Biomechanics of flail chest injuries: tidal volume and respiratory work changes in multiple segmental rib fractures.

IF 1.9 3区医学 Q2 EMERGENCY MEDICINE

European Journal of Trauma and Emergency Surgery Pub Date : 2025-01-17 DOI:10.1007/s00068-024-02754-x

Julian N Zierke, Georg N Duda, Karl F Braun, Vera Jaecker, Ulrich Stöckle, Philipp Damm, Mark Heyland, Marcel Niemann

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引用次数: 0

Abstract

Background: Flail chest (FC) injuries are segmental osseous injuries of the thorax that typically result from high-energy blunt trauma and regularly occur in multiple trauma (MT) patients. FC injuries are associated with paradoxical chest wall movements and, thus, have a high risk of respiratory insufficiency or even death. An increasing number of studies recommend an early surgical stabilization of FC injuries, but a definite trigger that would indicate surgery has, thus far, not been identified.

Methods: Based on real-world injury computed tomography (CT) data, this study aimed to establish a finite elements (FE) model of a thorax simulating spontaneous breathing. The model is based on a 0.625 mm slice thickness CT data set. In this FE model, various FC injury patterns were implemented to examine the impact of an increasingly large flail segment on tidal volume and respiratory work. The impact of the segmental defect sizes on the outcome measures mentioned above was examined using correlation analyses.

Results: The FE model in this study reliably simulated the spontaneous breathing patterns of an actively breathing patient in an uninjured setting as a reference and showed clinically realistic movements of the flail segments for various injury settings. Correlation analysis showed a significant negative correlation between the FC size and tidal volume (R² = 0.852, p = 0.003), while absolute (R² = 0.845, p = 0.0096) and relative loss (R² = 0.844, p = 0.0096) of tidal volume concerning the intact model and the compensatory respiratory work required (R² = 0.816, p = 0.0136) were positively correlated with FC size.

Conclusion: This study presents an FE model of the thorax of a patient who presented to our clinic as an MT patient with an FC injury. The FE model fulfills physiologic active breathing patterns and simulates an FC injury's paradoxical movement, realistically depicting clinical observations. The FE model showed that the number of consecutive ribs involved in the flail segment and the length of the flail segment significantly impacted active breathing concerning tidal volumes and respiratory work. With this, we have made the first step to define a trigger for surgery.

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连枷胸损伤的生物力学：多节段肋骨骨折的潮气量和呼吸功变化。

背景：连枷胸（FC）损伤是胸部的节段性骨损伤，通常由高能钝性创伤引起，通常发生在多发创伤（MT）患者中。FC损伤与矛盾的胸壁运动有关，因此，呼吸功能不全甚至死亡的风险很高。越来越多的研究建议对FC损伤进行早期手术稳定，但到目前为止，还没有确定一个明确的触发手术的因素。方法：基于真实损伤CT数据，建立模拟胸腔自主呼吸的有限元模型。该模型基于0.625 mm层厚CT数据集。在这个有限元模型中，我们采用了不同的FC损伤模式来检验连枷段越来越大对潮气量和呼吸功的影响。使用相关分析检查了上面提到的片段缺陷大小对结果度量的影响。结果：本研究的FE模型可靠地模拟了未受伤情况下主动呼吸患者的自主呼吸模式，作为参考，并显示了各种损伤情况下连枷节段的临床真实运动。相关分析显示，FC大小与潮气量呈显著负相关（R2 = 0.852, p = 0.003），而完整模型潮气量的绝对损失（R2 = 0.845, p = 0.0096）和所需代偿呼吸功的相对损失（R2 = 0.844, p = 0.0096）与FC大小呈正相关（R2 = 0.816, p = 0.0136）。结论：本研究提出了一个以FC损伤的MT患者的胸腔FE模型。FE模型实现了生理性的主动呼吸模式，模拟了FC损伤的矛盾运动，真实地描绘了临床观察结果。有限元模型显示，连枷段连续肋骨数和连枷段长度对潮气量和呼吸功的主动呼吸有显著影响。有了这个，我们已经迈出了确定手术触发因素的第一步。

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

European Journal of Trauma and Emergency Surgery 医学-急救医学

CiteScore

4.50

自引率

14.30%

发文量

311

审稿时长

3 months

期刊介绍： The European Journal of Trauma and Emergency Surgery aims to open an interdisciplinary forum that allows for the scientific exchange between basic and clinical science related to pathophysiology, diagnostics and treatment of traumatized patients. The journal covers all aspects of clinical management, operative treatment and related research of traumatic injuries. Clinical and experimental papers on issues relevant for the improvement of trauma care are published. Reviews, original articles, short communications and letters allow the appropriate presentation of major and minor topics.