Your search keyword '"James B. Kobler"' showing total 3 results

1. Simultaneous 3D imaging of sound-induced motions of the tympanic membrane and middle ear ossicles

Author

James B. Kobler, Seok Hyun Yun, Jeffrey Cheng, Ernest W. Chang, John J. Rosowski, and Christof Röösli

Subjects

Tympanic Membrane, Movement, Acoustics, Vibration, Article, Imaging, Three-Dimensional, Optical coherence tomography, Chinchilla, Otology, medicine, Animals, Humans, Ear Diseases, Acoustic reflex, Sound pressure, Ear Ossicles, Audio frequency, Physics, medicine.diagnostic_test, Ossicles, medicine.disease, Sensory Systems, Conductive hearing loss, medicine.anatomical_structure, Acoustic Stimulation, Middle ear, Tomography, Optical Coherence

Abstract

Efficient transfer of sound by the middle ear ossicles is essential for hearing. Various pathologies can impede the transmission of sound and thereby cause conductive hearing loss. Differential diagnosis of ossicular disorders can be challenging since the ossicles are normally hidden behind the tympanic membrane (TM). Here we describe the use of a technique termed optical coherence tomography (OCT) vibrography to view the sound-induced motion of the TM and ossicles simultaneously. With this method, we were able to capture three-dimensional motion of the intact TM and ossicles of the chinchilla ear with nanometer-scale sensitivity at sound frequencies from 0.5 to 5 kHz. The vibration patterns of the TM were complex and highly frequency dependent with mean amplitudes of 70–120 nm at 100 dB sound pressure level. The TM motion was only marginally sensitive to stapes fixation and incus-stapes joint interruption; however, when additional information derived from the simultaneous measurement of ossicular motion was added, it was possible to clearly distinguish these different simulated pathologies. The technique may be applicable to clinical diagnosis in Otology and to basic research in audition and acoustics.

Published

2013

2. Motoneuron axon distribution in the cat stapedius muscle

Author

James B. Kobler, Barbara E. Norris, Sylvette R. Wiener-Vacher, and John J. Guinan

Subjects

Motor Neurons, Muscle Fibers, Skeletal, Anatomy, Stapedius, Biology, Motor neuron, Facial nerve, Stapedius muscle, Motor Endplate, Sensory Systems, Axons, Motor unit, medicine.anatomical_structure, nervous system, medicine, Cats, Animals, Brainstem, Axon, Acoustic reflex, Neuroscience, Horseradish Peroxidase

Abstract

Stapedius-motoneuron cell bodies in the brainstem are spatially organized according to their acoustic response laterality, as demonstrated by intracellular labeling of physiologically identified motoneurons [Vacher et al., 1989. J. Comp. Neurol. 289, 401-415]. To determine whether a similar functional spatial segregation is present in the muscle, we traced physiologically identified, labeled axons into the stapedius muscle. Ten labeled axons were visible in the facial nerve and five could be traced to endplates within the muscle. These five axons had 39 observed branches (others may have been missed). This indicates an average innervation ratio (> or = 7.8) which is much higher than that obtained from previous estimates of the numbers of stapedius motoneurons and muscle fibers in the cat. One well-labeled stapedius motor axon innervated only a single muscle fiber. In contrast, two labeled axons had over 10 endings and innervated muscle fibers spread over wide areas in the muscle. Two of the axons branched and coursed through two primary stapedius fascicles, indicating that the muscle zones innervated by different primary fascicles are not functionally segregated. In another series of experiments, retrograde tracers were deposited in individual primary nerve fascicles. In every case, labeled stapedius-motoneuron cell bodies were found in each of the physiologically identified stapedius-motoneuron regions in the brainstem. These observations suggest there is little, if any, functional spatial segregation based on separate muscle compartments in the stapedius muscle, despite there being functional spatial segregation in the stapedius-motoneuron pool centrally.

Published

1999

3. Echo intensity compensation by echolocating bats

Author

James B. Kobler, O.W. Henson, Blake S. Wilson, and A.L. Bishop

Subjects

Physics, biology, Pulse (signal processing), Acoustics, Movement, Echo (computing), Pendulum, Human echolocation, biology.organism_classification, Sensory Systems, Intensity (physics), symbols.namesake, Sound, Chiroptera, Echolocation, Orientation, Pteronotus, symbols, Animals, Ultrasonic sensor, Cues, Doppler effect

Abstract

When mounted on a swinging pendulum, mustache bats, Pteronotus p. parnellii, emit ultrasonic pulses as they move toward and away from fixed targets. During forward swings they systematically decrease the intensity of their emitted pulses and during backward swings they increase the intensity. In this way, echo strength is continuously adjusted and apparently optimized for signal analysis. We have called this behavior echo intensity compensation. Pteronotus simultaneously Doppler and echo intensity compensate during forward swings of the pendulum but during backward swings they only echo intensity compensate. Pteronotus can regulate the intensity of both the constant frequency and frequency modulated components of their pulses; this regulation is independent of vestibular cues, pulse repetition rates, pulse durations and pulse-echo intervals.

Published

1985