 can be changed by allowing one or another light to transmit more or to dump more when passing through the optics. A ratio between irradiated and not irradiated skin patterns can be variable as well to allow a bigger portion of the non-treated skin to provide cooling and then healing the effected by a light skin portions. Tissue destruction generally depends on temperature and time. Therefore care should be taken to apply the laser energy at rates will produce only minimal damage to tissue which is not targeted. A technique to keep the temperature of non-targeted tissue below the damage threshold is to cool it with sapphire cylindrical lenses that are cooling elements at the same time. Conductive cooling of the skin surface is desired before, during and after the laser treatment. A set of diode lasers is placed at the first row of the device. Diode lasers emit energy at 720 nm to be well absorbed by a topical gel containing a chromophore indocyanin green ICG ₅ glycolic acid and glycerin. A role of the topical gel with glycolic acid and chromophore ICG to partially destroy a stratum

corneum of the epidermis by interacting with a diode light (ICG). Glycerin role is to transmit more light through the stratum comeum by filling a space between dry layers of the upper skin. A handpiece contains two rows of stratum corneum removal blade located between cold cylindrical lenses. Stratum corneum is partially or totally removed by blades after the destruction by glycolic acid, ICG and diode light. Stratum corneum blade has a sharp cutting and scrabbing edge of 150 micron. A pressure applied to the blade will not reach blood vessels during stratum corneum removal not causing any bleeding. Removal of stratum corneum allows an improving significantly a transdermal delivery properties of the upper skin as well as optical properties. Stratum corneum shaving blade can be used before, after during or separately to deliver cosmoceuticals, medications, proteins and other substances into or through the skin. A preferred technique is to apply 8 beams in bursts of pulses with about 10 pulses in two seconds so that the total energy deposited in the skin is about 12 Joules/cm2 if surface cooling is not used. With surface cooling the energy deposited could be increased to about 40 Joules/cm2. Preferably, the ratio of the 1079 nm energy to the 1341 nm energy is about 2 to 1.

Components

[0015] Diode 720 nm laser is available from Asah Corporation with office in Copenhagen, Denmark. Optical fiber with multiple inputs and one output is available from Newport Corporation, Irvine, Calif. The YAP:Nd laser is available from Fotona d.d. with offices in Ljubljana, Slovenia.

Other Similar Embodiments

[0016] Nd: YAG laser in infrared range 1320 nm and diode laser at 1450 nm might be also improved by using YAP:Nd as a second preferred embodiment. Nd: YAG laser deck is available from Sciton with office in Palo Alto, Calif. Diode laser 1450 is available from Candela, Wayland, Mass.

Fourth Preferred Embodiment YAP Enhancer for 1.5 Micron Diode or Fiber Laser

[0017] A well known technique for wrinkle removal and treating pigmented lesions and acnes on the skin involves the use of lasers at 1.5 urn. This technique is based on the fact that 1.5 um laser light is absorbed by the upper layers of the skin that leads to coagulation of those tissues. However, light at this wavelength does not penetrate skin tissue very well and as a result it is difficult to target tissues deeper than 700-800 um without seriously damaging the non-targeted skin tissue. Also this type of laser is difficult to use on a darker type of skin because of higher risk to damage skin.

[0018] In an alternate embodiment InP diode 1.5 um laser beams are enhanced with the output of a YAP:Nd, 1079 nm laser. The YAP:Nd 1079 nm laser does not have specific high absorption in skin and the laser light penetrates much deeper in skin than the light of 1.5 um. With the help of 1079 nm light it is easy to provide sufficient energy deposition at deeper layers of skin where the target is located. This combination increases the effect of 1.5 um radiation to the deeper layers of the skin to extend from 700-800 um up to 2- 2.5 mm.

[0019] Fiber lasers are available from IPG Photonics, Oxford, Mass. InP diodes are available from Covega, Jessap, Md.

YAP Enhancer for Diode Laser

[0020] YAP lasers can be used to enhance performance of diode lasers using the same approach as described above. Medical laser diode laser might be available from Coherent, Santa Clara, Calif., model LightSheer, DioMed, Boston, Mass., Both lasers operate at 800-810 nm range and might be improved by both 1079 and 1341 nm YAP:Nd laser. The 1079 nm wavelength of YAP:Nd laser improves hair removal using diodes lasers, while 1340 nm line of YAP:Nd improves coagulation of small blood vessel by non-selective thermolysis.

