Sound-induced motions of individual cochlear hair bundles

Biophysical Journal

Volumn 87, Issue 5, 2004, Pages 3536-3546

  Aranyosi, Alexander J ^a,c   Freeman, Dennis M ^a,b,c,d  

^a MASSACHUSETTS INSTITUTE OF TECHNOLOGY   (United States)

^b USA   (United States)

^c HARVARD MIT DIVISION OF HEALTH SCIENCES AND TECHNOLOGY   (United States)

^d MASSACHUSETTS EYE AND EAR INFIRMARY   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

AMPLIFIER; ANIMAL TISSUE; ARTICLE; AUDITORY STIMULATION; CELL MOTION; COCHLEA; CONTROLLED STUDY; HAIR CELL; NONHUMAN; RECEPTOR POTENTIAL; SOUND; SOUND INTENSITY; ANIMAL; CELL CULTURE; COMPUTER ASSISTED DIAGNOSIS; CYTOLOGY; LIZARD; MECHANOTRANSDUCTION; METHODOLOGY; MOVEMENT (PHYSIOLOGY); PHYSIOLOGY; SOUND DETECTION;

ACOUSTIC STIMULATION; ANIMALS; CELLS, CULTURED; COCHLEA; HAIR CELLS, INNER; IMAGE INTERPRETATION, COMPUTER-ASSISTED; LIZARDS; MECHANOTRANSDUCTION, CELLULAR; MOVEMENT; SOUND SPECTROGRAPHY;

EID: 16344381942     PISSN: 00063495     EISSN: None     Source Type: Journal    
DOI: 10.1529/biophysj.104.044404     Document Type: Article

References (51)

