确定脑-颅骨界面在拉伸和压缩条件下的机械特性

Sajjad Arzemanzadeh, Benjamin Zwick, Karol Miller, Tim Rosenow, Stuart I. Hodgetts, Adam Wittek
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引用次数: 0

摘要

大脑的计算生物力学模型已成为研究大脑对机械负荷反应的重要工具。此类脑模型的几何形状、加载条件和构成特性已得到深入研究和普遍认可。然而,连接大脑和头骨的组织层(脑-颅界面)模型缺乏实验证据支持,而这些组织层决定了大脑的边界条件。我们提出了一种确定脑颅界面生物力学特性的新方案,并展示了初步结果(针对从绵羊尸体头部提取的少量组织样本)。该方法包括使用脑组织和脑-颅复合体(由脑组织、脑-颅界面和颅骨组成)进行生物力学实验,以及使用有限元(FE)方法对实验进行全面的计算机模拟。在确定描述脑组织和脑-颅骨界面生物力学行为的参数时,有限元模拟的应用使我们放弃了传统的依赖于假定立方体(或圆柱形)样本几何形状的分析方法。在模拟中,我们使用了从磁共振成像(MRI)中获得的样品的精确三维几何形状。我们的结果表明,脑-颅骨界面在压缩载荷下的行为与在拉伸载荷下的行为明显不同。在拉伸负荷下,界面破裂清晰可见,而在压缩负荷下,没有观察到明显的机械故障迹象。这些结果表明,假定脑组织和颅骨之间存在坚硬连接或无摩擦滑动接触(这是大脑生物力学计算模型中经常使用的方法),可能无法准确表示大脑-颅骨界面的机械行为。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Towards Determining Mechanical Properties of Brain-Skull Interface Under Tension and Compression
Computational biomechanics models of the brain have become an important tool for investigating the brain responses to mechanical loads. The geometry, loading conditions, and constitutive properties of such brain models are well-studied and generally accepted. However, there is a lack of experimental evidence to support models of the layers of tissues (brain-skull interface) connecting the brain with the skull which determine boundary conditions for the brain. We present a new protocol for determining the biomechanical properties of the brain-skull interface and present the preliminary results (for a small number of tissue samples extracted from sheep cadaver heads). The method consists of biomechanical experiments using brain tissue and brain-skull complex (consisting of the brain tissue, brain-skull interface, and skull bone) and comprehensive computer simulation of the experiments using the finite element (FE) method. Application of the FE simulations allowed us to abandon the traditionally used approaches that rely on analytical formulations that assume cuboidal (or cylindrical) sample geometry when determining the parameters that describe the biomechanical behaviour of the brain tissue and brain-skull interface. In the simulations, we used accurate 3D geometry of the samples obtained from magnetic resonance images (MRIs). Our results indicate that the behaviour of the brain-skull interface under compressive loading appreciably differs from that under tension. Rupture of the interface was clearly visible for tensile load while no obvious indication of mechanical failure was observed under compression. These results suggest that assuming a rigid connection or frictionless sliding contact between the brain tissue and skull bone, the approaches often used in computational biomechanics models of the brain, may not accurately represent the mechanical behaviour of the brain-skull interface.
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