[0021] All variety of laser diodes in wavelength range 650-1550 are available from SLI Corporation Binghamton, N.Y. YAP laser might be located at the same platform as the diode laser. Optical fiber with two inputs and one output is available from Newport Cortoration, Irvine, Calif.

Fifth Preferred Embodiment

[0022] YAG:Er at 2936 nm performs surface wrinkle (superficial) ablation. The effect is based on the very high absorption of YAG:Er laser light in water. This laser works pretty well on small surface wrinkle but does not remove large deep wrinkles because the 2936 nm beam is extremely well absorbed in skin tissue so the penetration is only a few microns. The YAP:Nd laser at 1341 nm will penetrate a few milimeters and provides subsurface wrinkle treatment. Thus, YAP:Nd laser may preferably be used to enhance YAG:Er laser to perform both surface and deep wrinkles treatment. The approach is similar to those discussed above except in this case the beams are combined in an articulated arm 20 instead of the fiber optic. YAG:Er crystal might be obtained from - Litton Airtron with office in Charlotte, N. C. YAG :Er lasers deck is available from Continuum with office in Santa Clara, Calif., Focus Medical, Bethel, Conn., Fotona, Ljubljana, Slovenia. Articulated arm is available from MedArt Technology, San Diego, Calif.

Simultaneous Application

[0023] Both beams should preferably be applied during the same time interval. The beams may be but do not have to be synchronized. There should not be an significant delay in applying YAG:Er and YAP:Nd laser pulses, since the treated tissue may start to swell very soon after treatment which results in dramatic change in its optical and physiological properties.

Sixth Preferred Embodiment

[0024] A known technique for subsurface collagen remodeling using a InP 1300 nm laser involves a space partial thermolysis of papillary and reticular dermis to produce a

high absorption of IR light in upper layers of the skin. Its multi beam output at 1300 nm is combined with the output of a 980 nm diode laser using multi-beams combining optical fibers connected to a hand piece.

[0025] The InP diode laser at 980 nm is used to improve selective thermolysis at 1300 nm by using non-selective thermolysis at 980 nm. The 980 nm laser light of diode laser has no specific absorption in epidermis or dermis of the skin. The 980 nm light is very highly scattered in skin and is fairly uniformly absorbed down to depths of a few millimeters. The 980 nm light thus heats skin though all layers of skin creating a heated epidermis, dermis and subcutaneous fat. This enhanced heating when added to the heating produced in the upper dermis enhances a tissue transformation and modification effect produced by the 1300 nm beam alone. Therefore care must be taken to be certain that excessive transformation or destruction of the surrounding skin does not occur. To prevent an excessive damage and to control a tissue transformation process a ratio between fluences of 980 and 1300 can be changed by allowing one or another light to transmit more or to dump more when passing through the optics. A ratio between irradiated and not irradiated skin patterns can be variable as well to allow a bigger portion of the non-treated skin to provide cooling and then healing the effected by a light skin portions. Tissue modification generally depends on temperature and time. Therefore care should be taken to apply the laser energy at rates will produce only minimal damage to tissue which is not targeted. A technique to keep the temperature of non-targeted tissue below the damage threshold is to cool it with sapphire cylindrical lenses that are cooling elements at the same time. Conductive cooling of the skin surface is desired before, during and after the laser treatment. A set of diode lasers are placed at the first row of the device. Diode lasers emit energy at 720 nm to be well absorbed by a topical gel containing a chromophore Indocyanin Green ICG, glycolic acid and Glycerin. A role of the topical gel with glycolic acid and chromophore ICG to partially destroy a stratum corneum of the epidermis by interacting with a diode light (ICG). Glycerin role is to transmit more light through the stratum corneum by filling a space between dry layers of the upper skin. A handpiece contains two rows of stratum corneum removal blade located between cold cylindrical lenses. Stratum corneum is partially or totally removed by blades after the destruction by

glycoϊic acid, ICG and diode light. Stratum corneum blade has a sharp cutting and scrabbing edge of 150 micron. A pressure applied to the blade will not reach blood vessels during stratum corneum removal not causing any bleeding. Removal of stratum corneum allows an improving significantly a transdermal delivery properties of the upper skin as well as optical properties. Stratum corneum shaving blade can be used before, after during or separately to deliver cosmoceuticals, medications, proteins and other substances into or through the skin. A preferred technique is to apply 8 beams in bursts of pulses with about 10 pulses in two seconds so that the total energy deposited in the skin is about 12 Joules/cm ² if surface cooling is not used. With surface cooling the energy deposited could be increased to about 40 Joules/cm2. Preferably, the ratio of the 980 nm energy to the 1300 nm energy is about 2 to 1.

