The middle ear plays a vital role in the sense and sensitivity of hearing, yet there is currently a lack of knowledge about the mechanisms of high-frequency middle-ear sound transmission in mammals. The overall goal of this project is to understand the relationships between the morphometry of the middle ear and the biomechanical processes that lead to physiological and clinical responses. The approach is to deconstruct the middle ear into subsystems that are each characterized by morphological and physiological measurements, as well as three-dimensional linear and nonlinear mathematical analyses. The subsystems are then mathematically reassembled to form a complete `virtual middle-ear'model that can be used to examine issues relevant to high frequency sound transmission in a variety of animals and repaired middle ears before and after surgery.
Specific Aim #1 : At high frequencies, experimental evidence suggests that sound conduction is not limited by the inertia of the middle-ear bones, contrary to expectations. Recent moment of inertia calculations suggest that the malleus switches from a hinging motion at low frequencies to a new twisting motion at high frequencies, in order to take advantage of the reduced inertia associated with a twisting type of motion. It is hypothesized that the mobile saddle-shaped malleus-incus joint is able to suitably transfer this twisting motion to the incus. This will be tested using micro-CT imaging, cryogenic transmission electron microscopy, optical second harmonic generation, hinging and twisting motion measurements with a laser Doppler vibrometer, and bio-computational modeling.
Specific Aim #2 : The human middle-ear cavity is known to be an irregularly shaped space within the temporal bone that varies from person to person. A finite element modeling approach will be used to test the hypothesis that the complex shape of the human middle-ear cavity functions to break up resonant modes that would otherwise decrease hearing sensitivity at specific resonant frequencies. The finite element approach, which is well-suited for the nonlinear descriptions needed to incorporate the forces exerted by the tensor tympani and the stapedius muscles, will also be used to understand how these muscles affect sound transmission through the middle ear.
Specific Aim #3 : Ear surgeons target restoration of hearing in the speech frequency range, and not in the higher frequencies where important sound localization cues are known to reside. Temporal bone measurements and the anatomically- and physics-based virtual middle-ear model will be used to understand how to improve high-frequency outcomes of middle-ear surgical treatments, such as tympanic membrane repair (myringoplasty) and ossicle replacement with a prosthesis (tympanoplasty).
Specific Aim #4 : Our hypothesis that myringoplasty and tympanoplasty surgery patients continue to have air-bone gap deficits at frequencies above 4 kHz will be tested. New methods to measure bone conduction sensitivity will be developed for high frequencies and combined with existing air conduction measurement methods. While it is well accepted that amongst terrestrial vertebrates, the mammalian middle ear is unique in its ability to transmit sounds from the external world to the cochlea for frequencies above 10 kHz, the biomechanical basis for sound transmission at high frequencies is poorly understood, which has consequences in the clinical realm. It is well known that the morphometry of the middle ear plays a key role in sound transmission, but the lack of knowledge about the relationships between middle-ear structures and sound transmission has resulted in unsatisfactory and variable outcomes of middle-ear repairs, particularly at high frequencies where sound localization cues may be important for hearing in noisy situations. The proposed studies will provide a solid scientific foundation for understanding the structural basis of middle-ear sound transmission, leading to clinical applications for the surgical reconstruction of the middle ear, the interpretation of otoacoustic emissions, and improvements to the understanding of passive and active prostheses used by surgeons to repair the middle ear.

Public Health Relevance

While it is well accepted that amongst terrestrial vertebrates, the mammalian middle ear is unique in its ability to transmit sounds from the external world to the cochlea for frequencies above 10 kHz, the biomechanical basis for sound transmission at high frequencies is poorly understood, which has consequences in the clinical realm. It is well known that the morphometry of the middle ear plays a key role in sound transmission, but the lack of knowledge about the relationships between middle-ear structures and sound transmission has resulted in unsatisfactory and variable outcomes of middle-ear repairs, particularly at high frequencies where sound localization cues may be important for hearing in noisy situations. The proposed studies will provide a solid scientific foundation for understanding the structural basis of middle-ear sound transmission, leading to clinical applications for the surgical reconstruction of the middle ear, the interpretation of otoacoustic emissions, and improvements to the understanding of passive and active prostheses used by surgeons to repair the middle ear.

Agency
National Institute of Health (NIH)
Institute
National Institute on Deafness and Other Communication Disorders (NIDCD)
Type
Research Project (R01)
Project #
5R01DC005960-05
Application #
7771706
Study Section
Auditory System Study Section (AUD)
Program Officer
Watson, Bracie
Project Start
2009-02-17
Project End
2014-01-31
Budget Start
2010-02-01
Budget End
2011-01-31
Support Year
5
Fiscal Year
2010
Total Cost
$334,385
Indirect Cost
Name
Stanford University
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
009214214
City
Stanford
State
CA
Country
United States
Zip Code
94305
Gottlieb, Peter K; Vaisbuch, Yona; Puria, Sunil (2018) Human ossicular-joint flexibility transforms the peak amplitude and width of impulsive acoustic stimuli. J Acoust Soc Am 143:3418
Khaleghi, Morteza; Puria, Sunil (2017) Attenuating the ear canal feedback pressure of a laser-driven hearing aid. J Acoust Soc Am 141:1683
O'Connor, Kevin N; Cai, Hongxue; Puria, Sunil (2017) The effects of varying tympanic-membrane material properties on human middle-ear sound transmission in a three-dimensional finite-element model. J Acoust Soc Am 142:2836
Santa Maria, Peter Luke; Gottlieb, Peter; Santa Maria, Chloe et al. (2017) Functional Outcomes of Heparin-Binding Epidermal Growth Factor-Like Growth Factor for Regeneration of Chronic Tympanic Membrane Perforations in Mice. Tissue Eng Part A 23:436-444
Gottlieb, Peter K; Li, Xiping; Monfared, Ashkan et al. (2016) First results of a novel adjustable-length ossicular reconstruction prosthesis in temporal bones. Laryngoscope 126:2559-2564
Aldaz, Gabriel; Puria, Sunil; Leifer, Larry J (2016) Smartphone-Based System for Learning and Inferring Hearing Aid Settings. J Am Acad Audiol 27:732-749
Shin, Dong Ho; Seong, Ki Woong; Puria, Sunil et al. (2016) A tri-coil bellows-type round window transducer with improved frequency characteristics for middle-ear implants. Hear Res 341:144-154
Woo, Seong Tak; Shin, Dong Ho; Lim, Hyung-Gyu et al. (2015) A New Trans-Tympanic Microphone Approach for Fully Implantable Hearing Devices. Sensors (Basel) 15:22798-810
Kim, Namkeun; Steele, Charles R; Puria, Sunil (2014) The importance of the hook region of the cochlea for bone-conduction hearing. Biophys J 107:233-41
Kim, Namkeun; Steele, Charles R; Puria, Sunil (2013) Superior-semicircular-canal dehiscence: effects of location, shape, and size on sound conduction. Hear Res 301:72-84

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