Focal point technology: Controlling treatment depth and pattern of skin injury by a novel highly focused laser.

IF 12.8 1区医学 Q1 DERMATOLOGY

Journal of the American Academy of Dermatology Pub Date : 2025-01-01 Epub Date: 2024-09-07 DOI:10.1016/j.jaad.2024.09.004

Dieter Manstein, Henry H Chan, Jayant Bhawalkar, Irina Erenburg, Hyemin Pomerantz, Jhony Escobar, Zeina Tannous, Jane Yoo, Thanh-Nga Tran, Raj Katkam, R Rox Anderson

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引用次数: 0

Abstract

Background: Selective photothermolysis has limitations in efficacy and safety for dermal targets. We describe a novel concept using scanned focused laser microbeams for precise control of dermal depth and pattern of injury, using a 1550 nm laser that generates an array of conical thermal zones while minimizing injury to the epidermis.

Objective: To characterize the conical thermal zones in vivo and determine safe starting parameters to transition to a second phase to explore potential clinical indications.

Methods: A focused toroidal (ring) laser beam was delivered through a cold sapphire window, sparing epidermal injury in a central zone. Pulse energy, lesion depth, density, and energy delivery were titrated in ex vivo human skin and subsequently on the backs of 21 human subjects.

Results: Histology showed microscale patterns of thermal injury, which varied predictably with laser parameters. Time-course healing through histology and skin surface imaging demonstrated the ability of the device to deliver high energies without sequelae.

Limitations: Clinical data are currently being collected to further explore the safety and efficacy of the device.

Conclusion: The 1550 nm laser with focal point technology enables precise control of lesion depth while simultaneously sparing a large portion of the epidermis, lowering the risk of adverse effects.

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焦点技术：利用新型高聚焦激光控制治疗深度和皮肤损伤模式。

背景：选择性光热解对真皮目标的疗效和安全性都有局限性。我们介绍了一种新概念，即利用扫描聚焦激光微光束精确控制真皮深度和损伤模式，使用 1550 nm 激光产生锥形热区（CTZ）阵列，同时最大限度地减少对表皮的损伤：目的：描述 CTZ 的活体特征，确定安全的起始参数，以便过渡到第二阶段，探索潜在的临床适应症：方法：聚焦环形（环状）激光束通过冷蓝宝石窗口发射，在中央区域避免表皮损伤。在活体外人体皮肤上对脉冲能量、损伤深度、密度和能量传输进行了滴定，随后在 21 名受试者的背部进行了滴定：结果：组织学显示热损伤的微尺度模式随激光参数的变化而变化。组织学和皮肤表面成像显示，该设备有能力提供高能量而不产生后遗症：目前正在收集临床数据，以进一步探索该设备的安全性和有效性：采用焦点技术的 1550nm 激光可精确控制病变深度，同时保留大部分表皮，降低不良反应的风险。

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

Journal of the American Academy of Dermatology 医学-皮肤病学

CiteScore

8.60

自引率

5.80%

发文量

2023

审稿时长

49 days

期刊介绍： The Journal of the American Academy of Dermatology (JAAD) is the official scientific publication of the American Academy of Dermatology (AAD). Its primary goal is to cater to the educational requirements of the dermatology community. Being the top journal in the field, JAAD publishes original articles that have undergone peer review. These articles primarily focus on clinical, investigative, and population-based studies related to dermatology. Another key area of emphasis is research on healthcare delivery and quality of care. JAAD also highlights high-quality, cost-effective, and innovative treatments within the field. In addition to this, the journal covers new diagnostic techniques and various other topics relevant to the prevention, diagnosis, and treatment of skin, hair, and nail disorders.