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36 6 2014 12 1) 2) (, 710049) 1970. 2 973 2 1. 2006 2009 1. /. 70 SCI 40 EI 50 2.... 20 20 000 Hz 4 000.,,,, : O428 Q66 : A doi 10.

1 ) 2) (, ) /. 70 SCI 40 EI Hz ,,,, : O428 Q66 : A doi / PROGRESS IN MECHANICS OF THE COCHLEA 1) MA Fuyin WU Jiuhui 2) (School of Mechanical Engineering and State Key Laboratory for Strength and Vibration of Mechanical Structure, Xi an Jiaotong University, Xi an , China) Abstract The mechanics of cochlea is the core of hearing sciences and physiological acoustics, as well as a representative biomechanics topic. The study of cochlear mechanical properties could promote the related studies of psychoacoustics. This paper reviews the mechanics of the cochlea in two parts, the macro and micro mechanics, focusing on the development trend of the cochlear mechanics and application prospects. It is suggested that the cochlea is a part of the inner ear and its mechanical response provides us with many aspects of our amazing sensitive and selective hearing, with an accurate frequency response from Hz and with the stimulus signal being able to be amplified more than times. Key words cochlea basilar membrane, traveling wave theory, hearing active feedback, cochlear amplifier, cochlear mechanics ) ( ). 2) ejhwu@mail.xjtu.edu.cn

an Jiaotong University, Xi an 710049, China) Abstract The mechanics of cochlea is the core of hearing sciences and physiological acoustics, as well as a representative biomechanics topic.

2 Helmholtz [1] 1960 Békésy [2] [3] Journal of Acoustic Society of American Hearing Research. Nature, Science, Nature Neuroscience, Physic Review Letters, Annual Review Neuroscience Robles [4] Physiological Reviews Ashmore Physiological Reviews [5] Robles.. Helmholtz [6] Békésy [2] Helmholtz Békésy [7] [4] [8] [9]. [10-12] -- [13-14] [15-18]. 2 [19-20] [21-23] Dallos [24] Prestin 1948 Gold [25] Ren [26]. [5]. -- ( ) mm. 0.1 mm Hz 0.5 mm 20 Hz [27].

2008 Ashmore Physiological Reviews [5] 2008. Robles.. Helmholtz [6]. 1960 Békésy [2] Helmholtz Békésy 1961. [7] [4] [8] [9].

3 第 6 期马富银等耳蜗力学研究进展底膜和每部分对应的频率如图 1(b) 所示. 内容摘自中国数字科技馆听觉部分介绍 [27]. 图 1 耳蜗耳蜗剖面与基底膜频率对应关系示意图 [27] 对应耳蜗的听觉功能来说 Corti 器是其核心功能部件决定耳蜗频率分析功能的基底膜构成听觉感受器的外毛细胞构成听觉效应器的内毛细胞与外毛细胞纤毛发生接触后产生非线性电活动的盖膜等都位于 Corti 器内. Corti 器的结构如图 2 所示. 声音从外耳道传入后使鼓膜发生振动鼓膜振动会推动听骨链的运动听骨链的终端以镫骨底板与耳蜗相连镫骨底板的振动会推动前庭阶内淋巴液的运动由于在蜗顶处通过蜗孔使鼓阶和前庭阶的淋巴液流通前庭阶流入的淋巴液会通过蜗孔从鼓阶回流中间以柔性基底膜分隔基底膜两边淋巴液的反向剪切运动使基底膜发生振动. 687 就目前耳蜗力学的研究来看主要研究的内容包括体外基底膜底端力学行为和顶端力学行为 (需要说明的是基底膜的力学行为呈现非线性变化底端和顶端有较大差异) 耳蜗随长度变化的振动模式 (即频率分析规律) 耳蜗行波微观力学两个纯音作用下的耦合响应行为听觉滤波器压 -- 电转换力学行为与听觉主动反馈 (包括耳声发射) 耳蜗放大器等几部分. 里面也涉及了大量的神经生理活动相关内容增加了耳蜗力学的学科交叉性和力学行为的复杂性. 2 基底膜力学行为 2.1 基底膜底端力学行为目前报道的绝大多数关于正常内耳的力学行为都是人们在研究豚鼠栗鼠松鼠猴和猫等动物的耳蜗基底膜底端的运动时获得的. 关于基底膜底端的振动研究者们已经在大多数问题上基本达成共识包括如何判断信号记录质量精确获得特征频率等. 然而大量的研究表明耳蜗顶部的力学行为与底端的力学行为截然不同至少在定量描述上是完全不同的. 现阶段的耳蜗振动测试技术对基底膜可以精确测量对 Corti 器和盖膜则存在困难对纯音的响应图 3 为在栗鼠耳蜗中离卵圆窗 3.5 mm 处记录到的基底膜在纯音刺激下的速度与声压级关系 [28]. 对比图 3(a) 中小于等于特征频率的几组不同频率刺激下的线性响应曲线可以发现当刺激频率接近特征频率时表现出高度压缩的增长过程也就是说刺激强度增加到 96 db 时响应频率却只增加了图 2 Corti 器结构及构成 [27] 考虑到微观层次由于毛细胞的根部是在基底膜上的基底膜的振动会使毛细胞发生运动从而使毛细胞上成排分布的纤毛与盖膜发生接触产生压电行为. 目前研究者们已达成共识外毛细胞纤毛与盖膜发生接触内毛细胞纤毛不与盖膜发生接触. 由于外毛细胞纤维与盖膜发生接触后产生电信号与外毛细胞相连的传入神经感受到电刺激后会将刺激传到大脑皮层的中央听区产生听觉. 在这个过程中基底膜的运动可以看作是宏观力学行为纤毛和盖膜的接触属于微观力学行为并带有压 -- 电转换行为产生电刺激的过程属于电生理行为电刺激传导并产生听觉属于神经动力学行为. (a) 对小于等于特征频率 (10 khz) 的纯音刺激下的响应图 3 纯音作用下基底膜速度与声压级响应关系 (图中纵坐标 V 表示基底膜速度)

