The goal of our work is to define rules that relate external and middle-ear structure to function so that we can understand the functional significance of normal and pathologic variations in middle-ear anatomy. In this application we propose experiments designed to investigate how differences in the configuration of the tympanic membrane, ossicles and middle-ear air spaces affect middle-ear performance. The processes involved represent the most peripheral action of the middle ear. Two complimentary taxonomic groups, will be studied. (1) Four rodent species (chinchilla, gerbil, hamster, and rat) have been selected because of distinct differences in both their middle ears and their audiograms. The structural differences are in the size of the tympanic membrane and ossicles, the shape and rigidity of the malleus suspension, the relative volume of the middle-ear air-spaces, and the relative size of the accessory tympanic membrane. Physiological and anatomical measurements will quantitatively determine the effects of these structural differences. (2) The middle-ears of species in the cat family (Felidae) have great structural uniformity with large variations in size. The effects of the middle-ear air spaces in domestic cat are known to be sharply frequency dependent and are related to the two-cavity configuration of the spaces that is characteristic of cats. Using skulls from museum collections we will make structural measurements on (essentially) all 36 species of this family to determine quantitative rules that relate dimensions of the ear to skull size. For a subset of these (about 12 species) more detailed reconstructions of the middle ear will be made from CT scans of the skull, which will yield three dimensional descriptions from which acoustic models can be derived. Post-mortem physiological measurements of acoustic responses will be made on specimens of 6-10 species (as available from zoos and wildlife departments), which will also be reconstructed anatomically from CT scans and from histological sections. Quantitative models relating the structural features and physiologic performance will be developed for both taxonomic groups and these models will tested by the measurements.
Our aim i s to provide a unified theory in which both the diverse structural configurations of these rodents and the quantitatively variable structure in Felidae are included in rules that quantitatively describe the functional consequences of both kinds of variations. This systematic approach will lay a base for a quantitative description of the effects of pathological and interspecies differences in middle-ear structure on auditory function. Such a description will replace anecdotal descriptions with a comprehensive theory that can impact the clinical understanding of middle-ear pathology and reconstruction as well as ideas about evolution of the ear.

Agency
National Institute of Health (NIH)
Institute
National Institute on Deafness and Other Communication Disorders (NIDCD)
Type
Research Project (R01)
Project #
2R01DC000194-11A1
Application #
3216066
Study Section
Hearing Research Study Section (HAR)
Project Start
1983-01-01
Project End
1997-03-31
Budget Start
1993-04-01
Budget End
1994-03-31
Support Year
11
Fiscal Year
1993
Total Cost
Indirect Cost
Name
Massachusetts Institute of Technology
Department
Type
Organized Research Units
DUNS #
City
Cambridge
State
MA
Country
United States
Zip Code
02139
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
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
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; 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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