Your search keyword '"Ketten, Darlene R."' showing total 7 results

1. A model and experimental approach to the middle ear transfer function related to hearing in the humpback whale (Megaptera novaeangliae).

Author

Tubelli, Andrew A., Zosuls, Aleksandrs, Ketten, Darlene R., and Mountain, David C.

Subjects

BALEEN whales, AUDIOGRAM, COCHLEA, HUMPBACK whale, MIDDLE ear, FINITE element method

Abstract

At present, there are no direct measures of hearing for any baleen whale (Mysticeti). The most viable alternative to in vivo approaches to simulate the audiogram is through modeling outer, middle, and inner ear functions based on the anatomy and material properties of each component. This paper describes a finite element model of the middle ear for the humpback whale (Megaptera novaeangliae) to calculate the middle ear transfer function (METF) to determine acoustic energy transmission to the cochlea. The model was developed based on high resolution computed tomography imaging and direct anatomical measurements of the middle ear components for this mysticete species. Mechanical properties for the middle ear tissues were determined from experimental measurements and published values. The METF for the humpback whale predicted a better frequency range between approximately 15 Hz and 3 kHz or between 200 Hz and 9 kHz based on two potential stimulation locations. Experimental measures of the ossicular chain, tympanic membrane, and tympanic bone velocities showed frequency response characteristics consistent with the model. The predicted best sensitivity hearing ranges match well with known vocalizations of this species. [ABSTRACT FROM AUTHOR]

Published

2018

2. Biomechanical Analysis of Hearing in Whales Using Nanoindentation and the Finite Element Method.

Author

Tubelli, Andrew A., Zosuls, Aleks, Ketten, Darlene R., and Mountain, David C.

Subjects

BIOMECHANICS, HEARING, BALEEN whales, FINITE element method, MIDDLE ear, ANIMAL sound production

Abstract

The detailed biomechanics of hearing in baleen whales are almost entirely unknown. As a first step to predicting the audiogram for these species, a linear three-dimensional finite-element model of the minke whale (Balaenoptera acutorostrata) middle ear was developed. A reconstruction of the ear was made from CT scans and imported into a finite element solver. Young's modulus of the bone was estimated via nanoindentation. The middle-ear transfer function was estimated by applying a pressure to the glove finger (the thick, everted equivalent of the tympanic membrane) with velocity calculated at the stapes footplate. It was found that the most sensitive frequencies corresponded with vocalization frequencies. For all frequencies tested, the malleus-incus complex flexed about the anterior process of the malleus and the stapes rotated within the oval window. Results indictae that finite element modeling is a useful approach for studying the mechanics of hearing in species that are difficult to study in vivo. [ABSTRACT FROM AUTHOR]

Published

2011

3. Middle Ear Cavity Morphology Is Consistent with an Aquatic Origin for Testudines.

Author

Willis, Katie L., Christensen-Dalsgaard, Jakob, Ketten, Darlene R., and Carr, Catherine E.

Subjects

TURTLES, PHYLOGENY, MIDDLE ear, ANIMAL morphology, MAGNETIC resonance, TOMOGRAPHY

Abstract

The position of testudines in vertebrate phylogeny is being re-evaluated. At present, testudine morphological and molecular data conflict when reconstructing phylogenetic relationships. Complicating matters, the ecological niche of stem testudines is ambiguous. To understand how turtles have evolved to hear in different environments, we examined middle ear morphology and scaling in most extant families, as well as some extinct species, using 3-dimensional reconstructions from micro magnetic resonance (MR) and submillimeter computed tomography (CT) scans. All families of testudines exhibited a similar shape of the bony structure of the middle ear cavity, with the tympanic disk located on the rostrolateral edge of the cavity. Sea Turtles have additional soft tissue that fills the middle ear cavity to varying degrees. When the middle ear cavity is modeled as an air-filled sphere of the same volume resonating in an underwater sound field, the calculated resonances for the volumes of the middle ear cavities largely fell within testudine hearing ranges. Although there were some differences in morphology, there were no statistically significant differences in the scaling of the volume of the bony middle ear cavity with head size among groups when categorized by phylogeny and ecology. Because the cavity is predicted to resonate underwater within the testudine hearing range, the data support the hypothesis of an aquatic origin for testudines, and function of the middle ear cavity in underwater sound detection. [ABSTRACT FROM AUTHOR]

Published

2013

4. A prediction of the minke whale (Balaenoptera acutorostrata) middle-ear transfer function.

Author

Tubelli, Andrew A., Zosuls, Aleks, Ketten, Darlene R., Yamato, Maya, and Mountain, David C.