声音从外耳道传入后使鼓膜发生振动鼓膜振动会推动听骨链的运动听骨链的终端以镫骨底板与耳蜗相连镫骨底板的振动会推动前庭阶内淋巴液的运动由于在蜗顶处通过蜗孔使鼓阶和前庭阶的淋巴液流通前庭阶流入的淋巴液会通过蜗孔从鼓阶回流中间以柔性基底膜分隔基底膜两边淋巴液的反向剪切运动使基底膜发生振动.

4 (b) [4] / db. 3 ( V ) ( ) 28 db. 0.2 db/db.. Mössbauer db db [29-30]. [31-32] 100 db db 5 ( ) [4] 6 ( )... ( ). 1/ ( ) [4] 6 ( ) [4]

-- 80 db 90 100 db [29-30]. [31-32] 100 db 4.

5 6 689,. 7 ( ) db. 6 db/ 200 Hz [33-34] (1) (2) ( ) (3) ( Corti )... 8 [4] db 74 db. 7 [4] khz [35] 9 [4]

6 ,. 10 db 90 db 990 µs 610 µs.... [36]. 3.5% ( 29 db). [36]. ( ) Mössbauer [37] [38] khz 30 ms [38]... 1 ms [4] µm [38]...,. 11 [4]

10 10 khz 30 ms [38]... 1 ms... 10 [4] 11.

7 [39] Corti Hz [40] Claudius Hz ( ) db/db db 22 db [4] Corti Hz ( 12 ) dB/dB Hz [4]

8 db 35 nm. Corti 50% [41] ms ms ms Békésy... CF = A (10 αx k) (1) CF khz x 0 1 α ( mm) 2.1. k α k.. 75% x > 0.25 (1) 25%. A % 1.57 mm 3.55 mm. 0.6 mm 0.13 mm 1 mm. ( ).. (1). 3.5 mm 14 mm (2).

8 1 0.85. α k.. 75% x > 0.25 (1) 25%. A 0.456 0.164 0.35 0.36 0.4.. 17% 1.

9 6 693 [40]. (3) [4] ( ) ( ) [40]. (4)... (5) ( ) ( ) ( ) ( 8 ). 0 6 khz mm ( 41%)

10 Békésy [42] m/s. Wever Lawrence. Wever, Lawrence Békésy Békésy. Békésy 3 (1) Hz Békésy. 4. (2)... ( ).. 15 khz ( 15 ). 1 mm 35 db mm 10 m/s kHz [4] 100 m/s( ) mm 28 m/s 12.8 mm 1.55 m/s mm mm Hz 2.2 mm 10% [43] mm 30 µs

. 15 khz ( 15 ). 1 mm 35 db 1.5 0.67 mm 10 m/s.. 15 15kHz [4] 100 m/s( ).. 1.7 mm 28 m/s 12.

11 khz [38-39]. 3 ( 14 mm Hz) ms khz 1 ms 320 Hz 2.7 ms. 1 ms Békésy [42] Békésy. (1) Békésy.. 2. Békésy [44] Békésy [42] [42] 100 [45].. [45].. [45]. ( N/m) 1 3 mm [46]. 8 mm 2 5 N/m [46] 6 11 N/m. 94 db 1 Pa 10 nm. ( m 4 /N) ( m 4 /N).. Békésy.. Békésy [46].. [45]. 7 N/m 11 N/m

100 1 000 [42] 100 [45].. [45].. [45]. ( 0.2 1.1 N/m) 1 3 mm [46]. 8 mm 2 5 N/m [46] 6 11 N/m.

