生物膜机电学,重点关注听觉
Membrane Electromechanics in Biology, with a Focus on Hearing.
作者信息
Sachs F, Brownell W E, Petrov A G
出版信息
MRS Bull. 2009 Sep 1;34(9):665. doi: 10.1557/mrs2009.178.
Abstract
Cells are ion conductive gels surrounded by a ~5-nm-thick insulating membrane, and molecular ionic pumps in the membrane establish an internal potential of approximately -90 mV. This electrical energy store is used for high-speed communication in nerve and muscle and other cells. Nature also has used this electric field for high-speed motor activity, most notably in the ear, where transduction and detection can function as high as 120 kHz. In the ear, there are two sets of sensory cells: the "inner hair cells" that generate an electrical output to the nervous system and the more numerous "outer hair cells" that use electromotility to counteract viscosity and thus sharpen resonance to improve frequency resolution. Nature, in a remarkable exhibition of nanomechanics, has made out of soft, aqueous materials a microphone and high-speed decoder capable of functioning at 120 kHz, limited only by thermal noise. Both physics and biology are only now becoming aware of the material properties of biomembranes and their ability to perform work and sense the environment. We anticipate new examples of this biopiezoelectricity will be forthcoming.
摘要
细胞是由一层约5纳米厚的绝缘膜包裹的离子导电凝胶,膜中的分子离子泵建立起约-90毫伏的内部电势。这种电能储存用于神经、肌肉和其他细胞的高速通信。自然界也将这种电场用于高速运动活动,最显著的是在耳朵中,在那里转换和检测功能的频率可高达120千赫。耳朵中有两组感觉细胞:向神经系统产生电输出的“内毛细胞”和数量更多的利用电运动来抵消粘性从而增强共振以提高频率分辨率的“外毛细胞”。自然界以一种非凡的纳米力学展示,用柔软的水性材料制造出了一个能够在120千赫下工作的麦克风和高速解码器,仅受热噪声限制。物理学和生物学直到现在才开始认识到生物膜的材料特性及其做功和感知环境的能力。我们预计这种生物压电性的新例子将会出现。
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