Heat Influence on Different Hyaluronic Acid Fillers

Q4 Medicine
P. Kubik, W. Gruszczyński
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引用次数: 0

Abstract

Facial volume deficits, providing long-term facial aesthetic enhancement outcomes for the signs of aging and/or facial contouring. Numerous hyaluronic acid (HA) fillers seem to have similar characteristics, although their properties regarding rheology, viscoelasticity, heat resistance are different in many ways. The resistance heat degradation is important when hyaluronic acid fillers and energy-based devices are going to be used sequentially. Our objective was to determine the characteristics of HA gels in terms of heat resistance. Degradation of the gels was measured as a change of surface area of the sample. Five types of HA fillers, chosen from most common products on the market for temporary correction of congenital and acquired soft tissue deficits of the face via intradermal or subcutaneous injection: 20mg/ml HA-BDDE, 20mg/ml HA-BDDE, 20mg/ml HA-BDDE, 25 mg/ml HA-BDDE, 28mg/ml HA-PEG were tested in this study. Even though the three dermal fillers contained the same concentration of HA and were cross-linked with the same cross-linking agent, they were produced by different manufacturers using different technologies developed by individual companies. We tested in vitro resistance to heat degradation using Celltibator GT (Medikan Co., LTD, Seoul, Rep. of Korea) and Autoclave (Medotti 22L PRO, Poland). All of the HA fillers samples (0,3 ml) were placed on the petri dishes and put into the autoclave for 10 minutes (temp. 72,4°C). Three of the gels samples (20mg/ml HA-BDDE, 25mg/ml HA-BDDE, 28mg/ml HA-PEG) each 0,3ml were placed into Celltibator for 10 min, temp. 55,2°C degree, centrifugation: 30 RPM. Centrifugation was used to imitate the behaviour of the fillers under the conditions of forces acting on it in the tissue (stress under the influence of facial expressions, exercises, etc.). The temperatures used during this test correspond with commonly used heat-based devices, such as radio-frequency devices (about 45°C), infrared (about 55-65°C) and HiFU (about 70-75°C). Before and after each test pictures of the samples were taken. Heat degradation of the HA samples was measured by comparing (before and after) the changes of the surface area of samples on the petri dishes (on the graph paper). The 28-mg/ml HA-PEG gel filler demonstrated greater resistance to heat versus the 20- mg/ml and 25-mg/ml BDDE gel fillers. The 28-mg/ml HA-PEG, demonstrated in both test (celltibator with/without rotation and autoclave) greater resistance to heat in terms of deformation / thermal degradation and change of surface area. Selection of dermal filler with the right rheological properties is a key factor in achieving a natural-looking long-lasting desired aesthetic outcome. Hyaluronic acid fillers combined with energy-based devices are frequently used sequentially during the same session, however, in some cases it might cause thermal damage of HA. Caution is advised in using IR over recently injected filler (selection of dermal fillers is crucial in this case). Study limitations include use of in vitro model and lack of inflammatory response in an ex-vivo model.
热对不同透明质酸填料的影响
面部体积缺陷,为衰老和/或面部轮廓的迹象提供长期的面部美学增强结果。许多透明质酸(HA)填料似乎具有相似的特性,尽管它们在流变性、粘弹性、耐热性等方面的性能在许多方面有所不同。当透明质酸填料和基于能量的设备将依次使用时,耐热降解是重要的。我们的目的是确定HA凝胶在耐热性方面的特性。凝胶的降解通过样品表面积的变化来测量。本研究从市场上最常见的五种HA填充剂中选择,通过皮内或皮下注射暂时矫正面部先天性和后天性软组织缺损:20mg/ml HA- bdde, 20mg/ml HA- bdde, 20mg/ml HA- bdde, 25mg /ml HA- bdde, 28mg/ml HA- peg。尽管这三种皮肤填充剂含有相同浓度的HA,并与相同的交联剂交联,但它们是由不同的制造商使用不同的技术生产的,这些技术是由各个公司开发的。我们使用Celltibator GT (Medikan Co., LTD, Seoul, Rep. of Korea)和Autoclave (Medotti 22L PRO,波兰)进行了体外热降解抗性测试。将所有HA填料样品(0.3 ml)置于培养皿中,放入高压灭菌器中10分钟(温度为72.4°C)。取3份凝胶样品(20mg/ml HA-BDDE、25mg/ml HA-BDDE、28mg/ml HA-PEG),各0.3 ml,置于Celltibator中,温度55℃,2℃,离心:30 RPM。用离心来模拟填料在组织中受到作用力(面部表情、运动等影响下的应力)的情况下的行为。本测试使用的温度对应于常用的基于热的设备,如射频设备(约45℃)、红外设备(约55 ~ 65℃)和HiFU设备(约70 ~ 75℃)。在每次测试前后对样品进行拍照。通过比较培养皿(在图纸上)样品表面积的变化(前后)来测量HA样品的热降解。28毫克/毫升HA-PEG凝胶填料比20毫克/毫升和25毫克/毫升BDDE凝胶填料表现出更大的耐热性。28毫克/毫升的HA-PEG,在两个测试中(有/没有旋转和高压灭菌器),在变形/热降解和表面积变化方面表现出更大的耐热性。选择具有正确流变特性的真皮填充物是实现自然外观持久所需美学结果的关键因素。透明质酸填充剂与能量基装置在同一疗程中经常连续使用,然而,在某些情况下,它可能导致HA的热损伤。在使用IR代替最近注射过的填充物时要谨慎(真皮填充物的选择在这种情况下是至关重要的)。研究的局限性包括使用体外模型和在离体模型中缺乏炎症反应。
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 applied cosmetology
Journal of applied cosmetology Medicine-Dermatology
CiteScore
0.40
自引率
0.00%
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