1. Authier, S., and G. A. Manley. 1995. A model of frequency tuning in the basilar papilla of the tokay gecko, gekko gecko. Hear. Res. 82:1-13.
2. Benser, M., R. Marquis, and A. Hudspeth. 1996. Rapid, active hair bundle movements in hair cells from the bullfrog's sacculus. J. Neurosci. 16:5629-5643.
3. Billone, M., and S. Raynor. 1973. Transmission of radial shear forces to cochlear hair cells. J. Acoust. Soc. Am. 54:1143-1156.
4. Brownell, W. E., C. R. Bader, D. Bertrand, and Y. de Ribaupierre. 1985. Evoked mechanical responses of isolated cochlear hair cells. Science. 227:194-196.
5. Camalet, S., T. Duke, F. Jülicher, and J. Prost. 2000. Auditory sensitivity provided by self-tuned critical oscillations of hair cells. Proc. Natl. Acad. Sci. USA. 97:3183-3188.
6. Cheatham, M., and P. Dallos. 1998. The level dependence of response phase: observations from cochlear hair cells. J. Acoust. Soc. Am. 104:356-369.
7. Cheatham, M., and P. Dallos. 1999. Response phase: a view from the inner hair cell. J. Acoust. Soc. Am. 105:799-810.
8. Cooper, N. P. 1998. Harmonic distortion on the basilar membrane in the basal turn of the guinea-pig cochlea. J. Physiol. 509:277-288.
9. Copeland, A. D. 2003. Robust motion estimation in the presence of fixed pattern noise. Master's thesis, Massachusetts Institute of Technology, Cambridge, MA.
10. Crawford, A. C., and R. Fettiplace. 1985. The mechanical properties of ciliary bundles of turtle cochlear hair cells. J. Physiol. 364:359-379.
11. Dallos, P. 1985. Response characteristics of mammalian cochlear hair cells. J. Neurosci. 5:1591-1608.
12. Dallos, P., M. C. Billone, J. D. Durrant, C. Wang, and S. Raynor. 1972. Cochlear inner and outer hair cells: functional differences. Science. 177:356-358.
13. Dallos, P., and M. A. Cheatham. 1989. Nonlinearities in cochlear receptor potentials and their origins. J. Acoust. Soc. Am. 86:1790-1796.
14. Davis, C. Q. 1997. Measuring nanometer, three-dimensional motions with light microscopy. PhD thesis, Massachusetts Institute of Technology, Cambridge, MA.
15. Davis, C. Q., and D. M. Freeman. 1995. Direct observations of sound-induced motions of the reticular lamina, tectorial membrane, hair bundles, and individual stereocilia. In Abstracts of the Eighteenth Midwinter Research Meeting, Association for Research in Otolaryngology, St. Petersburg, FL.
16. Davis, C. Q., and D. M. Freeman. 1998a. Statistics of subpixel registration algorithms based on spatio-temporal gradients or block matching. Opt. Eng. 37:1290-1298.
17. Davis, C. Q., and D. M. Freeman. 1998b. Using a light microscope to measure motions with nanometer accuracy. Opt. Eng. 37:1299-1304.
18. Freeman, D. M. 1990. Anatomical model of the cochlea of the alligator lizard. Hear. Res. 49:29-38.
19. Freeman, D. M., and T. F. Weiss. 1990a. Hydrodynamic analysis of a two-dimensional model for micromechamcal resonance of freestanding hair bundles. Hear. Res. 48:37-68.
20. Freeman, D. M., and T. F. Weiss. 1990b. Hydrodynamic forces on hair bundles at high frequencies. Hear. Res. 48:31-36.
21. Freeman, D. M., and T. F. Weiss. 1990c. Hydrodynamic forces on hair bundles at low frequencies. Hear. Res. 48:17-30.
22. Frishkopf, L. S., and D. J. DeRosier. 1983. Mechanical tuning of freestanding stereociliary bundles and frequency analysis in the alligator lizard cochlea. Hear. Res. 12:393-404.
23. Holton, T., and A. J. Hudspeth. 1983. A micromechanical contribution to cochlear tuning and tonotopic organization. Science. 222:508-510.
24. Holton, T., and T. F. Weiss. 1983a. Frequency selectivity of hair cells and nerve fibers in the alligator lizard cochlea. J. Physiol. 345:241-260.
25. Holton, T., and T. F. Weiss. 1983b. Receptor potentials of lizard cochlear hair cells with freestanding stereocilia in response to tones. J. Physiol. 345:205-240.
26. Horn, B. K. P. 1986. Robot Vision. MIT Press, Cambridge, MA.
27. Horn, B. K. P., and E. J. Weldon, Jr. 1988. Direct methods for recovering motion. Int. J. of Comput. Vision. 2:51-76.
28. Hudspeth, A. J., and D. P. Corey. 1977. Sensitivity, polarity, and conductance change in the response of vertebrate hair cells to controlled mechanical stimuli. Proc. Natl. Acad. Sci. USA. 74:2407-2411.
29. Inoue, S. 1986. Video Microscopy. Plenum Press, New York.
30. Langer, M., S. Fink, A. Koitschev, U. Rexhausen, J. Hörber, and J. Ruppersberg. 2001. Lateral mechanical coupling of stereocilia in cochlear hair bundles. Biophys. J. 80:2608-2621.
31. Liberman, M., J. Gao, D. He, X. Wu, S. Jia, and J. Zuo. 2002. Prestin is required for electromotility of the outer hair cell and for the cochlear amplifier. Nature. 419:300-304.
32. Manley, G. A. 2000. Cochlear mechanisms from a phylogenetic viewpoint. Proc. Natl. Acad. Sci. USA. 97:11736-11743.
33. Manley, G. A., D. L. Kirk, C. Koppl, and G. K. Yates. 2001. In vivo evidence for a cochlear amplifier in the hair-cell bundle of lizards. Proc. Natl. Acad. Sci. USA. 98:2826-2831.
34. Martin, P., A. J. Hudspeth, and F. Jülicher. 2001. Comparison of a hair bundle's spontaneous oscillations with its response to mechanical stimulation reveals the underlying active process. Proc. Natl. Acad. Sci. USA. 98:14380-14385.
35. Martin, P., A. D. Mehta, and A. J. Hudspeth. 2000. Negative hair-bundle stiffness betrays a mechanism for mechanical amplification by the hair cell. Proc. Natl. Acad. Sci. USA. 97:12026-12031.
36. Mulroy, M. J. 1974. Cochlear anatomy of the alligator lizard. Brain Behav. Evol. 10:69-87.
37. Peake, W. T., and A. L. Ling, Jr. 1980. Basilar-membrane motion in the alligator lizard: its relation to tonotopic organization and frequency selectivity. J. Acoust. Soc. Am. 67:1736-1745.
38. Robles, L., and M. A. Ruggero. 2001. Mechanics of the mammalian cochlea. Physiol. Rev. 81:1305-1352.
39. Rosowski, J. J., W. T. Peake, T. J. Lynch, R. Leong, and T. F. Weiss. 1985. A model for signal transmission in an ear having hair cells with freestanding stereocilia: II. Macromechanical stage. Hear. Res. 20:139-155.
40. Ruggero, M. A., N. C. Rich, A. Recio, S. S. Narayan, and L. Robles. 1997. Basilar-membrane responses to tones at the base of the chinchilla cochlea. J. Acoust. Soc. Am. 101:2151-2163.
41. Russell, I. J., G. P. Richardson, and M. Kössl. 1986. Mechanosensitivity of mammalian auditory hair cells in vitro. Nature. 321:517-519.
42. Russell, I. J., and P. M. Sellick. 1983. Low-frequency characteristics of intracellularly recorded receptor potentials in guinea-pig cochlear hair cells. J. Physiol. 338:179-206.
43. Sellick, P. M., and I. J. Russell. 1980. The responses of inner hair cells to basilar membrane velocity during low frequency auditory stimulation in the guinea pig cochlea. Hear. Res. 2:439-445.
44. Shatz, L. F. 2000. The effect of hair bundle shape on hair bundle hydrodynamics of inner ear hair cells at low and high frequencies. Hear. Res. 141:39-50.
45. Shera, C. 2001. Intensity-invariance of fine time structure in basilar-membrane click responses: implications for cochlear mechanics. J. Acoust. Soc. Am. 110:332-348.
46. Timoner, S. J., and D. M. Freeman. 2001. Multi-image gradient-based algorithms for motion estimation. Opt. Eng. 40:2003-2016.
47. Weiss, T. F. 1982. Bidirectional transduction in vertebrate hair cells: A mechanism for coupling mechanical and electrical processes. Hear. Res. 7:353-360.
48. Weiss, T. F., and R. Leong. 1985. A model for signal transmission in an ear having cells with freestanding stereocilia. III. Micromechanical stage. Hear. Res. 20:157-174.
49. Weiss, T. F., M. J. Mulroy, R. G. Turner, and C. L. Pike. 1976. Tuning of single fibers in the cochlear nerve of the alligator lizard: relation to receptor morphology. Brain Res. 115:71-90.
50. Weiss, T. F., W. T. Peake, A. Ling, and T. Holton. 1978. Which structures determine frequency selectivity and tonotopic organization of vertebrate cochlear nerve fibers? Evidence from the alligator lizard. In Evoked Electrical Activity in the Auditory Nervous System. R. Naunton and C. Fernandez, editors. Academic Press, New York. 91-112.
51. Zheng, J., W. Shen, D. He, K. Long, L. Madison, and P. Dallos. 2000. Prestin is the motor protein of cochlear outer hair cells. Nature. 405:149-155.