新闻活动


    
首页新闻活动 新闻
返回

技术分享 | 1470nm半导体激光器在家用嫩肤中的应用

发布日期:2021-04-29

近年来,家用美容设备市场蓬勃发展,消费者对去皱、抗衰老产品的需求持续增长。作为一种将电能直接转换为光的半导体设备,半导体激光器与其他用于皮肤再生的激光源相比,具有许多优势,包括较高的转换效率、较小的尺寸和较低的成本。

本文介绍了1470nm半导体激光器在家用嫩肤中的应用,由炬光科技产品经理吴佩等撰写,原文发表于《Laser Focus World》2021年4月刊,全文如下:

1470 nm Diode Lasers Enable Home Skin Rejuvenation

Osier Wu, Kevin Yang

FOCUSLIGHT TECHNOLOGIES INC.

 

1.png

FIGURE 1. Lasers commonly used for fractional photothermolysis treatment have wavelengths highly absorbed by water and less absorbed by melanin and hemoglobin.

Laser-based technologies effectively treat cutaneous damage from the sun, as well as scars, wrinkles, and freckles. Since development of the first carbon dioxide (CO2) laser for skin resurfacing in the 1980s, lasers have been widely used for skin rejuvenation, as the technologies have evolved from ablative, to non-ablative, to the currently popular fractional method.

The ablative CO2 lasers first commercialized for skin rejuvenation applications provide the most significant treatment result by vaporizing water in skin tissue. However, exposing the entire treatment area to the ablative laser necessitates prolonged 7- to 10-day recovery times, and increases the risk of adverse effects such as infection, long-term erythema, and crusting. Consequently, pre- or post-operative procedures commonly include oral antibiotics, ice-cooling, and anti-inflammatories.

The non-ablative lasers introduced later overcame some of these issues, but produce results that are inconsistent and often unpredictable. Fractional photothermolysis (FP), introduced in 2004 by Manstein et al.,1 reduces treatment risk and side effects, and eliminates recovery downtime, driving their increased popularity today.

Fractional Photothermolysis

FP devices are classified into two categories: ablative and non-ablative. Because water is the main target chromophore for such treatment, the lasers commonly used have wavelengths highly absorbed by water and less absorbed by melanin and hemoglobin. Longer wavelengths in the range of 2.79 to 10.6 µm, typically CO2 (10.6 μm) and Er:YAG (2.94 μm), are ablative lasers that vaporize the tissue due to strong absorption of water (see Fig. 1) such that the optical penetration depth is minimal (see Fig. 2).

2.png

FIGURE 2. Lasers can penetrate deep into the dermis (1470 nm around 400 μm, and 1550 nm up to 1600 μm.(Image credit: Plastic Surgery Key)

During such treatment, the stratum corneum will be damaged and a small hole of a certain depth on skin will be produced. To increase the penetration depth into the dermis, higher energy density is required. When the energy density exceeds the vaporization threshold, the resulting depth will relate to the energy, independent of the applied wavelength.

Shorter wavelengths ranging from 1320 to 1927 nm usually do not remove skin, but coagulate the skin tissue as a result of thermal effects.

Er:glass (1540 nm), Nd:YAG (1320/1440 nm), and diode (1470/1550 nm) lasers are the most common non-ablative fractional laser sources. Water absorption at 1470 and 1550 nm is lower than Er:YAG or CO2 lasers, but is relatively higher than 810–1060 nm (see Fig. 1). Such lasers can penetrate deep into the dermis (1470 nm around 400 μm, and 1550 nm up to 1600 μm; see Fig. 2). During non-ablative treatment, the stratum corneum remains undamaged, so skin is intact and no superficial damage can be seen.

Light at 1060 nm or shorter wavelengths can penetrate deep into the subcutaneous fat layer or deep dermis, but is highly absorbed by melanin and hemoglobin. As a result, this is not a good choice for skin rejuvenation. Light at 755–1060 nm can be used for hair removal.

1470 nm Diode Lasers

As a monolithic semiconductor device that converts electrical energy directly into light, the diode laser, when compared with other laser sources for skin rejuvenation, has many advantages, including conversion efficiency, compact size, and cost. Thanks to these benefits, diode laser-based skin rejuvenation devices can be designed for at-home use. Here, we will discuss the basic principles of using a 1470 nm diode laser for home-use skin rejuvenation.

Laser skin rejuvenation is based on the theory of selective photothermolysis,2 which states that tissue chromophores will selectively absorb different wavelengths. Common chromophores in human tissues are water, hemoglobin, and melanin, among which the water is the primary chromophore (70% of the tissue) for the skin rejuvenation treatment.

Compared with other wavelengths, a 1470 nm laser provides a suitable absorption coefficient for water and can penetrate approximately 400 μm deep into the dermis. Lasers with wavelengths longer than 1400 nm can be strongly absorbed in the eye’s cornea and lens, which means the energy often doesn’t reach the retina. Under the maximum permissible exposure (MPE), the 1400 nm light source is considered safe. The MPE at 1470 nm is a million times below that of the 1400 nm wavelength (see Fig. 3).

