Impact of skin hydration on patterns of microthermal injury produced by fractional CO2 laser

IF 2.2 3区医学 Q2 DERMATOLOGY Lasers in Surgery and Medicine Pub Date : 2023-11-21 DOI:10.1002/lsm.23741

Emily Wenande MD, PhD, Anna Hastrup BSc, Gabriella Louise Fredman MD, Uffe Høgh Olesen PhD, Albert Wolkerstorfer MD, PhD, Merete Haedersdal MD, PhD, DMSc

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Abstract

Objectives

The impact of skin hydration on patterns of thermal injury produced by ablative fractional lasers (AFLs) is insufficiently examined under standardized conditions. Using skin with three different hydration levels, this study assessed the effect of hydration status on microchannel dimensions generated by a fractional CO₂ laser.

Methods

A hydration model (hyperhydrated-, dehydrated- and control) was established in ex vivo porcine skin, validated by changes in surface conductance and sample mass. After, samples underwent AFL exposure using a CO₂ laser (10,600 nm) at two examined pulse energies (10 and 30 mJ/mb, fixed 10% density, six repetitions per group). Histological assessment of distinct microchannels (n = 60) determined three standardized endpoints in H&E sections: (1) depth of microthermal treatment zones (MTZs), (2) depth of microscopic ablation zones (MAZs), and (3) coagulation zone (CZ) thickness. As a supplemental in vivo assessment, the same laser settings were applied to hyperhydrated- (7-h occlusion) and normohydrated forearm skin (no pretreatment) of a human volunteer. Blinded measurement of MAZ depth (n = 30) was performed using noninvasive optical coherence tomography (OCT).

Results

Modest differences in microchannel dimensions were shown between hyperhydrated, dehydrated and control skin at both high and low pulse energy. Compared to controls, hyperhydration led to median reductions in MTZ and MAZ depth ranging from 5% to 8% (control vs. hyperhydrated at 30 mJ/mb; 848 vs. 797 µm (p < 0.003) (MAZ); 928 vs. 856 µm (p < 0.003) (MTZ)), while 14%–16% reductions were shown in dehydrated skin (control vs. dehydrated at 30 mJ/mb; MAZ: 848 vs. 727 µm (p < 0.003); MTZ: 928 vs. 782 µm (p < 0.003)). The impact of skin hydration on CZ thickness was in contrast limited. Corresponding with ex vivo findings, hyperhydration was similarly associated with lower ablative depth in vivo skin. Thus, median MAZ depth in hydrated skin was 10% and 14% lower than in control areas at 10 and 30 mJ/mb pulse energy, respectively (10 mJ: 210 vs. 180 µm (p < 0.001); 30 mJ: 335 vs. 300 µm (p < 0.001)).

Conclusion

Skin hydration status can exert a minimal impact on patterns of microthermal injury produced by fractional CO₂ lasers, although the clinical implication in the context of laser therapy requires further study.

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皮肤水合作用对CO2激光微热损伤模式的影响。

目的:在标准化条件下，皮肤水合作用对烧蚀分数激光(afl)产生的热损伤模式的影响尚不充分。使用三种不同水合水平的皮肤，本研究评估了水合状态对分数CO2激光产生的微通道尺寸的影响。方法:在离体猪皮肤上建立水化模型(过度水化、脱水水化和对照水化)，并通过表面电导和样品质量的变化进行验证。之后，样品使用CO2激光(10,600 nm)以两种检测脉冲能量(10和30 mJ/mb，固定10%密度，每组6次重复)进行AFL暴露。不同微通道的组织学评估(n = 60)确定了H&E切片的三个标准化终点:(1)微热处理区深度(MTZs)，(2)显微消融区深度(maz)，(3)凝固区厚度(CZ)。作为补充体内评估，将相同的激光设置应用于人类志愿者的过度水合(7小时闭塞)和正常水合前臂皮肤(未预处理)。采用无创光学相干断层扫描(OCT)对MAZ深度(n = 30)进行盲法测量。结果:在高、低脉冲能量下，超水合皮肤、脱水皮肤和对照皮肤的微通道尺寸存在适度差异。与对照组相比，过度水合导致MTZ和MAZ深度中位数减少5%至8%(对照组与过度水合30 mJ/mb;结论:皮肤水合状态可以对分数CO2激光产生的微热损伤模式产生最小的影响，尽管在激光治疗背景下的临床意义需要进一步研究。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Lasers in Surgery and Medicine 医学-外科

CiteScore

5.40

自引率

12.50%

发文量

119

审稿时长

1 months

期刊介绍： Lasers in Surgery and Medicine publishes the highest quality research and clinical manuscripts in areas relating to the use of lasers in medicine and biology. The journal publishes basic and clinical studies on the therapeutic and diagnostic use of lasers in all the surgical and medical specialties. Contributions regarding clinical trials, new therapeutic techniques or instrumentation, laser biophysics and bioengineering, photobiology and photochemistry, outcomes research, cost-effectiveness, and other aspects of biomedicine are welcome. Using a process of rigorous yet rapid review of submitted manuscripts, findings of high scientific and medical interest are published with a minimum delay.