Reissner 膜上的波:从耳蜗传播耳声发射的一种机制。
Waves on Reissner's membrane: a mechanism for the propagation of otoacoustic emissions from the cochlea.
机构信息
Howard Hughes Medical Institute and Laboratory of Sensory Neuroscience, The Rockefeller University, New York, NY 10065-6399, USA.
出版信息
Cell Rep. 2012 Apr 19;1(4):374-84. doi: 10.1016/j.celrep.2012.02.013.
Abstract
Sound is detected and converted into electrical signals within the ear. The cochlea not only acts as a passive detector of sound, however, but can also produce tones itself. These otoacoustic emissions are a striking manifestation of the cochlea's mechanical active process. A controversy remains of how these mechanical signals propagate back to the middle ear, from which they are emitted as sound. Here, we combine theoretical and experimental studies to show that mechanical signals can be transmitted by waves on Reissner's membrane, an elastic structure within the cochlea. We develop a theory for wave propagation on Reissner's membrane and its role in otoacoustic emissions. Employing a scanning laser interferometer, we measure traveling waves on Reissner's membrane in the gerbil, guinea pig, and chinchilla. The results are in accord with the theory and thus support a role for Reissner's membrane in otoacoustic emissions.
摘要
声音在耳朵内被检测并转换为电信号。耳蜗不仅是声音的被动检测器,还可以自身产生音调。这些耳声发射是耳蜗机械主动过程的显著表现。机械信号如何从耳蜗传播回中耳并作为声音发出,这仍然存在争议。在这里,我们结合理论和实验研究表明,机械信号可以通过 Reissner 膜上的波传播,Reissner 膜是耳蜗内的一种弹性结构。我们为 Reissner 膜上的波传播及其在耳声发射中的作用建立了一个理论。我们使用扫描激光干涉仪测量了沙鼠、豚鼠和南美栗鼠中 Reissner 膜上的行波。结果与理论相符,因此支持 Reissner 膜在耳声发射中的作用。
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