3.png

FIGURE 3. MPE as energy density vs. wavelength for various exposure times.(Image credit: Wikipedia)

Treatment employing a fractional method produces small three-dimensional thermal injuries or columns, also known as microscopic treatment zones or microthermal zones (MTZs). The size of MTZs usually does not exceed 400 μm so that fibrosis or inflammation will not be induced. With larger MTZs, fibrosis is caused instead of wound healing. Both the size and penetration depth of MTZs depend on the laser wavelength and input energy. For the same laser, the higher the power introduced, the bigger the MTZs and the deeper they penetrate.

At-Home Treatment

During the FP treatment, the only thermal damage area is the MTZs; surrounding tissues remain intact, acting as a reservoir for cell regeneration. MTZ density should be well controlled, as a sufficient amount of undamaged tissue is required to ensure a quick repair process. However, the cumulative density should be enough to provide a satisfactory clinical result. Usually, MTZs should account for not greater than 40% of the treatment area so that the epidermis can be regenerated in 24–48 hours.

Within 24 hours after the treatment, necrotic cells in the epidermis are replaced by active cells surrounding MTZs. The degenerated necrotic cells are known as microscopic epidermal necrotic debris (MENDs, including necrotic epidermal tissue and dermal tissue, melanin, and elastin), which will migrate through the stratum corneum and be excreted through the epidermis. During the treatment, new collagen and elastin tissue will be also be stimulated.

Solid-state lasers like Er:glass and Nd:YAG are challenging to be installed in at-home devices due to their size, heat dissipation, and cost. It is the commercialization of diode lasers that makes home-use laser skin treatment possible. A 1470 nm fractional laser (a laser that delivers a beam with multiple MTZs into the skin) has been proven to be useful for both professional systems and home-use devices. Some commercialized at-home devices, including RéAura (Philips; Amsterdam, Netherlands) and the Tria Age Defying Laser (Tria Beauty; Dublin, CA), are FDA-approved.

Unlike professional systems, at-home devices have smaller treatment areas with fewer MTZs. Professional systems usually have higher MTZ density and shorter pulse width due to the high power (dozens of watts) of the laser source. The MTZ/cm2 can be 50, 100, 500, or even 1000 cm2. With professional treatments, a few sessions are enough to see the result. For an at-home device, MTZ/cm2 usually does not exceed 40 due to lower power (a few watts), so many more treatments are needed (3–4X per week and continue for a few weeks).

For at-home use devices, due to limited heat dissipation capacity and smaller dimensions, diode laser power is restricted to the range of 1 to 15 W, whether single emitter, multiple emitters, or bar. Specific optical designs can generate a single spot of 100 to 200 µm, a spot line, or a spots array. Spot energy is usually within 15 mJ/spot and pulse widths are 10 to 60 ms. Since at-home devices have to be air-cooled, heat dissipation has to be designed well.

4.png

FIGURE 4. A home-use, non-ablative 1470 nm fractional laser demo system (200g, 210 × 55 × 60 mm3) at Focuslight and the spots it generates.

Like professional devices, both stamping and rolling treatment modes can be adapted for the at-home version. In stamping mode, the MTZ pattern is preset by the device. During treatment, the device will stamp region by region until the entire treatment area is covered (no movements during light-emitting time/pulse width). Stamping mode can cover all areas with high precision, but results in a longer treatment time.

In rolling mode, the operator must move the device continuously to cover the treatment area. As the device is moving during the light-emitting time, the actual spot will be elongated compared to the designed spot size, depending on the movement speed and pulse width. Both methods are recommended based on the user’s preference and the parameters of the device.

5.png

FIGURE 5. Less erythema can be seen after the treatment by the Focuslight demo system under 10 ms, at 10 mJ/spot.

Home-Use Demo System Results

A home-use demo system was built in the Focuslight lab with a 1470 nm, 1.5 W diode laser (see Fig. 4). Spot size is 100 × 100 μm and energy is from 6 to 12 mJ/spot. The demo system is built with an adapter, but a commercial device usually has a battery.

6.png

FIGURE 6. Treatment of periorbital wrinkles by the Focuslight demo system at 10 ms, at 10 mJ/spot. Treatment is done 3X per week; after 5 weeks, reduction in wrinkles can be seen.

The results showed less erythema on the skin right after treatment (see Fig. 5). Unlike professional treatments, current at-home devices are only indicated by the FDA to treat periorbital wrinkles (see Fig. 6), but this device also was effective for fading acne marks on the face (see Fig. 7). To treat deeper wrinkles, scars, and even stretch marks, professional systems at clinics or hospitals can be deployed.

7.png

FIGURE 7. Treatment of an acne scar by the Focuslight demo system at 10 ms, at 10 mJ/spot. Treatment is done 3–4X times per week; after 5 weeks, the acne marks are reduced and skin texture is improved.

