The invention relates generally to the treatment of skin using laser light, and more particularly to a non-invasive device and method for performing said treatment.
Various forms of electromagnetic radiation, particularly laser light beams, have been used on the skin for many years for a variety of treatments, such as hair removal, skin rejuvenation to reduce wrinkles and reduction of pigmentation spots, and the treatment of conditions like acne, actinic keratosis, blemishes, scar tissue, discoloration, vascular lesions, acne treatment, cellulite and tattoo removal. Most of these treatments rely on photothermolysis, where a treatment location is targeted by the treatment radiation. Preferably, the treatment radiation is configured to be mainly absorbed at the treatment location, such that the temperature at the treatment location is raised sufficiently to achieve the desired thermal damage, for example tissue necrosis, denaturation or coagulation.
In skin rejuvenation treatments, the treatment laser beam passes through the outer layers of the skin to the dermis layer. The dermis is damaged by heating to induce a wound response, without damage to the epidermis. In other words, a target area within the skin is damaged in a controlled way, and the skin is allowed to replace the damaged tissue by new collagen growth—the damage promotes healing and a rejuvenation effect occurs. The renewed tissue improves the skin's radiance, tone, and can even provide a reduction in pore size, wrinkles and fine lines.
Selective non-ablative photothermolysis based on water absorption is used to heat the tissue to between 60 and 100 degrees Celsius to induce damage in the selected areas, without ablation or vaporization of the skin. Ablative photothermolysis occurs when the water temperature exceeds 100 degrees Celsius.
Focused laser light may even be used to create laser induced optical breakdown (LIOB) inside the dermis layer, as known from the published international patent application WO 2008/001284 A2.
Since many skin treatments require a treatment location in an inner skin layer, such as the dermis, damage to an adjacent outer layer, such as the epidermis, is a major problem. Subjecting the epidermis to high intensities may cause undesirable heating, which may result in additional discomfort to the subject being treated, adverse skin reactions and unwanted changes in skin pigment. This is particularly undesirable when treating facial disorders such as rhytides and wrinkles.
Techniques to reduce heating of the epidermis are known, for example, from the article “Spatially confined photothermolysis of dermal targets using an IR-fiber laser in combination with focusing and contact cooling,” Lasers Surg Med., 14 (Suppl):28 (2002) by Manstein D, Poureshagh M, Yaroslaysky I, Altshuler G B, and Anderson R R. Here, active surface cooling was applied in parallel to avoid epidermal injury when treating the skin by intradermal focusing of infrared fiber (λ=1.06 and 1.2 μm) laser pulses. However, active surface cooling makes the treatment device more complicated and expensive. This is particularly disadvantageous for home-use applications.
A different approach was attempted in PCT application WO 2005/122694 by spreading out the radiation by means of a beam conversion system between the radiation source and the skin surface. The beam conversion system deflects the incident radiation beam off-axis, and then redirects back at an angle to cross the symmetry axis at the target point under the skin. Two main embodiments are described one in which a single beam is rotated around the target axis at a fixed angle, and the other where the radiation beam is split into a plurality of angled beams. The beam conversions system makes this system very complex and difficult to adjust.
A further known technique is to separate the laser pulses by a pulse delay of sufficient length to provide normal thermal relaxations for the epidermis. This is described in the article “Intense Pulsed Light as a Nonablative Approach to Photoaging”, Dermatol Surg 2005; 31:1179-1187, by Goldman, Weiss R, and Weiss M. In particular, on pages 1180-1181, a pulse delay of at least 10 milliseconds is recommended in general, and for some subjects 20 to 30 milliseconds is recommended.
As the treatment efficacy depends on both the temperature at the target location and the duration of the treatment, the use of excessively long pulse delays may increase the overall duration of the treatment.
It is therefore desirable to improve the efficacy of such treatments, while keeping the treatment device as simple as possible.
An object of the invention is to provide a non-invasive skin treatment device and method for treatment of an inner skin layer using laser light.
The object is achieved according to the invention by a device comprising:
wherein an extent of the third beam region is predetermined and/or controlled to provide a corresponding third skin region in the outer skin layer, arranged between the first and the second skin region,
wherein the lower light intensity of the third beam region is predetermined and/or controlled to provide a maximum temperature during a pulse of the laser treatment beam within the third skin region which is lower than maximum temperatures during said pulse of the laser treatment beam within the first and the second skin region;
and wherein the light source is configured and arranged to provide, in use, a pulse duration of the pulse of the laser treatment beam which is longer than a thermal relaxation time of the first and the second skin region.
