不同类型听力损失对耳蜗微力学的影响

2015 IEEE 15th International Conference on Bioinformatics and Bioengineering (BIBE) Pub Date : 2015-11-02 DOI:10.1109/BIBE.2015.7367683

G. Ni, S. Elliott

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引用次数: 1

摘要

听力损失的原因很复杂，目前还不完全清楚其机制。外毛细胞(OHC)的损失被认为起着重要的作用。实验观察表明，耳毒性酸对羟基碳化物的损伤从最外层到最内层开始，而强噪声暴露导致的羟基碳化物损失从最内层到最外层发生。受这些实验的启发，本研究采用有限元方法建立了包括耳蜗精细结构在内的人类耳蜗切片的详细模型。OHC运动是通过在OHC两端施加力来响应立体纤毛偏转来实现的，这被认为是耳蜗放大的关键过程。这样，由于强噪声暴露或耳毒性酸造成的热碳化合物损失的影响可以通过抑制单个热碳化合物的力来研究。因此可以预测不同的听力损失机制导致的耳蜗机械放大和耳蜗内振动模式的变化。

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Change of cochlear micromechanics due to different types of hearing loss

The reasons for hearing loss are complex and currently the mechanics are not entirely clear. Outer hair cell (OHC) loss is believed to play an important role. Experimental observations shown that damage on OHCs due to ototoxic acid starts from the outermost row to the innermost row, whereas, loss of OHCs due to intense noise exposure occurs from the innermost row to the outermost row. Inspired by these experiments, this study employs the finite element method to develop a detailed model of a slice of the human cochlea including cochlear fine structures. OHC motility is implemented by applying forces at the two ends of the OHCs in response to stereocilia deflection, which are believed to be a key process in cochlear amplification. In this way, the effects of a loss of OHCs due to either intense noise exposure or ototoxic acid can be studied by suppressing forces on individual OHCs. Change of cochlear mechanical amplification and vibration patterns inside the organ of Corti due to different hearing loss mechanisms can thus be predicted.

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2015 IEEE 15th International Conference on Bioinformatics and Bioengineering (BIBE)

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