Components

[0026] Diode lasers are available from Asab Corporation with office in Copenhagen, Denmark. Optical fiber with multiple inputs and one output is available from Newport Corporation, Irvine, Calif. Diode lasers are also available from Covega with offices in Jessap, Maryland.

Other Similar Embodiments

[0027] ErGlass lasers in infrared range 1550 nm and diode laser at 1450 nm and 1300 might be also improved by using 980 nm diode laser as a second preferred embodiment. Er: Glass laser deck is available from Quantel with offices in Les Ulis, France. Diode laser 1450 is available from Candela, Wayland, Mass.

Seventh Preferred Embodiment Diode Enhancer for 1.5 Micron Diode or Fiber Laser

[0028] A well known technique for wrinkle removal and treating pigmented lesions and acnes on the skin involves the use of lasers at 1.5 urn. This technique is based on the fact that 1.5 um laser light is absorbed by the upper layers of the skin that leads to coagulation of those tissues. However, light at this wavelength does not penetrate skin tissue very well and as a result it is difficult to target tissues deeper than 700-800 um without

seriously damaging the non-targeted skin tissue. Also this type of laser is difficult to use on a darker type of skin because of higher risk to damage skin.

[0029] In an alternate embodiment InP diode 1.5 um laser beams are enhanced with the output of a 980 nm diode laser. The 980 nm diode laser does not have specific high absorption in skin and the laser light penetrates much deeper in skin than the light of 1.5 um. With the help of 980 nm light it is easy to provide sufficient energy deposition at deeper layers of skin where the target is located. This combination increases the effect of 1.5 um radiation to the deeper layers of the skin to extend from 700-800 um up to 2-2.5 mm.

[0030] Fiber lasers are available from IPG Photonics, Oxford, Mass. InP diodes are available from Covega, Jessap, Md.

Eight Preferred Embodiment

[0031] YAG:Er at 2936 nm performs surface wrinkle (superficial) ablation. The effect is based on the very high absorption of YAG:Er laser light in water. This laser works pretty well on small surface wrinkle but does not remove large deep wrinkles because the 2936 nm beam is extremely well absorbed in skin tissue so the penetration is only a few microns. A980 nm diode laser at 980 nm will penetrate a few milimeters and provides subsurface wrinkle treatment. Thus, YAP:Nd laser may preferably be used to enhance YAG:Er laser to perform both surface and deep wrinkles treatment together with a diode laser at 1300 nm. The approach is similar to those discussed above except in this case the beams are combined in an articulated arm 20 instead of the fiber optic. YAG:Er crystal might be obtained from -Litton Airtron with office in Charlotte, N.C. YAG:Er lasers deck is available from Continuum with office in Santa Clara, Calif., Focus Medical, Bethel, Conn., Fotona, Ljubljana, Slovenia. Articulated arm is available from MedArt Technology, San Diego, Calif.

Simultaneous Application

[0032] Two or more beams should preferably be applied during the same time interval. The beams may be but do not have to be synchronized. There should not be an significant delay in applying the various laser pulses, since the treated tissue may start to swell very soon after treatment which results in dramatic change in its optical and physiological properties.

Ninth Preferred Embodiment for Hair Removal

[0024] A known technique for subsurface collagen remodeling using a Ga Ar 810 nm laser involves a selective thermolysis of hair melanin to produce a high absorption of infrared light in hair shafts and matrix. Its multi-beam output at 810 nm is combined with the output of a 980 nm diode laser using multi-beams combining optical fibers connected to a hand piece.

[0025] hi this ninth preferred embodiment, a InP diode laser at 980 nm is used to improve selective thermolysis at 810 nm by using non-selective thermolysis at 980 nm. The 980 nm laser light of diode laser has no specific absorption in epidermis or dermis of the skin. The 980 nm light is very highly scattered in skin and is fairly uniformly absorbed down to depths of a few millimeters. The 980 nm light thus heats skin though all layers of skin creating a heated epidermis, dermis and subcutaneous fat. This enhanced heating when added to the heating produced in the upper dermis enhances a tissue transformation and modification effect produced by the 810 nm beam. In the two or more wavelength system, the first wavelength provides deep heating without much absorption in the skin water and pigments. This first wavelength is in the range from 900 nm to 12 nm and can be provided by Indium Phosphate diode lasers and/or super luminescent LED's. The second wavelength which is a melanin absorptive wavelength is in the range from 590 nm to 899 nm and can be provided with solid state diode pummp double frequency lasers and/or gallium arsenade diodes or suuper luminescent LED's. Intense pulse light from filtered flash lamps, filtered to provide light in the above ranges can also be used. One wavelength is to provide removal of non-pigmented hairs by using deep heating of

