期刊
MRS BULLETIN
卷 34, 期 9, 页码 665-670出版社
CAMBRIDGE UNIV PRESS
DOI: 10.1557/mrs2009.178
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资金
- NIH [DC 00354, DC 02775]
- Bulgarian Fund [NT 1-03/2004]
- NATIONAL INSTITUTE ON DEAFNESS AND OTHER COMMUNICATION DISORDERS [R01DC002775, F32DC000354, R01DC000354] Funding Source: NIH RePORTER
Cells are ion conductive gels surrounded by a similar to 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.
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