Conductive hearing losses result from a wide range of pathological conditions, but all degrade people's ability to communicate. Modern surgical practice includes dramatic procedures for treatment of conductive hearing problems, including reconstruction of abnormal or diseased external and middle ears, but the effects of some treatments on the patients hearing are often variable and hard to predict. Choices among medical and surgical treatments are guided by diagnostic tests, by physicians' experience and by theories of how pathologies affect the normal processes of the external and middle ear. However, many current theories are based on anecdotal evidence, incompletely tested ideas, or poorly controlled observations. The ears of animals provide an opportunity to determine unmistakably the effects of structural variations on the ear's function, and to develop and test theories of the ear's operation. These structures of the external and middle ear that control the collection and delivery of sound signals from the environment to the inner ear, and thence to the brain, vary in their configuration among species as well as during development from newborn to adult, and controlled experimental manipulation is possible in physiological experiments on anesthetized animals. We use all these approaches to determine the effects on hearing of variations of external- and middle-ear structures. Specifically, measurements of middle and external-ear structure and function will be made in anesthetized rodents with different middle-ear structures and in developing cats. The proposed functional and structural measurements will lead to a quantitative theory of how the external and middle ear function together. One result will be a quantitative understanding of how hearing is affected by the wide variations in the air volume of the normal and pathological human middle-ear cavities. One benefit of this knowledge will be that acoustic effects of fluid in the middle ear (an abnormal condition which occurs frequently in children) will be explained and thereby both inform physicians' judgments on causes of children's hearing loss and make possible prediction of the effects of treatments. Our expected results may also explain deficits in people's ability to identify the direction from which sound arrives, as a result of abnormal ear structures. A listener's ability to """"""""localize"""""""" talkers, in perceptual space, is crucial to communication in environments where more than one person speaks simultaneously, such as dinner tables and bus stations.

Agency
National Institute of Health (NIH)
Institute
National Institute on Deafness and Other Communication Disorders (NIDCD)
Type
Research Project (R01)
Project #
5R01DC000194-16
Application #
2837930
Study Section
Special Emphasis Panel (ZRG1-HAR (02))
Project Start
1983-01-01
Project End
2002-11-30
Budget Start
1998-12-01
Budget End
1999-11-30
Support Year
16
Fiscal Year
1999
Total Cost
Indirect Cost
Name
Massachusetts Eye and Ear Infirmary
Department
Type
DUNS #
073825945
City
Boston
State
MA
Country
United States
Zip Code
02114
Rosowski, John J; Bowers, Peter; Nakajima, Hideko H (2018) Limits on normal cochlear 'third' windows provided by previous investigations of additional sound paths into and out of the cat inner ear. Hear Res 360:3-13
Ravicz, Michael E; Rosowski, John J (2017) Chinchilla middle ear transmission matrix model and middle-ear flexibility. J Acoust Soc Am 141:3274
Chhan, David; McKinnon, Melissa L; Rosowski, John J (2017) Identification of induced and naturally occurring conductive hearing loss in mice using bone conduction. Hear Res 346:45-54
Chhan, David; Bowers, Peter; McKinnon, Melissa L et al. (2016) Middle-ear and inner-ear contribution to bone conduction in chinchilla: The development of Carhart's notch. Hear Res 340:144-152
Ravicz, Michael E; Rosowski, John J (2013) Inner-ear sound pressures near the base of the cochlea in chinchilla: further investigation. J Acoust Soc Am 133:2208-23
Chhan, David; Röösli, Christof; McKinnon, Melissa L et al. (2013) Evidence of inner ear contribution in bone conduction in chinchilla. Hear Res 301:66-71
Ravicz, Michael E; Rosowski, John J (2013) Middle-ear velocity transfer function, cochlear input immittance, and middle-ear efficiency in chinchilla. J Acoust Soc Am 134:2852-65
Röösli, Christof; Chhan, David; Halpin, Christopher et al. (2012) Comparison of umbo velocity in air- and bone-conduction. Hear Res 290:83-90
Puria, Sunil; Rosowski, John J (2012) Bekesy's contributions to our present understanding of sound conduction to the inner ear. Hear Res 293:21-30
Ravicz, Michael E; Rosowski, John J (2012) Chinchilla middle-ear admittance and sound power: high-frequency estimates and effects of inner-ear modifications. J Acoust Soc Am 132:2437-54

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