dermal papilla and bulge areas with stem cells. Another wavelength destroys melanin containing and producing tissue. A third wavelength can destroy supplying blood vessels. Power for both wavelengths should be in the range from 50 mW to 20 W. Exposure time for one spot is from 10 microseconds to 5 seconds. A one wavelength system can be used in the range from 800 nm to 1200 nm. The rest of the parameters are the same. In preferred embodiments blades and creams are used as described elsewhere.

Care should be taken to apply the laser energy at rates will produce only minimal damage to tissue which is not targeted. A technique to keep the temperature of non-targeted tissue below the damage threshold is to cool it with sapphire cylindrical lenses that are cooling elements at the same time. Conductive cooling of the skin surface is desired before, during and after the laser treatment. A set of diode lasers are placed at the first row of the device. Diode lasers emit energy at 720 nm to be well absorbed by a topical gel containing a chromophore Indocyanin Green ICG, glycolic acid and Glycerin. A role of the topical gel with glycolic acid and chromophore ICG to partially destroy a stratum corneum of the epidermis by interacting with a diode light (ICG). Glycerin role is to transmit more light through the stratum corneum by filling a space between dry layers of the upper skin. A handpiece contains two rows of stratum corneum removal blade located between cold cylindrical lenses. Stratum corneum is partially or totally removed by blades after the destruction by glycolic acid, ICG and diode light. Stratum corneum blade has a sharp cutting and scrabbing edge of 150 micron. A pressure applied to the blade will not reach blood vessels during stratum corneum removal not causing any bleeding. Removal of stratum corneum allows an improving significantly a transdermal delivery properties of the upper skin as well as optical properties. Stratum corneum shaving blade can be used before, after during or separately to deliver cosmoceuticals, medications, proteins and other substances into or through the skin. A preferred technique is to apply 8 beams in bursts of pulses with about 10 pulses in two seconds so that the total energy deposited in the skin is about 12 Joules/cm2 if surface cooling is not used. With surface cooling the energy deposited could be increased to about 40 Joules/cm2. Preferably, the ratio of the 980 nm energy to the 1300 nm energy is about 2 to 1.

Components

[0026] Diode lasers are available from Asah Corporation with office in Copenhagen, Denmark. Optical fiber with multiple inputs and one output is available from Newport Corporation, Irvine, Calif. Diode lasers are also available from Covega with offices in Jessap, Maryland.

Other Embodiments

[0033] Other preferred embodiments include other Nd contained laser crystals such as GGG, GSGG, YAG at around 1320 nm or another Er contained crystal YSGG at 2791 nm, SLED's, other diode lasers, IPL's, and flash lamps.

Optical Components

[0034] The various optical components needed to fabricate the laser system described above are available from normal optics suppliers and techniques for arranging the components are well known to persons skilled in the laser-optics art. For example the YAP:Nd rods for production of the 1079 nm and 1341 nm beams are available from Crytur, Ltd. with offices in Palackehol75, 51101 Tumov, Czeck Republec and Scientific Material Corp. with offices in Bozeman, Mont. Optics for arranging the resonator cavities are available from CVI Corp. with offices in Albuquerque, N. Mex. Flash lamp pumps for these crystal rods are available from Perkin Elmer with offices in Sunnyvale, Calif. Mirrors 12, 20, 22, and 24 and the optics shown to combine both laser lights are available from CVI Corp.

Preferred Specifications

[0035] The power supplies, pump sources and crystal rods should be sized to pulse energies appropriate for the particular treatments planned. In general pulse energies corresponding to about 0.5 watt per exposure for the selective beam and about 20 J per pulse for the transmissive beam is recommended. The beam diameters prior to coupling into the optical fiber optic is about 0.05 mm or more. The beams are normally focused onto the skin surface to produce faiences in the range of about 10 to 200 J per square

centimeters during the treatment period. As explained above^ damage to the skin can be avoided or minimized with prior, simultaneous or immediately subsequent cooling.

[0036] Although the present invention has been described in terms of preferred embodiments the reader should understand many changes and additions could be made without changing the nature of the invention. Therefore, the scope of the invention is to be determined by the appended claims and their legal equivalents.