The object is also achieved by a non-invasive method of treating an inner skin layer using a device for generating laser light, the device comprising a light source and an associated optical system for generating pulses of a laser treatment beam along a treatment optical axis of the device,
the method comprising:
The invention is based on the insight that providing at least one central beam region of significantly lower laser intensity, within the transverse cross-section of the laser treatment beam, provides a corresponding central skin region in an outer skin layer. The lower laser intensity in this central skin region may be configured and arranged to provide a lower degree of heating than in the surrounding skin regions. In other words, a heat-sink region is provided for the surrounding skin regions. This is advantageous because the heating of the outer layer of skin may be more uniformly distributed than when use is made of a beam with a conventional Gaussian or top-hat intensity profile, thus avoiding hot spots which can result in undesired thermal damage in the outer skin layer. Controlling and/or predetermining the extent of this heat-sink region are convenient ways of preventing excessive temperatures in the outer skin layer.
The light source is configured and arranged to provide, in use, a pulse duration of the pulse of the laser treatment beam which is longer than the thermal relaxation time of the first and the second skin region. The invention thus makes it possible to treat an inner skin layer using longer duration pulses, without using further measures such as external cooling. The inner heat-sink region in the outer skin layer provides a skin region within which excess heat from the surrounding skin regions may dissipate.
It may be also advantageous for the light source or optical system to further comprise at least one optical element configured and arranged to provide the first, the second and the third beam region. This optical element (or optical elements) may be disposed within the light source, for example in the laser cavity or in the optical system. Any suitable optical element known in the art may be used, for example, a central mask, a ring aperture, a Spatial Light Modulator (SLM), a Diffractive-Optical element (DOE), a phase mask, a spiral wave plate, a vortex wave plate, a Pitch-Fork Hologram, a Q-Plate, or a Cylindrical Mode Converter. It may be advantageous to combine more than one of these optical elements to provide the beam regions. It may also be advantageous to provide at least one optical element inside the light source, in combination with at least one optical element in the optical system.
Although the invention may provide many configurations of the beam regions, it may be particularly advantageous to provide a first and a second beam region that are non-contiguous, and to configure the third beam region so as to separate the first and the second beam region throughout the length of their borders within the transverse cross-section of the laser treatment beam.
In a further advantageous configuration, the first and the second beam region are contiguous and form part of an annular region of non-zero light intensity, the third beam region being configured to form a central region of lower light intensity, and wherein the central region of lower light intensity is enclosed by the annular region of non-zero light intensity. Such a ring-shaped or doughnut-shaped pattern may be provided using an appropriately placed central aperture, or many other techniques known to the skilled person.
It may be advantageous to configure and arrange the light source to provide, in use, a pulse duration of the pulse of the laser treatment beam which is longer than a thermal relaxation time of the outer skin layer and shorter than a thermal relaxation time of the inner skin layer. For example, if the outer skin layer is the epidermis, the pulse duration should be longer than or equal to 10 to 30 ms. These values are typical values of the thermal relaxation time of the epidermis. If the inner skin layer is the dermis, the pulse duration should be shorter than or equal to 100 ms to 300 ms. These values are typical values of the thermal relaxation time of the dermis. Such pulse durations are expected to effectively heat the dermis in focused positions, while sparing the epidermis from unnecessary thermal damage. In particular, the pulse duration may be predetermined and/or controlled to be longer than the thermal relaxation time of the skin tissue present in the first and the second skin region and shorter than the thermal relaxation time of the skin tissue or chromophore present at the focal spot of the laser treatment beam.
It should be noted that items which have the same reference numbers in different Figures, have the same structural features and the same functions, or are the same items. Where the function and/or structure of such an item have been explained, there is no necessity for repeated explanation thereof in the detailed description.
Focusing the beam increases the laser intensity in the focal spot 25, which increases the efficacy of the treatment because the focal spot 25 will reach higher temperatures than the outer skin layer 16. This provides a relatively simple focusing system, allowing a dynamic control of the focusing depth. This is different to known devices, such as those described in WO 2005/122694 which use very complicated beam conversion systems to split the incident beam into multiple beams, to deflect them aways from the axis, and to redirect them to intersect below the surface of the skin.
The focal spot 25 is selected to correspond to the treatment location in most applications, the focal spot 25 will be disposed at the treatment location.
In some applications, it may also be advantageous to dispose the focal spot 25 proximate to the treatment location, whereby the heat from the focal spot 25 diffuses towards the treatment location. The focal spot is then selected to coincide with a suitable chromophore in the inner skin layer 17.