12 ( Corti ) 1 2 N/m. Corti ( ) Olson. Olson µm. 16(b) 16(d) [4] Békésy... Békésy

13 6 697 ( ). Békésy [42] ( 2 ). Békésy Zwislocki. Peterson Bogert [44]. Lighthill. Dancer [47-48]. Dancer [47-48] ( 1.5 ) ( 15 ). [49]. [49].... ( ) 0 ( ).. [39] Peterson [44] [44]. Peterson [12] Peterson Amitava [50]

.. ( 1.5 )... 16 ( 15 ). [49]. [49].... ( ) 0 ( ).. [39].

14 力 698 学与实践 2014 年第 36 卷并考虑了外毛细胞的作用. 该模型如图 18 所示. 这是目前为止提出的最为简单的耳蜗力学模型可以通过简单的几何关系和材料力学关于梁的理论分析其力学特性. 图 18 耳蜗一维梁模型 [50] [3] 建立了一种新的一维耳蜗模型通过该模型对耳蜗基底膜的双重放大机制进行了研究指出通过耳蜗内部结构与淋巴液的相互作用可以将声刺激信号放大倍以上年 Tobias 等图 20 二自由度耳蜗理论模型 [8] 1976 年 Allen[51] 建立了一个二维耳蜗流体力学模型如图 19 所示. 从图中可以看出该模型是矩形等截面模型存在较大的简化年 Stephen[52] 建立了一个二维耳蜗力学模型并通过有限差分法进行了理论求解年 Mammano 等 [53] 给出了一个耳蜗的二维模型考虑了纵截面形状的变化. 图 21 耳蜗三维矩形等截面模型 [54] 类似都是矩形等截面模型但是在这个模型中考虑了耳蜗螺旋特征带来的影响年 Paul[55] 建立了三维耳蜗锥形截面模图 19 矩形等截面二维耳蜗模型 2011 年 Lamb 等 [51] [8] 建立了耳蜗二自由度理论模型. 在该模型中综合考虑了盖膜基底膜和淋巴液的作用并进行了理论求解模型如图 20 所示. 耳蜗三维模型主要分为两类一类是简化模型和一维模型一样这类模型采用圆锥管来模拟耳蜗不考虑耳蜗的螺旋特性另一类是通过 3D 断层扫描技术等建立较为精确的三维耳蜗几何模型. 无论是简化模型还是精确模型得到三维几何模型后一般都借助有限元分析方法来进行分析和研究年 Larry 等 [54] 建立了三维流体的耳蜗力学模型如图 21 所示. 该模型与图 19 所示的二维模型型完整考虑了外毛细胞纤维盖膜基底膜等诸多因素的影响模拟了耳蜗对声音的放大作用. 从上述这些模型可以看出基本上都是用直管代替了螺旋管截面也是一般用矩形半圆形等截面总体上看都做了大量的简化. 此后有大量的研究者通过计算机 3D 断层扫描技术建立了耳蜗的精确模型特别是对内部核心的 Corti 器实现了精确建模和分析. 而且有研究表明螺旋管对耳蜗流场和基底膜振动的影响是非常大的但是目前还缺乏精确地考虑螺旋管道的影响的整体耳蜗模型精确的模型也主要集中在对局部特征的研究上. 5 耳蜗微观力学对应耳蜗的听觉功能来说 Corti 器是其核心功

从图中可以看出该模型是矩形等截面模型存在较大的简化. 1981 年 Stephen[52] 建立了一个二维耳蜗力学模型并通过有限差分法进行了理论求解. 1993 年 Mammano 等 [53] 给出了一个耳蜗的二维模型考虑了纵截面形状的变化. 图 21 耳蜗三维矩形等截面模型 [54] 类似都是矩形等截面模型但是在这个模型中考虑了耳蜗螺旋特征带来的影响.

15 6 699 Corti [27] Corti [56]. [56]. Corti.. (1). (2) [57]. (3) [58]. [57]... ( ) Corti.. 90 db ( 90 db)

16 Corti. Corti (Hensen s ) 4. Hensen s. [59]. Cooper Rhode Corti.. Claudius db [59] 70 mm/pa [60] db [60-61]. [60-61] mm s 1 Pa 1... [60-61].. [19-20].. Corti.,.,, Corti (18.8 khz).. ( 22 )

06 [59] 70 mm/pa [60]... 35 db [60-61]. [60-61]. 200 1 800 mm s 1 Pa 1.

17 6 701 [62]. 22 [4] Hz 12 khz ( ) Hz [63] [62].... [62]...

