A Computational Study on Effects of PID Temperature Target and RF Frequency for PID-Controlled Nonablative RF Cosmetic Systems.

IF 2.2 3区医学 Q2 DERMATOLOGY

Lasers in Surgery and Medicine Pub Date : 2024-11-04 DOI:10.1002/lsm.23855

Lu-Xiao Wang, Xiang-Yong Kong, Tong-Juan Zhou

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引用次数: 0

Abstract

Background and objectives: Commonly adopted in cosmetic dermatology, nonablative radiofrequency (RF) devices convert high-frequency electromagnetic energy into thermal energy to induce a wound-healing response in skin tissue. However, differences in the electrical properties of different skin layers raise questions about the impact of different RF frequencies and target temperatures on treatment effectiveness. This paper presents a finite element analysis (FEA)-based computational study aimed at simulating and optimizing the effects of a proportional integral derivative (PID)-controlled RF cosmetic devices under different combinations of these two parameters during treatment.

Study design/materials and methods: A 3D physical model for the application of a nonablative RF device was constructed using COMSOL, which included the human tissue and RF electrodes, electromagnetic and thermal boundary conditions, as well as the PID controller. FEA was performed for each of the twelve models with parameter combinations of three RF frequencies (0.1, 0.5, and 1 MHz) and three PID-controlled target temperatures (60°C, 65°C, and 70°C) plus one group without PID control. Treatment effectiveness was quantitatively assessed using the integration of tissue thermal damage fraction, i.e., thermal damage volume.

Results: In the earlier stage of heating (0-10 s), higher RF frequency resulted in a larger thermal damage volume. At 10 s, among models with a temperature target of 70°C, there is a 6.04% difference between the thermal damage volume at RF frequencies of 1.0 and 0.1 MHz. In the later stage of heating(11-80 s), the impact of RF frequency decreases. The difference in thermal damage volume caused by higher temperature targets is more significant, at 80 s, among models with an RF frequency of 1.0 MHz, the 70°C model produces 1.15 and 1.36 times more tissue thermal damage than the 65°C and 60°C models.

Conclusion: PID controller has ensured treatment safety and uniformity, in exchange for some efficiency. Among 12 parameter combinations, the one with a temperature of 70°C and RF frequency of 1.0 MHz achieved the highest thermal damage volume, which could potentially result in the best esthetic effect. Considering users' different susceptibility to heat, engineers or physicians can select better temperature targets and RF frequencies to bring the desired cosmetic results based on thermal damage volume curves from this study.

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关于 PID 温度目标和射频频率对 PID 控制非烧蚀射频美容系统影响的计算研究。

背景和目的：非烧蚀射频（RF）设备通常用于皮肤美容，它能将高频电磁能转化为热能，诱导皮肤组织产生伤口愈合反应。然而，不同皮肤层的电特性存在差异，这就提出了不同射频频率和目标温度对治疗效果的影响问题。本文介绍了一项基于有限元分析（FEA）的计算研究，旨在模拟和优化比例积分导数（PID）控制的射频美容设备在治疗过程中这两个参数的不同组合下的效果：研究设计/材料和方法：使用 COMSOL 建立了应用非烧蚀射频设备的三维物理模型，其中包括人体组织和射频电极、电磁和热边界条件以及 PID 控制器。对三种射频频率（0.1、0.5 和 1 MHz）和三种 PID 控制目标温度（60°C、65°C 和 70°C）的参数组合以及一组无 PID 控制的模型分别进行了有限元分析。治疗效果通过整合组织热损伤分数（即热损伤体积）进行定量评估：结果：在加热的早期阶段（0-10 秒），射频频率越高，热损伤体积越大。10 秒时，在温度目标为 70°C 的模型中，射频频率为 1.0 和 0.1 MHz 时的热损伤体积相差 6.04%。在加热后期（11-80 秒），射频频率的影响减小。在 80 秒时，射频频率为 1.0 MHz 的模型中，70°C 模型产生的组织热损伤分别是 65°C 和 60°C 模型的 1.15 倍和 1.36 倍：结论：PID 控制器确保了治疗的安全性和均匀性，同时也提高了治疗效率。在 12 种参数组合中，温度为 70°C、射频频率为 1.0 MHz 的参数组合所产生的热损伤量最大，可能带来最佳的美容效果。考虑到使用者对热的敏感性不同，工程师或医生可以根据本研究的热损伤量曲线选择更好的温度目标和射频频率，以达到理想的美容效果。

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.