The home-use beauty device market has grown significantly during recent years and is driving increased use of 1470 nm lasers for skin rejuvenation. The home-use market will continue to boom, as consumer demand is high for easy to use, at-home devices. With the increasing size of the geriatric population, demand for anti-aging products such as wrinkle removal for skin laxity improvement applications will continue to grow, further fueling the market.

References

1. D. Manstein, G. S. Herron, R. K. Sink, H. Tanner, and R. R. Anderson, Lasers Surg. Med., 34, 5, 426–438 (2004).

2. R. R Anderson and J. A. Parrish, Science, 220, 4596, 524–527 (Apr. 29, 1983); doi:10.1126/science.6836297.

3. E. P. Tierney, D. J. Kouba, and C. W. Hanke, Dermatol. Surg., 35, 10, 1445–1461 (Oct. 2009); doi:10.1111/j.1524-4725.2009.01258.x.

4. X. Leihong and Z. Zhanchao, Laser Treatment Theory and Technology for Dermatology, People’s Medical Publishing House, 59–60 (2014).

5. C. Albert, “Fractional vs. non-fractional laser,” Congress handout, 6 (2017).

6. X. Wenlin, Chinese J. Aesthetic Med., 1535 (2009).

7. K. Nouri, Lasers in Dermatology and Medicine, Springer, 123–133 (2011).

8. S. B. Kaushik and A. F. Alexis, J. Clin. Aesthetic Dermatol., 52 (2017).

Meet the authors

Osier Wu has been senior sales manager for medical and aesthetic products at Focuslight Technologies Inc. for years. Currently she is the product manager for home use medical and aesthetic products focusing on the in-depth study of different home use medical and aesthetic products and applications. Email: wup@focuslight.com.

Kevin Yang is director of medical and aesthetic product line at Focuslight Technologies Inc. He focuses on the study of high-power diode lasers for medical and aesthetics applications. Kevin Yang has a master’s degree in engineering from Northwest University. Email: yangk@focuslight.com.

关于炬光科技:

西安炬光科技股份有限公司成立于2007年,是一家全球领先的专业从事高功率半导体激光器、激光微光学元器件、光子技术应用解决方案的研发、生产及销售的国家级高新技术企业。公司围绕光子技术及应用领域,致力于为全球客户提供高功率半导体激光器与激光微光学核心元器件及光子技术应用解决方案,形成了全面、完善的研发、生产及销售服务体系。

上一篇:新品上市 | 炬光科技发布FocusTest系列测试分析设备 下一篇: 新品发布 | 炬光科技推出905nm线光斑激光发射模组LE02
隐私偏好中心
为了使站点正常运行并为访问者提供无缝和定制化体验,Cookie 和其他类似技术(“Cookie”)非常重要。 Zoom 通过 Cookie 支持您使用我们的站点。 我们还通过 Cookie 允许您个性化定制您使用我们网站的方式,为您提供增强的功能,并不断提高我们网站的表现。 如果您已启用下面的定向 Cookie,我们可能会将根据您的账户类型或登录状态允许第三方广告商使用他们在我们的站点上所设置的 Cookie 在我们的网站或产品上向您显示与您相关的广告内容。
您可以接受或拒绝除“绝对必要 Cookie”之外的所有 Cookie,或者定制下面的 Cookie 设置。 您可以随时更改您的 Cookie 设置。 部分“绝对必要性 Cookie”可能会将个人数据传送到美国。 要了解有关 Zoom 如何处理个人数据的更多信息,请访问我们的隐私声明
将下面标有“定向”的按钮切换为关闭状态之后,加利福尼亚州的居民可以行使“选择拒绝出售个人信息”的权利。
接受Cookie
管理许可偏好
  • +目标定位
    我们的广告合作伙伴可以通过我们的站点设置这些 Cookie。 这些 Cookie 可供广告合作伙伴公司根据自有策略跟踪您使用我们网站的情况,并可将相应信息与其他信息相结合,然后在我们的站点和其他站点上向您显示相关广告。 如果您不允许使用这些 Cookie,您将不会在 Zoom 网站或产品上看到个性化广告。
  • +功能
    这些 Cookie 支持网站提供增强型功能和定制功能。 Cookie 可能由我们或由在我们的网页上添加服务的第三方供应商设置。 如果您不允许这些 Cookie,那么部分或所有的这些服务可能无法正常运行。
  • +性能
    这些 Cookie 使我们能够计算访问量和流量来源,以便我们评估和改进我们的网站性能。 这些 Cookie 可帮助我们了解哪些页面最受欢迎,哪些页面最不受欢迎,并了解访问者在网站上的浏览方式。 如果您不允许这些 Cookie,我们将不知道您何时访问过我们的网站,也无法监测网站性能。
  • +绝对必要

    始终处于活动状态

    这些 Cookie 对于网站的运行是绝对必要的,且无法在我们的系统中关闭。 通常,只有在您做出近乎服务请求的行为(例如,设置您的隐私偏好、登录或填写表单)时才会设置这些 Cookie。 您可以将浏览器设置为阻止或提醒您注意这些 Cookie,但网站的某些部分可能会无法运行。
确认我的选择