Analyzing the effect of undermining on suture forces during simulated skin flap surgeries with a three-dimensional finite element method

IF 2.5 4区计算机科学 Q2 COMPUTER SCIENCE, SOFTWARE ENGINEERING

Computers & Graphics-Uk Pub Date : 2024-08-22 DOI:10.1016/j.cag.2024.104057

Wenzhangzhi Guo , Allison Tsz Kwan Lau , Joel C. Davies , Vito Forte , Eitan Grinspun , Lueder Alexander Kahrs

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Abstract

Skin flaps are common procedures used by surgeons to cover an excised area during the reconstruction of a defect. It is often a challenging task for a surgeon to come up with the most optimal design for a patient. In this paper, we set up a simulation system based on the finite element method for one of the most common flap types — the rhomboid flap. Instead of using the standard 2D planar patch, we constructed a 3D patch with multiple layers. This allowed us to investigate the impact of different undermining areas and depths. We compared the suture forces for each case and identified vertices with the largest suture force. The shape of the final suture line is also visualized for each case, which is an important clue when deciding on the most optimal skin flap orientation according to medical textbooks. We found that under the optimal undermining setup, the maximum suture force is around 0.7 N for top of the undermined layer and 1.0 N for bottom of the undermined layer. When measuring difference in final suture line shape, the maximum normalized Hausdorff distance is 0.099, which suggests that different undermining region can have significant impact on the shape of the suture line, especially in the tail region. After analyzing the suture force plots, we provided recommendations on the most optimal undermining region for rhomboid flaps.

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用三维有限元方法分析在模拟皮瓣手术中破坏对缝合力的影响

皮瓣是外科医生在重建缺损时用来覆盖切除区域的常用程序。对于外科医生来说，为患者设计出最理想的皮瓣往往是一项极具挑战性的任务。在本文中，我们针对最常见的皮瓣类型之一--斜方形皮瓣，建立了一个基于有限元法的模拟系统。我们没有使用标准的二维平面补片，而是构建了一个具有多层的三维补片。这样，我们就能研究不同破坏区域和深度的影响。我们比较了每个病例的缝合力，并确定了缝合力最大的顶点。每个病例最终缝合线的形状也可视化，这是在根据医学教科书决定最佳皮瓣方向时的重要线索。我们发现，在最佳埋线设置下，埋线层顶部的最大缝合力约为 0.7 N，埋线层底部的最大缝合力约为 1.0 N。在测量最终缝合线形状的差异时，最大归一化豪斯多夫距离为 0.099，这表明不同的破坏区域会对缝合线的形状产生显著影响，尤其是在尾部区域。在分析了缝合力图之后，我们对斜方形皮瓣的最佳下拉区域提出了建议。

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

Computers & Graphics-Uk 工程技术-计算机：软件工程

CiteScore

5.30

自引率

12.00%

发文量

173

审稿时长

38 days

期刊介绍： Computers & Graphics is dedicated to disseminate information on research and applications of computer graphics (CG) techniques. The journal encourages articles on: 1. Research and applications of interactive computer graphics. We are particularly interested in novel interaction techniques and applications of CG to problem domains. 2. State-of-the-art papers on late-breaking, cutting-edge research on CG. 3. Information on innovative uses of graphics principles and technologies. 4. Tutorial papers on both teaching CG principles and innovative uses of CG in education.