Optimization of laser technology for removing tatuage pigment

中国激光医学杂志 Pub Date : 2020-09-05 DOI:10.37895/2071-8004-2020-24-1-39-44

E. A. Leontiev, Yu. A. Igonin

{"title":"Optimization of laser technology for removing tatuage pigment","authors":"E. A. Leontiev, Yu. A. Igonin","doi":"10.37895/2071-8004-2020-24-1-39-44","DOIUrl":null,"url":null,"abstract":"Purpose: To study the effectiveness of tattoo pigment removal with laser light depending on the wavelength and depth of penetration into tissues in order to optimize a technique of laser selective photocavitation. Material and methods. 127 male white mongrel rats, aged 8 weeks, were intradermally injected with pigment particles into their backs looking like 2 rows of spots 0.5 cm in diameter. In 6 weeks, 367 skin samples with tattoo pigment were taken. Each sample was a patch of epidermis with pigment crystals surrounded by connective tissue capsules not less than 2.5 mm of thickness. Before the experiment, the epidermal stratum corneum – 10–15 mkm in depth and about 1 mm in diameter- was removed with spray-coagulation (apparatus EHVCH-50-MEDSI). The rest of skin flap surface remained intact. Thus, each skin sample had two areas on the surface – one with removed stratum corneum (experimental) and the other one intact (control). To register changes in the luminous flux, the authors placed an emitter (IPL xenon lamp 7.65.130), tissue sample and photomultiplier (PMT-62) on one and the same axis. To cut off light waves, the authors used a set of light filters – 315, 364, 400, 440, 490, 540, 590, 670, 750, 870, 980 nm. Results. Destruction of skin surface layers was not statistically significant under wavelengths up to 450 nm and after 1000 nm. The epidermal stratum corneum prevents laser light penetration with wavelengths 450–694 nm by 27%, in average, and with wavelengths 700–1000 nm by 33%, in average. Conclusion. Epidermal stratum corneum destruction statistically significantly increases light density in deep tissue layers and increases the depth of penetration of laser light into biological tissues.","PeriodicalId":10008,"journal":{"name":"中国激光医学杂志","volume":"246 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2020-09-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"中国激光医学杂志","FirstCategoryId":"3","ListUrlMain":"https://doi.org/10.37895/2071-8004-2020-24-1-39-44","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 1

Abstract

Purpose: To study the effectiveness of tattoo pigment removal with laser light depending on the wavelength and depth of penetration into tissues in order to optimize a technique of laser selective photocavitation. Material and methods. 127 male white mongrel rats, aged 8 weeks, were intradermally injected with pigment particles into their backs looking like 2 rows of spots 0.5 cm in diameter. In 6 weeks, 367 skin samples with tattoo pigment were taken. Each sample was a patch of epidermis with pigment crystals surrounded by connective tissue capsules not less than 2.5 mm of thickness. Before the experiment, the epidermal stratum corneum – 10–15 mkm in depth and about 1 mm in diameter- was removed with spray-coagulation (apparatus EHVCH-50-MEDSI). The rest of skin flap surface remained intact. Thus, each skin sample had two areas on the surface – one with removed stratum corneum (experimental) and the other one intact (control). To register changes in the luminous flux, the authors placed an emitter (IPL xenon lamp 7.65.130), tissue sample and photomultiplier (PMT-62) on one and the same axis. To cut off light waves, the authors used a set of light filters – 315, 364, 400, 440, 490, 540, 590, 670, 750, 870, 980 nm. Results. Destruction of skin surface layers was not statistically significant under wavelengths up to 450 nm and after 1000 nm. The epidermal stratum corneum prevents laser light penetration with wavelengths 450–694 nm by 27%, in average, and with wavelengths 700–1000 nm by 33%, in average. Conclusion. Epidermal stratum corneum destruction statistically significantly increases light density in deep tissue layers and increases the depth of penetration of laser light into biological tissues.

查看原文本刊更多论文

激光去除残留色素技术的优化

目的:研究激光去除纹身色素的效果与激光穿透组织的波长和深度的关系，以优化激光选择性光空化技术。材料和方法。127只8周龄雄性白杂种大鼠背部皮下注射色素颗粒，形成2排直径0.5 cm的斑点。在6周内，采集了367个带有纹身色素的皮肤样本。每个样品是一个表皮斑块，色素晶体被厚度不小于2.5 mm的结缔组织胶囊包围。实验前，用喷雾凝固法(EHVCH-50-MEDSI仪器)去除表皮角质层(深度10 - 15km，直径约1mm)。皮瓣表面其余部分保持完整。因此，每个皮肤样本的表面都有两个区域——一个是去除角质层的区域(实验)，另一个是完整的区域(对照)。为了记录光通量的变化，作者将发射器(IPL氙灯7.65.130)、组织样品和光电倍增管(PMT-62)放在同一轴上。为了切断光波，作者使用了一组滤光片——315、364、400、440、490、540、590、670、750、870、980 nm。结果。在波长达450 nm和1000 nm之后，皮肤表层的破坏没有统计学意义。角质层对波长为450 ~ 694 nm的激光的平均阻挡率为27%，对波长为700 ~ 1000 nm的激光的平均阻挡率为33%。结论。表皮角质层的破坏显著增加了深层组织层的光密度，增加了激光进入生物组织的穿透深度。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

中国激光医学杂志

自引率

0.00%

发文量

5650

期刊介绍： The main columns of "Chinese Journal of Laser Medicine & Surgery" include treatises, which report the latest research results in basic research and clinical trials in the field of laser medicine; comprehensive reviews of the latest research progress in laser medicine at home and abroad. In addition, there are short reports and excerpts from foreign journals, conference news and other columns. The journal has published a large number of papers on basic research on laser medicine and applied research in various clinical subjects, aiming to play a positive role in promoting the application of laser in medicine and improving the level of laser medicine research.