Point Cloud Registration for Measuring Shape Dependence of Soft Tissue Deformation by Digital Twins in Head and Neck Surgery

Biomedicine hub Pub Date : 2024-01-09 DOI:10.1159/000535421

Sara Monji-Azad, D. Männle, Jürgen Hesser, Jan Pohlmann, N. Rotter, Annette Affolter, Cleo-Aron Weis, Sonja Ludwig, Claudia Scherl

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Abstract

Introduction: A 2½ D point cloud registration method was developed to generate digital twins of different tissue shapes and resection cavities by applying a machine learning (ML) approach. This demonstrates the feasibility of quantifying soft tissue shifts. Methods: An ML model was trained using simulated surface scan data obtained from tumor resections in a pig head cadaver model. It hereby uses 438 2½ D scans of the tissue surface. Tissue shift was induced by a temperature change from 7.91 ± 4.1°C to 36.37 ± 1.28°C. Results: Digital twins were generated from various branched and compact resection cavities (RCs) and cut tissues (CT). A temperature increase induced a tissue shift with a significant volume increase of 6 mL and 2 mL in branched and compact RCs, respectively (p = 0.0443; 0.0157). The volumes of branched and compact CT were decreased by 3 and 4 mL (p < 0.001). In the warm state, RC and CT no longer fit together because of the significant tissue deformation. Although not significant, the compact RC showed a greater tissue deformation of 1 μL than the branched RC with 0.5 μL induced by the temperature change (p = 0.7874). The branched and compact CT forms responded almost equally to changes in temperature (p = 0.1461). Conclusions: The simulation experiment of induced soft tissue deformation using digital twins based on 2½ D point cloud models proved that our method helps to quantify shape-dependent tissue shifts.

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在头颈部手术中利用数字双胞胎测量软组织变形的形状依赖性的点云注册技术

简介通过应用机器学习（ML）方法，开发了一种 2½ D 点云配准方法，用于生成不同组织形状和切除腔的数字双胞胎。这证明了量化软组织移位的可行性。方法：使用从猪头尸体模型的肿瘤切除术中获得的模拟表面扫描数据训练 ML 模型。该模型使用了 438 次组织表面的 2½ D 扫描。温度从 7.91 ± 4.1°C 变化到 36.37 ± 1.28°C，诱发组织移动。结果：从不同的分支和紧凑切除腔（RC）和切口组织（CT）中生成了数字孪晶。温度升高会引起组织转移，支离和紧密 RC 的体积分别显著增加 6 mL 和 2 mL（p = 0.0443; 0.0157）。分枝型和紧密型 CT 的体积分别减少了 3 毫升和 4 毫升（p < 0.001）。在温热状态下，RC 和 CT 由于组织的显著变形而不再吻合。紧凑型 RC 的组织变形量为 1 μL，而支化型 RC 的组织变形量为 0.5 μL，虽然不明显，但温度变化引起的组织变形量更大（p = 0.7874）。分枝型和紧密型 CT 对温度变化的反应几乎相同（p = 0.1461）。得出结论：使用基于 2½ D 点云模型的数字双胞胎进行的软组织诱导变形模拟实验证明，我们的方法有助于量化与形状相关的组织变化。

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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Biomedicine hub

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