Simulation of mechanical to neural transduction in the auditory receptor

Meddis, Ray

doi:10.1121/1.393460

Cited by 274 publications

(185 citation statements)

References 10 publications

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“…10 and 12), something not observed with acoustic stimulation. Javel (1990) noted that adaptation to electric stimuli calls for a reevaluation of the mechanisms of adaptation, which is often solely attributed to the hair cell and synapse (e.g., Smith and Brachman 1982;Meddis 1986). One approach to this issue would be to compare acoustic and electric adaptation as functions of instantaneous, or short-term, response rates.…”

Section: Adaptationmentioning

confidence: 99%

Electrical Excitation of the Acoustically Sensitive Auditory Nerve: Single-Fiber Responses to Electric Pulse Trains

Miller

Abbas

Robinson

et al. 2006

JARO

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Nearly all studies on auditory-nerve responses to electric stimuli have been conducted using chemically deafened animals so as to more realistically model the implanted human ear that has typically been profoundly deaf. However, clinical criteria for implantation have recently been relaxed. Ears with Bresidualâ coustic sensitivity are now being implanted, calling for the systematic evaluation of auditory-nerve responses to electric stimuli as well as combined electric and acoustic stimuli in acoustically sensitive ears. This article presents a systematic investigation of single-fiber responses to electric stimuli in acoustically sensitive ears. Responses to 250 pulse/s electric pulse trains were collected from 18 cats. Properties such as threshold, dynamic range, and jitter were found to differ from those of deaf ears. Other types of fiber activity observed in acoustically sensitive ears (i.e., spontaneous activity and electrophonic responses) were found to alter the temporal coding of electric stimuli. The electrophonic response, which was shown to greatly change the information encoded by spike intervals, also exhibited fast adaptation relative to that observed in the Bdirect^response to electric stimuli. More complex responses, such as Bbuildup^(increased responsiveness to successive pulses) and Bbursting^(alternating periods of responsiveness and unresponsiveness) were observed. Our findings suggest that bursting is a response unique to sustained electric stimulation in ears with functional hair cells.

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Section: Adaptationmentioning

confidence: 99%

Electrical Excitation of the Acoustically Sensitive Auditory Nerve: Single-Fiber Responses to Electric Pulse Trains

Miller

Abbas

Robinson

et al. 2006

JARO

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“…Although the mechanism that gives rise to synaptic adaptation is not completely understood, it could be caused either by the depletion of neurotransmitter from a readily releasable presynaptic pool of neurotransmitter ͑Moser and Beutner, 2000; Schnee et al, 2005;Goutman and Glowatzki, 2007͒ or by the desensitization of post-synaptic receptors ͑Raman et al, 1994͒. Modeling the adaptation in the IHC-AN synapse has been a focus of extensive research over the last several decades. Early attempts employed a single-reservoir system with loss and replenishment of transmitter quanta ͑Schroeder and Hall, 1974;Sujaku, 1974, 1975͒, and later models added extra reservoirs ͑or sites͒ or more complex principles of transmitter flow control ͑Furukawa and Matsuura, 1978;Furukawa et al, 1982;Ross, 1982Ross, , 1996Schwid and Geisler, 1982;Smith and Brachman, 1982;Cooke, 1986;Meddis, 1986Meddis, , 1988Westerman and Smith, 1988͒. In general, the transmitter in these models lies in reservoirs or sites close to the presynaptic membrane and diffuses between reservoirs within the cell and out of the cell to the synaptic cleft.…”

Section: Introductionmentioning

confidence: 99%

“…The diversity and complexity of adaptation pose a great challenge for successful modeling of the dynamics of this synapse. Two models with different structures have been developed independently in a series of studies ͑Meddis, 1986͑Meddis, , 1988Westerman and Smith, 1988;Carney, 1993;Zhang et al, 2001;Sumner et al, 2002. However, the mathematical descriptions of these two models are essentially equivalent despite their structural differences ͑Zhang and Carney, 2005͒.…”

Section: Introductionmentioning

confidence: 99%

A phenomenological model of the synapse between the inner hair cell and auditory nerve: Long-term adaptation with power-law dynamics

Zilany

Bruce²,

Nelson³

et al. 2009

The Journal of the Acoustical Society of America

318

346

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There is growing evidence that the dynamics of biological systems that appear to be exponential over short time courses are in some cases better described over the long-term by power-law dynamics. A model of rate adaptation at the synapse between inner hair cells and auditory-nerve ͑AN͒ fibers that includes both exponential and power-law dynamics is presented here. Exponentially adapting components with rapid and short-term time constants, which are mainly responsible for shaping onset responses, are followed by two parallel paths with power-law adaptation that provide slowly and rapidly adapting responses. The slowly adapting power-law component significantly improves predictions of the recovery of the AN response after stimulus offset. The faster power-law adaptation is necessary to account for the "additivity" of rate in response to stimuli with amplitude increments. The proposed model is capable of accurately predicting several sets of AN data, including amplitude-modulation transfer functions, long-term adaptation, forward masking, and adaptation to increments and decrements in the amplitude of an ongoing stimulus.

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“…The output of each gammatone filter serves as input to Meddis' model of the mechanical to neural transduction at the hair cell-auditory nerve synapse (Meddis, 1986(Meddis, , 1988Meddis et al, 1990). The output is the instantaneous AN discharge rate function in response to arbitrary stimuli.…”

Section: Auditory Peripherymentioning

confidence: 99%

“…In the peripheral stage of the present model, the mechanical to neural transduction at the hair cell-auditory nerve synapse was simulated using Meddis' model implementation (Meddis, 1986(Meddis, , 1988Meddis et al, 1990). Instead of actually computing individual spike trains for each AN fiber the "deterministic" rate function at the output of the synapse was considered as representing the AN activity.…”

Section: Simplifications Made In the Present Modelmentioning

confidence: 99%

A Functional Point-Neuron Model Simulating Cochlear Nucleus Ideal Onset Responses

Dicke

Dau

2005

J Comput Neurosci

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Simulation of mechanical to neural transduction in the auditory receptor

Cited by 274 publications

References 10 publications

Electrical Excitation of the Acoustically Sensitive Auditory Nerve: Single-Fiber Responses to Electric Pulse Trains

Electrical Excitation of the Acoustically Sensitive Auditory Nerve: Single-Fiber Responses to Electric Pulse Trains

A phenomenological model of the synapse between the inner hair cell and auditory nerve: Long-term adaptation with power-law dynamics

A Functional Point-Neuron Model Simulating Cochlear Nucleus Ideal Onset Responses

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