Finite Element Tissue Strains Computation to Evaluate the Mechanical Protection Provided by a New Bilayer Dressing for Heel Pressure Injuries.

IF 1.7 4区医学 Q3 DERMATOLOGY Advances in Skin & Wound Care Pub Date : 2023-10-01 DOI:10.1097/ASW.0000000000000042

Nolwenn Fougeron, Gregory Chagnon, Nathanael Connesson, Thierry Alonso, Laurent Pasquinet, Stephane Auguste, Antoine Perrier, Yohan Payan

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Abstract

Objective: Pressure injuries (PIs) result in an extended duration of care and increased risks of complications for patients. When treating a PI, the aim is to hinder further PI development and speed up the healing time. Urgo RID recently developed a new bilayer dressing to improve the healing of stages 2 and 3 heel PIs. This study aims to numerically investigate the efficiency of this new bilayer dressing to reduce strains around the PI site.

Methods: The researchers designed three finite element models based on the same heel data set to compare the Green-Lagrange compressive and maximal shear strains in models without a PI, with a stage 2 PI, and with a stage 3 PI. Simulations with and without the dressing were computed. Analysis of the results was performed in terms of strain clusters, defined as volumes of tissues with high shear and compressive strains.

Results: Decreases in the peak and mean values of strains were low in all three models, between 0% and 20%. However, reduction of the strain cluster volumes was high and ranged from 55% to 68%.

Conclusions: The cluster analysis enables the robust quantitative comparison of finite element analysis. Results suggest that use of the new bilayer dressing may reduce strain around the PI site and that this dressing could also be used in a prophylactic manner. Results should be extended to a larger cohort of participants.

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有限元组织应变计算评估新型双层敷料对足跟压力损伤的机械保护作用。

目的：压力性损伤会延长患者的护理时间，增加并发症的风险。治疗PI时，目的是阻碍PI的进一步发展并加快愈合时间。Urgo RID最近开发了一种新的双层敷料，以改善2期和3期足跟PIs的愈合。本研究旨在数值研究这种新型双层敷料减少PI位点周围应变的效率。方法：研究人员基于相同的足跟数据集设计了三个有限元模型，以比较没有PI、第2阶段PI和第3阶段PI的模型中的Green Lagrange压缩应变和最大剪切应变。计算了有和没有敷料的模拟。根据应变簇对结果进行分析，应变簇定义为具有高剪切和压缩应变的组织体积。结果：在所有三个模型中，菌株的峰值和平均值的降低都很低，在0%到20%之间。然而，菌株簇体积的减少幅度很大，在55%到68%之间。结论：聚类分析能够实现有限元分析的稳健定量比较。结果表明，使用新的双层敷料可以减少PI位点周围的应变，并且这种敷料也可以以预防性的方式使用。结果应该扩大到更大的参与者群体。

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

Advances in Skin & Wound Care DERMATOLOGY-NURSING

CiteScore

2.50

自引率

12.50%

发文量

271

审稿时长

>12 weeks

期刊介绍： A peer-reviewed, multidisciplinary journal, Advances in Skin & Wound Care is highly regarded for its unique balance of cutting-edge original research and practical clinical management articles on wounds and other problems of skin integrity. Each issue features CME/CE for physicians and nurses, the first journal in the field to regularly offer continuing education for both disciplines.