Markin V S, Hudspeth A J
Howard Hughes Medical Institute, University of Texas Southwestern Medical Center, Dallas 75235-9117, USA.
Biophys J. 1995 Jul;69(1):138-47. doi: 10.1016/S0006-3495(95)79883-6.
The high sensitivity and sharp frequency selectivity of acoustical signal transduction in the cochlea suggest that an active process pumps energy into the basilar membrane's oscillations. This function is generally attributed to outer hair cells, but its exact mechanism remains uncertain. Several classical models of amplification represent the load upon the basilar membrane as a single mass. Such models encounter a fundamental difficulty, however: the phase difference between basilar-membrane movement and the force generated by outer hair cells inhibits, rather than amplifies, the modeled basilar-membrane oscillations. For this reason, modelers must introduce artificially either negative impedance or an appropriate phase shift, neither of which is justified by physical analysis of the system. We consider here a physical model based upon the recent demonstration that the basilar membrane and reticular lamina can move independently, albeit with elastic coupling through outer hair cells. The mechanical model comprises two resonant masses, representing the basilar membrane and the reticular lamina, coupled through an intermediate spring, the outer hair cells. The spring's set point changes in response to displacement of the reticular lamina, which causes deflection of the hair bundles, variation of outer hair cell length and, hence, force production. Depending upon the frequency of the acoustical input, the basilar membrane and reticular lamina can oscillate either in phase or in counterphase. In the latter instance, the force produced by hair cells leads basilar-membrane oscillation, energy is pumped into basilar-membrane movement, and an external input can be strongly amplified. The model is also capable of producing spontaneous oscillation. In agreement with experimental observations, the model describes mechanical relaxation of the basilar membrane after electrical stimulation causes outer hair cells to change their length.
耳蜗中听觉信号转导的高灵敏度和敏锐的频率选择性表明,一种主动过程将能量泵入基底膜的振荡中。这种功能通常归因于外毛细胞,但其确切机制仍不确定。几种经典的放大模型将基底膜上的负载表示为单个质量。然而,这样的模型遇到了一个基本困难:基底膜运动与外毛细胞产生的力之间的相位差会抑制而非放大所模拟的基底膜振荡。因此,建模者必须人为地引入负阻抗或适当的相移,而这两者都没有通过对系统的物理分析得到证实。我们在此考虑一个基于最近证明的物理模型,即基底膜和网状板可以独立移动,尽管通过外毛细胞存在弹性耦合。该力学模型包括两个共振质量,分别代表基底膜和网状板,通过中间弹簧(外毛细胞)耦合。弹簧的设定点会响应网状板的位移而变化,这会导致毛束偏转、外毛细胞长度变化,进而产生力。根据声学输入的频率,基底膜和网状板可以同相或反相振荡。在后一种情况下,毛细胞产生的力会引导基底膜振荡,能量被泵入基底膜运动中,并且外部输入可以被强烈放大。该模型还能够产生自发振荡。与实验观察结果一致,该模型描述了电刺激使外毛细胞改变长度后基底膜的机械松弛。