Subjects

MINKE whale, TRANSFER functions, MIDDLE ear, NOISE measurement, EAR ossicles

Abstract

The lack of baleen whale (Cetacea Mysticeti) audiograms impedes the assessment of the impacts of anthropogenic noise on these animals. Estimates of audiograms, which are difficult to obtain behaviorally or electrophysiologically for baleen whales, can be made by simulating the audiogram as a series of components representing the outer, middle, and inner ear (Rosowski, 1991; Ruggero and Temchin, 2002). The middle-ear portion of the system can be represented by the middle-ear transfer function (METF), a measure of the transmission of acoustic energy from the external ear to the cochlea. An anatomically accurate finite element model of the minke whale (Balaenoptera acutorostrata) middle ear was developed to predict the METF for a mysticete species. The elastic moduli of the auditory ossicles were measured by using nanoindentation. Other mechanical properties were estimated from experimental stiffness measurements or from published values. The METF predicted a best frequency range between approximately 30 Hz and 7.5 kHz or between 100 Hz and 25 kHz depending on stimulation location. Parametric analysis found that the most sensitive parameters are the elastic moduli of the glove finger and joints and the Rayleigh damping stiffness coefficient β. The predicted hearing range matches well with the vocalization range. [ABSTRACT FROM AUTHOR]

Published

2012

5. Middle-Ear Stiffness of the Bottlenose Dolphin Tursiops truncatus.

Author

Miller, Brian S., Zosuls, Aleks L., Ketten, Darlene R., and Mountain, David C.

Subjects

MIDDLE ear, CETACEA, HEARING, BOTTLENOSE dolphin, ANIMAL behavior

Abstract

Previous research on the cetacean auditory system has consisted mostly of behavioral studies on a limited number of species. Little quantitative physiologic data exists on cetacean hearing. The frequency range of hearing varies greatly across different mammalian species. Differences among species correlate with differences in the middle-ear transfer function. Middle-ear transfer functions depend on the mechanical stiffness of the middle ear and the cochlear input impedance. The purpose of this study was to measure the middle-ear stiffness for the bottlenose dolphin (Tursiops truncatus), a species specialized for underwater high-frequency hearing and echolocation. Middle-ear stiffness was measured with a force probe that applied a known displacement to the stapes and measured the restoring force. The average middle-ear stiffness in ten dolphin ears was 1.37 N/µm, which is considerably higher than that reported for most terrestrial mammals. The relationship between middle-ear stiffness and low-frequency hearing cutoff in Tursiops was shown to be comparable to that of terrestrial mammals. [ABSTRACT FROM AUTHOR]

Published

2006

6. Optical and tomographic imaging of a middle ear malformation in the bullfrog (Rana catesbeiana).

Author

Horowitz, Seth S., Simmons, Andrea Megela, and Ketten, Darlene R.

Subjects

MIDDLE ear, HEARING disorders, TOMOGRAPHY, BULLFROG, MORPHOLOGY, DIAGNOSTIC imaging

Abstract

Using a combination of in vivo computerized tomography and histological staining, a middle ear anomaly in two wild-caught American bullfrogs (Rana catesbeiana) is characterized. In these animals, the tympanic membrane, extrastapes, and pars media (shaft) of the stapes are absent on one side of the head, with the other side exhibiting normal morphology. The pars interna (footplate) of the stapes and the operculum are present in their normal positions at the entrance of the otic capsule on both the affected and unaffected sides. The pattern of deformity suggests a partial failure of development of tympanic pathway tissues, but with a preservation of the opercularis pathway. While a definitive proximate cause of the condition could not be determined, the anomalies show similarities to developmental defects in mammalian middle ear formation. [ABSTRACT FROM AUTHOR]

Published

2005

7. The History of Auditory Research in Lizards

Author

Manley, Geoffrey A., Coffin, Allison B., Series Editor, Popper, Arthur N., Founding Editor, Avraham, Karen, Editorial Board Member, Sisneros, Joseph, Series Editor, Fay, Richard R., Founding Editor, Bass, Andrew, Editorial Board Member, Cunningham, Lisa, Editorial Board Member, Fritzsch, Bernd, Editorial Board Member, Groves, Andrew, Editorial Board Member, Hertzano, Ronna, Editorial Board Member, Le Prell, Colleen, Editorial Board Member, Litovsky, Ruth, Editorial Board Member, Manis, Paul, Editorial Board Member, Manley, Geoffrey, Editorial Board Member, Moore, Brian, Editorial Board Member, Simmons, Andrea, Editorial Board Member, Yost, William, Editorial Board Member, and Ketten, Darlene R., editor

Published

2024