Effect of absence of cochlear outer hair cells on behavioural auditory threshold

doi:doi:10.1038/253044a0

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Nature 253, 44 - 46 (03 January 1975); doi:10.1038/253044a0

Effect of absence of cochlear outer hair cells on behavioural auditory threshold

ALLEN RYAN & PETER DALLOS

Auditory Physiology Laboratory (Audiology) and Department of Electrical Engineering, Northwestern University, Frances Searle Building, Evanston, Illinois 60201

THE function of the two populations of sensory cells in the mammalian inner ear is not well understood. Anatomical evidence indicates that the inner hair cells (IHCs) and the outer hair cells (OHCs) play separate roles in the transduction of acoustic stimuli¹. Furthermore, there have been numerous proposals attributing different roles to the two hair cell populations in the production of the various cochlear potentials²⁻⁵. On the other hand, theoretical considerations and the interpretation of data from several experiments have led to suggestions of different types of interaction between the OHCs and IHCs⁶⁻⁸.

References

1. Spoendlin, H., in Facts and Models in Hearing (edit. by Zwicker, E., and Terhardt, E.), 18–32, (Springer, New York, 1974).

2. Dallos, P., Billone, M., Durrant, J., Wang, C.-y., and Raynor, S., Science, 177, 356–358 (1972).

3. Davis, H., Deatherage, B. H., Rosenblut, B., Frenandez, C., Kimura, R., and Smith, C., Laryngoscope, 68, 596–627 (1958).

4. Kiang, N. Y.-s., Moxon, E. C., and Levine, R. A., in Sensorineural Hearing Loss (edit. by Wolstenholme, G. E. W., and Knight, J.), 241, (J. A. Churchill, England, 1970).

5. Dallos, P., and Wang, C.-y., Audiology, 13, 277–289 (1974).

6. Evans, E. F., in Facts and Models in Hearing (edit. by Zwicker, E., and Terhardt, E.), 118–129, (Springer, New York, 1974).

7. Lynn, P. A., and Sayers, B.McA., J. acoust. Soc. Am., 47, 525–532 (1970).

8. Zwislocki, J., and Sokolich, W. G., in Facts and Models in Hearing (edit. by Zwicker, E., and Terhardt, E.), 107–117, (Springer, New York, 1974).

9. Hawkins, J. E., and Engström, H., Acta oto-lar., suppl. 188 (1964).

10. Kohonen, A., Acta oto-lar., suppl. 208 (1965).

11. Miller, J., J. acoust. Soc. Am., 48, 513–523 (1970).

12. Engström, H., Ades, H., and Andersson, A., Structural Pattern of the Organ of Corti (Williams and Wilkins, Baltimore, 1966).

13. Bohne, B. A., (thesis, Univ. Washington, St. Louis 1971).

14. J., Wersäll, in Basic Mechanisms in Hearing (edit. by Moller, A.), 235 (Academic Press, New York, 1973).

15. Eldredge, D. H., Mills, J. H., and Bohne, B. A., Adv. oto-rhino-lar., 20, 64–81 (1973).

16. Elliot, D. N., and McGee, T. M., Anal. Otol., 74, 386–408 (1965).

17. Ward, W. D., and Duvall, A. J., Anal. Otol., 80, 881–896 (1971).

18. Hunter-Duvar, I. M., and Bredberg, G., J. acoust. Soc. Am., 55, 795–801 (1974).

19. Spoendlin, H., in Basic Mechanisms in Hearing (edit. by Moller, A.), 185 (Academic Press, New York, 1973).

20. Kiang, N.Y.-s., Watanabe, T., Thomas, F. C., and Clark, L. F., Discharge Patterns of Single Fibres in the Cat's Auditory Nerve (MIT Press, Cambridge, Mass., 1965).

21. Perkins, R., Anat. Rec., 175, 410 (1973).