The light source 20 and optical system 12 may also be configured to provide a more diffuse treatment beam 22 by not focusing the treatment beam 22. In that case, the treatment location in the inner skin layer 17 will be determined by suitably located chromophores which are irradiated by the treatment beam 22. The optical system 12 is suitably configured to guide the first 22a and the second 22b beam region through an outer skin layer 16 to the treatment location, whereby the first 22a and the second 22b beam region pass through, respectively, a first 23a and a second 23b skin region in the outer skin layer 16.
The skin 15 comprises multiple layers with different optical properties. The epidermis 16 is composed of the outermost skin layers and forms a waterproof protective barrier. The outermost layer of the epidermis 16 is the stratum corneum. The dermis 17 is situated underneath the epidermis 16.
According to the preferred use of the invention, the focal spot 25 is disposed in the dermis 17, and the first 23a and the second 23b skin region are present in the stratum corneum, epidermis 16, or skin surface layer. The extent of the third beam region 23c is predetermined and/or controlled to provide the required extent of the corresponding third skin region. The extent of the third skin region 23c is selected to provide a heat sink of suitable dimensions to ensure that the maximum temperature during the treatment within the third skin region 23c in the outer skin layer 16 is lower than the maximum temperatures in the surrounding regions in the first 23a and the second 23b skin region.
The temperature within the skin regions may be monitored during use, using any convenient apparatus known in the art, such as an infrared camera or a microphone. Alternatively or additionally, skin simulation may be used to configure and arrange the device of the invention such that the maximum temperatures are not exceeded.
If the device 10 is used to reduce wrinkles in the skin 15, the focal spot 25 is disposed in the collagen of the dermis 17 in order to create microscopic lesions at the position of the focal spot 25, which results in new collagen formation. The focal spot 25 may then be disposed between 0.2 and 2 mm below the outer surface of the skin 15, in particular between 0.5 and 1.5 mm below the outer surface of the skin 15. Typically, the lesions formed will be larger than the volume of the focal spot 25.
The optical system 12 is configured and arranged to guide, in use, the laser treatment beam 22 to exit the device 10 along the treatment optical axis 13 which then impinges on an outer surface of the skin 15 to be treated, and to guide, in use, the treatment laser beam 22 to the focal spot 25 in an inner skin layer 17 along the treatment optical axis 13. The word “guide” includes configurations where the direction of the light beams is changed substantially, and configurations where the treatment beam 22 is allowed to propagate along the light beam direction without substantial change, and any intermediate degree of directional change. In all cases, the treatment beam 22 will exit the device 10 along the treatment optical axis 13.
The laser treatment beam 22 that impinges on an outer surface of the skin 15 will be approximately the same diameter as the beam that was produced by the light source 20. This is different to known devices, such as those described in WO 2005/122694 which use a beam conversion system to create a spot on the surface of the skin which has a total area larger than the cross-section area of the input light beam.
Consequently, the treatment light beam 22 will pass through an outer skin layer on its way to the focal spot 25. The device 10 according to the invention is configured and arranged to prevent or mitigate thermal damage in this outer skin layer during treatment at a treatment location corresponding to the focal spot 25. In other words, the invention protects the outer skin layer 16 from hot spots.
The phrase “outer skin layer” should be interpreted to include more than just the epidermis 16—the invention may also be used to protect the surface of the skin 15, or even the upper layer of the dermis 17. The phrase “inner skin layer” should be interpreted to include more than just the dermis 17—the focal spot 25 may be disposed in an upper layer of the dermis 17, or even in the epidermis 16. The only restriction is that the outer skin layer is located between the focal spot 23, disposed in the inner skin layer, and the device 10.
This “doughnut” cross-section may be provided by the light source 20 or optical system 12 comprising at least one optical element which reduces, or even blocks, the light intensity at the inner beam region 22c of the treatment beam 22. Any suitable optical elements known in the art may be used, for example, a central mask, a ring aperture, a Spatial Light Modulator (SLM) as known from U.S. Pat. No. 7,961,371, a Diffractive-Optical element (DOE), a phase mask as known from U.S. Pat. No. 7,982,938, a spiral waveplate, a vortex waveplate, a Pitch-Fork Hologram, a Q-Plate, or a cylindrical Mode Converter. A plurality and/or a combination of such elements may also be used.
