激光诱导光击穿对 1064nm 皮秒激光治疗期间皮肤类型的依赖性。

Dependence of laser-induced optical breakdown on skin type during 1064 nm picosecond laser treatment.

机构信息

Industry 4.0 Convergence Bionics Engineering, Pukyong National University, Busan, Republic of Korea.

Mymirae Research Institute for Dermatologic Science, Seoul, Republic of Korea.

出版信息

J Biophotonics. 2021 Sep;14(9):e202100129. doi: 10.1002/jbio.202100129. Epub 2021 Jun 18.

DOI:10.1002/jbio.202100129

PMID:34114344

Abstract

The current study aims to evaluate the dependence of laser-induced optical breakdown (LIOB) on skin types by using 1064 nm picosecond laser with micro-lens arrays (MLA) and diffractive optical elements (DOE). Both black and white skin tissues were examined to comparatively assess the LIOB effects in the skin in terms of laser-induced vacuolization. The black skin irradiated at 3.0 J/cm demonstrated that MLA yielded a deeper distribution (180-400 μm) of laser-induced vacuoles with a size of 67 μm, compared to DOE (180-280 μm; 40 μm in size). However, the white skin presented that MLA created larger vacuoles (134 μm in size) in a smaller number at deeper distributions (125-700 μm) than MLA with the black skin. DOE generated no laser-induced vacuolization in the white skin. The white skin tissue with inherent higher scattering could be responsible for deeper vacuolization after the picosecond laser treatment. Further investigations are expected to determine the optimal treatment conditions for various skin types.

摘要

本研究旨在通过使用微透镜阵列（MLA）和衍射光学元件（DOE）的 1064nm 皮秒激光，评估激光诱导击穿（LIOB）对皮肤类型的依赖性。分别检测黑色和白色皮肤组织，以比较评估激光诱导空化作用下皮肤中的 LIOB 效应。在 3.0J/cm 的黑色皮肤照射下，MLA 产生的激光诱导空泡分布更深（180-400μm；67μm 大小），而 DOE（180-280μm；40μm 大小）则更深。然而，白色皮肤在更深的分布（125-700μm）中产生了更大的空泡（134μm 大小），数量较少，与黑色皮肤的 MLA 相比。DOE 未在白色皮肤中产生激光诱导空化。固有散射较高的白色皮肤组织可能是皮秒激光治疗后空化更深的原因。预计将进一步研究确定各种皮肤类型的最佳治疗条件。

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激光诱导光击穿对 1064nm 皮秒激光治疗期间皮肤类型的依赖性。

Dependence of laser-induced optical breakdown on skin type during 1064 nm picosecond laser treatment.

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