18 [62,64] Hz (f 1 f 2 f 2 > f 1 ) f 2 f 1 2f 1 f 2 2f 2 f 1. 2f 1 f [4] ( oct ) (f 1 f 2 ) 23 3f 2 2f 1 2f 2 f 1 2f 1 f 2 3f 1 2f 2 2f 1 2f 2 [13] f 2 f 1.. (1) (2f 1 f 2 ) 2f 1 f db( 15%) 16 db. 27 db 20 db db. 2f 1 f 2.. ( 60 db ).,.. f 2 /f 1 ( > 1.2) f 2 /f db.. f 2 /f 1 3(b) f 2 /f ( ).

.. 23 [4] ( oct ) (f 1 f 2 ) 23 3f 2 2f 1 2f 2 f 1 2f 1 f 2 3f 1 2f 2 2f 1 2f 2 [13] f 2 f 1.

19 f 1 f 2.. (2) (f 2 f 1 ) f 2 f 1. ( ) 2f 1 f db [58]. [58]. Corti. f 2 f 1 = CF f 1 f 2 f 2 f 1 CF Békésy Hz 1 pm(10 12 m) khz µm/s nm( ) khz ( 10 db ) µm/s 1 2 nm. 164 µm/s 2.7 nm 15 µm/s 0.26 nm khz 1 nm( 200 µm/s). [65]. -- ( ) [65]. 3 4 mm ( khz ) db [65] 30 db. (20 30 db) (10 20 db ) 24.. ( Hz) ( db ) 1 3 nm 2 7µm/s [58]. ( 350 Hz) 60 db 38 nm Hz

9 10 khz ( 10 db ) 50 100 µm/s 1 2 nm. 164 µm/s 2.7 nm 15 µm/s 0.26 nm. 30 33 khz 1 nm( 200 µm/s). [65]. -- ( ) [65].

20 [4] 28 db nm. ( ).. 25 db µm/s ( ). [66]. ( ). Rhode [19-20] Rhode [66]. [66]..., µm/s 1 nm. 3.5 mm khz (0.9 nm) (50 µm/s). ( 24 ). 3 5 db. ( ) khz... ( 24 ) Hz.

[66]...,. 6.2.3. 40µm/s 1 nm. 3.5 mm. 9 10 khz (0.

21 ( ) ( ). ( -- ) Lamb [8] Corti. Davis 1983 Gold [25] [23]. (, )...., Corti Rhode. Rhode db. Corti

22 [16]. ( ) [67] [4] ( ).... ( ) [68].. ( 60 db). 0 50% 6 db ( ) db. ( ) mol/l( ). 45 db 10 db

23 6 707 ( ).... ( ) [57]. (27kHz) (270 ) [57]. Rhode khz 80 18kHz ( ).. f 1 f 2 2f 1 f 2. 2f 1 f 2. 2f 1 f 2 2f 1 f 2.. [62,64] ( ).. --

24 db db 90 db 10 db / ( ) ( ) Corti. Corti 15 khz. Corti [69] ( 2 )..,,. Moxon Nuttall [69] Corti. ( ). ( ). Corti [68]. ( )

25 [69] ( ). [68].. ( ) /. Corti Jiang Grosh , Szalai [18]. 26 [16,18] Corti ( ).

26 ( ) db (36 db) db 0 21 db. ( ) ( ) khz 78 db 9 10 khz 81 db. ( 1/2 ) ( ) khz db khz 35 db [58] mm ( ) % 0.5 mm 1.3 mm mm. Alexander., Saaid khz 1.5

27 /3. ( 2.5 mm/ ) 1.3 mm 0.8 mm 2.1 mm mm mm. 15 khz 2 mm 5.5 khz 3.5 mm 9 10 khz. 15. ( ). 8.4 Corti ( ). Brownell... Prestin [17]. ( [5] ). ( ) 30 nm/mv. 79 khz. ( ). 1.2 khz 6 db. 15 mv 16 khz 15 db. 1 nm Chen [70].... ATP (adenosine triphosphate) Andrei [13]. Szalai [18]. /. --. ( ) [71]. 50 nm [72-73] Dylan Hudspeth.. ( ).

28 ( ).,.. /Corti /. ( 6 11 N/m) ( N/m ) ( ).. ( ) --. (= 1/CF )... ( ) ( ).. ( db/db). (120 db) (30 40 db). Corti. Corti.

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JOURNAL OF EARTHQUAKE ENGINEERING AND ENGINEERING VIBRATION Vol. 31 No. 5 Oct /35 TU3521 P315.

31 5 2011 10 JOURNAL OF EARTHQUAKE ENGINEERING AND ENGINEERING VIBRATION Vol. 31 No. 5 Oct. 2011 1000-1301 2011 05-0075 - 09 510405 1 /35 TU3521 P315. 8 A Earthquake simulation shaking table test and analysis