In longitudinal cross-section, the laser treatment beam comprises a first 22a and a second 22b beam region of non-zero light intensity disposed at the periphery of the transverse cross-section, and a third beam region 22c, extending between the first 22a and the second 22b beam region, and being of substantially lower light intensity than the non-zero light intensity. When viewed in transverse cross-section, the first 22a and the second 22b beam region are portions of the ring-like outer beam region depicted in
As the laser treatment beam 22 passes through the outer skin layer 16, it creates a first 23a and a second skin region 23b of non-zero light intensity in the outer skin layer 16, corresponding to the first 22a and the second 22b beam region of non-zero intensity in the treatment beam 22. The relationship between the dimensions and intensities of the beam regions in the treatment beam 22 and the skin regions 23a, 23b in the outer skin layer 16 depends on the scattering and absorption properties of the outer skin layer 16, and on the tissues located between the first 23a and second 23b skin region and the outer surface of the skin 15. The dimensions and intensities in the skin regions 23a, 23b of the outer skin layer 16 determine the temperature rise in those skin regions 23a, 23b.
The first 22a and the second 22b non-zero intensity beam region are separated by a third beam region 22c having a lower light intensity than the non-zero light intensity. This lower light intensity is substantially lower than the non-zero intensity. This creates a third skin region 23c in the outer skin layer having a substantially lower intensity than the first 23a and the second 23b skin region. Again, the relationship between the dimensions and intensities of the central beam region 22c and the central skin region 23c depends on the scattering and absorption properties of the outer skin layer, and on the tissues located between the central skin region 23c and the outer surface of the skin 15. Although this central skin region 23c may have its temperature raised by the intensity of the laser light in this skin region 23c, the extent of the third beam region 22c is predetermined and/or controlled to provide a suitably-dimensioned heat sink between the first 23a and the second 23b skin region.
The intensity profile of the laser treatment beam 22 at the treatment location may also comprise non-zero intensity and lower-intensity regions. But the dimensions and intensities of such regions at the treatment location depend on the degree of focusing used, and the scattering and absorption properties of the treatment location, and on the tissues located between the treatment location and the outer surface of the skin 15.
If the treatment beam 22 is focused to a focal spot 25 in the dermis 17, the regions of significantly different intensity will no longer be preserved due to thermal diffusion. The focusing helps localize the region being heated. It also helps prevent damage to the epidermis 16 because the power density may be much lower in the epidermis 16 than in the dermis 17.
For the invention it is not necessary that a further heat sink skin region is created at the treatment location.
During treatment at the treatment location, the temperature will rise in the first 23a and the second 23b skin region of the outer skin layer 16. By providing a heat sink between these skin regions, a higher degree of thermal diffusion and thermal redistribution means that the risk of thermal damage within the first 23a and the second 23b skin region is reduced. By appropriate configuration of the device 10, the heat-sink dimensions may be determined such that, during the treatment, the maximum temperature within the third central skin region 23c is lower than the maximum temperatures in the first 23a and the second 23b skin region.
The principle of operation may also be understood from the graphs provided as
When the laser beam profiles are used to treat skin 15, the epidermal 16 temperature profiles depicted in
Conventionally, this “hot spot” is avoided by using the flat-top intensity profile 40. However, the associated temperature profile is not a flat-top.
The conventional solution to the hotspot problem is to reduce the maximum intensity 50 in the treatment beam profile until the epidermal hotspot no longer occurs. However, this also reduces the power of the laser treatment beam 22, resulting in a lower efficacy and/or extended treatment times.
When either of the laser beam profiles of
The invention therefore enables hot spots in the outer skin location to be avoided without significantly reducing the power of the laser treatment beam 22 by providing a central heat sink 23c. As a result, also the power reaching the treatment location is not significantly reduced. The dimensions of the heat sink are predetermined and/or controlled to limit the maximum temperature in the outer skin location 23a, 23b, 23c during treatment. If the dimensions of the heat sink are only predetermined, a simulation of skin may be used to determine appropriate settings, depending on the desired treatment. If the dimensions of the heat sink are only controlled, some form of feedback is desired, such as the temperature sensors depicted in U.S. Pat. No. 6,015,404 by Altshuler and Erofeev. Preferably, both predetermination aspects and control aspects are used to provide the most accurate temperature control in the outer skin location 23a, 23b, 23c.
The dimensions of the central heat sink required to prevent thermal damage depend on at least one parameter, including:
The parameters of the device 10 which may be used to predetermine and/or control the dimensions of the central heat sink include:
The skilled person will be able to determine the parameters of the device 10 by appropriate simulation and/or measurements.
