Exploring the biomechanical response of human semicircular canals by a visualized bionic model.

IF 2.2 4区生物学 Q3 BIOPHYSICS

European Biophysics Journal Pub Date : 2025-03-03 DOI:10.1007/s00249-025-01738-y

Yani Jiang, Xianhua Wen, Guangcheng Xiang, Wenxuan Zhang, Junjie Dai, Junjie Gong, Yixiang Bian

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引用次数: 0

Abstract

At present, research on the biomechanical response of the cupula of human semicircular canals (HSCs) has focused on indirect inference through the nystagmus view, which is limited by the participation of the human nervous system. In this study, 3D printing technology and hydrogel modification methods were used to fabricate a one-dimensional bionic semicircular canal (BSC) model with a ratio of 1:1 to the horizontal HSC. Target tracking technology was used to observe the deformation of the cupula. Then, constant angular acceleration stimulation and the other two stimulations were separately applied to the BSC to explore its biomechanical response. The results showed that the BSC had a similar time constant to that of the HSC, its maximum deviation displacement was proportional to the applied angular acceleration, and its amplitude-frequency gain under sinusoidal oscillation stimulation increased, but its phase difference decreased with increasing frequency, which consistent with the conclusions obtained by our theoretical deduction. The BSC model is expected to play a certain role in the mechanistic research and disease diagnosis of HSCs.

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利用可视化仿生模型探讨人体半规管的生物力学响应。

目前对人体半圆管丘生物力学反应的研究主要集中在眼球震颤视角的间接推断，受限于人体神经系统的参与。本研究采用3D打印技术和水凝胶改性方法制备了与水平HSC比例为1:1的一维仿生半规管（BSC）模型。采用目标跟踪技术观察锥体的变形情况。然后分别施加恒定角加速度刺激和其他两种刺激，研究BSC的生物力学响应。结果表明：BSC与HSC具有相似的时间常数，最大偏差位移与外加角加速度成正比，正弦振荡刺激下的幅频增益增大，但相位差随频率增加而减小，与理论推导一致。BSC模型有望在造血干细胞的机制研究和疾病诊断中发挥一定的作用。

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 Biophysics Journal 生物-生物物理

CiteScore

4.30

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： The journal publishes papers in the field of biophysics, which is defined as the study of biological phenomena by using physical methods and concepts. Original papers, reviews and Biophysics letters are published. The primary goal of this journal is to advance the understanding of biological structure and function by application of the principles of physical science, and by presenting the work in a biophysical context. Papers employing a distinctively biophysical approach at all levels of biological organisation will be considered, as will both experimental and theoretical studies. The criteria for acceptance are scientific content, originality and relevance to biological systems of current interest and importance. Principal areas of interest include: - Structure and dynamics of biological macromolecules - Membrane biophysics and ion channels - Cell biophysics and organisation - Macromolecular assemblies - Biophysical methods and instrumentation - Advanced microscopics - System dynamics.