Some examples of approximate settings are:
Many measurements have been made relating to the thermal relaxation time of skin—for example, the article “Analysis of Thermal Relaxation During Laser Irradiation of Tissue”, Lasers in Surgery and Medicine 29:351-359 (2001), by Choi and Welch. In this article, thermal relaxation times were investigated using both conventional Gaussian and conventional flat-top laser beam profiles. In particular, this article analyses thermal relaxation when the skin is treated with a plurality of pulses.
It may be advantageous if the central skin heat-sink region is dimensioned such that a cross-sectional extent of the central heat sink is equal to or greater than the thermal penetration depth of the outer skin layer 16. The cross-sectional extent may be determined by measuring the distance through a plane approximately parallel to the surface of the skin 15, between opposing edges of the first 23a and the second 23b skin region. The edge of each skin region 23a, 23b may be considered to be a contour joining points whose intensity is equal to half the maximum intensity within the skin region. The thermal penetration depth, measured in microns, is typically 50-200 microns.
According to the invention, the pulses of the laser treatment beam have a pulse duration which is longer than the thermal relaxation time of the outer skin region. Such relatively long pulses are conventionally avoided because pulses longer than the thermal relaxation time may result in a steady increase in temperature during treatment, which can cause the temperature of the skin to exceed the threshold for thermal damage. The thermal relaxation time for the epidermis depends on the individual, the place on the body and the parameters of the laser treatment, but is typically from 10 to 30 ms. See the “Intense Pulsed Light as a Nonablative Approach to Photoaging” article on pages 1180 to 1181 under “Pulse Durations”.
So, using the relationship 70 depicted in
It may also be advantageous to use the invention together with other measures known in the art, such as epidermal cooling.
Beam regions of non-zero and lower intensity within the transverse beam cross-section may be provided by configuring and arranging the laser light source 20 to operate in a higher order mode with a central region having a substantially lower intensity than at the periphery, i.e. not in the fundamental mode and not in a mixed multi-mode where the output is a combination of a plurality of higher-order modes. The higher order mode should be pure enough to create the required regions of non-zero and substantially lower intensity. Any methods known in the art may be used to achieve this, such as appropriate configuration of the laser cavity or resonator. For example, the article “Generation of pure TEMp0 modes using a friendly intra-cavity laser beam shaping technique” by Cagniot, Fromager et al; Laser Beam Shaping XII; SPIE Vol. 8130, 813006 (2011) discloses a model for generating higher modes with phase and amplitude DOEs in a laser cavity (resonator). For example, a pi-phase plate is inserted into a plano-concave cavity.
The intensity regions of the invention may also be provided by configuring and arranging the laser light source 20 to operate in the LG-01* mode, where p=0 and l=1. The “*” indicates that this is the so-called “doughnut” or annular mode depicted in
LG modes such as LG-11, LG-21, LG-22 and LG-34 may also be used to provide a plurality of suitable regions of low intensity 22c.
More details on intensity distributions in higher-order laser modes can be found in Chapter 11: Laser Beam Diagnostics in a Spatial Domain by Tae Moon Jeong and Jongmin Lee, in the book Laser Pulse Phenomena and Applications, edited by F. J. Duarte, ISBN 978-953-1007-405-4.
It will be clear to the skilled person that suitable intensity profiles may also be created by a combination of modifications and/or optical elements within the laser cavity, and optical elements disposed along the optical path outside the laser cavity.
The device and method according to the invention may be used for any suitable treatment of the skin, in particular non-invasive wrinkle reduction in the skin, actinic keratosis, scar tissue or acne and reduction of pigmentation spots. The device and method may be used for selective photothermolysis, in particular for ablative and non-ablative techniques.
The laser light source 20 may be disposed outside of the device 10, and connected using an optical fiber. This provides a small and lightweight applicator unit, with the bulkier and heavier laser source etc., in a separate and stationary unit.
It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design many alternative embodiments.
In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. Use of the verb “comprise” and its conjugations does not exclude the presence of elements or steps other than those stated in a claim. The article “a” or “an” preceding an element does not exclude the presence of a plurality of such elements. The invention may be implemented by means of hardware comprising several distinct elements, and by means of a suitably programmed computer. In the device claim enumerating several means, several of these means may be embodied by one and the same item of hardware. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.
Number | Date | Country | Kind |
---|---|---|---|
14151850.6 | Jan 2014 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2015/050018 | 1/4/2015 | WO | 00 |