Efferent Feedback Minimizes Cochlear Neuropathy from Moderate Noise Exposure

Maison, Stéphane F.; Usubuchi, Hajime; Liberman, M. Charles

doi:10.1523/jneurosci.5027-12.2013

Cited by 200 publications

(213 citation statements)

References 50 publications

(80 reference statements)

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“…The nervous system can set the value of the threshold by using efferent feedback. For example, hearing loss to sound intensities that normally would not produce deafness can arise because of a failure of efferent feedback in the cochlear nucleus [59]. The observation that the detection threshold for ankle proprioception depends on muscle tension in the calf muscles [79,80] raises the question as to whether detection thresholds for balance can be similarly adjusted by adopting different postures while standing.…”

Section: Stimulus Amplitudementioning

confidence: 99%

Human Balance Control: Dead Zones, Intermittency, and Micro-chaos

Milton

Insperger

Stépàn

2015

Mathematical Approaches to Biological Systems

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Summary. The development of strategies to minimize the risk of falling in the elderly represents a major challenge for aging, in industrialized societies. The corrective movements made by humans to maintain balance are small amplitude, intermittent and ballistic. Small amplitude, complex oscillations (micro-chaos) frequently arise in industrial settings when a time-delayed digital processor attempts to stabilize an unstable equilibrium. Taken together these observations motivate considerations of the effects of a sensory threshold on the stabilization of an inverted pendulum by time-delayed feedback. In the resulting switching-type delay differential equations, the sensory threshold is a strong small-scale nonlinearity which has no effect on large-scale stabilization, but may produce complex, small amplitude dynamics including limit cycle oscillations and micro-chaos. A close mathematical relationship exists between a scalar model for balance control and the micro-chaotic map that arises in some models of digitally controlled machines. Surprisingly, transient, timedependent, bounded solutions (transient stabilization) can arise even for parameter ranges where the equilibrium is asymptotically unstable. In other words the combination of a sensory threshold with a time-delayed sampled feedback can increase the range of parameter values for which balance can be maintained, at least transiently. Neuro-biological observations suggest that sensory thresholds can be manipulated either passively by changing posture or actively using efferent feedback. Thus it may be possible to minimize the risk of falling by means of strategies that manipulate sensory thresholds by using physiotherapy and appropriate exercises.

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Section: Stimulus Amplitudementioning

confidence: 99%

Human Balance Control: Dead Zones, Intermittency, and Micro-chaos

Milton

Insperger

Stépàn

2015

Mathematical Approaches to Biological Systems

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“…The MOCR may be essential for normal development of cochlear active mechanical processes (Walsh et al 1998), and/or to minimize deleterious effects of noise exposure on cochlear function (Maison et al 2013). A more widely accepted role is that the MOCR possibly facilitates understanding speech in noisy environments.…”

Section: Introductionmentioning

confidence: 99%

Physiology, Psychoacoustics and Cognition in Normal and Impaired Hearing

Dijk¹,

Başkent²,

Gaudrain

et al. 2016

Advances in Experimental Medicine and Biology

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“…Furthermore, vulnerability of the mouse cochlear nerve to TTS increases when the LOC efferents are removed [10]. An antiexcitotoxicity role of the LOC system has been suggested [10,38,46]. It is difficult to measure the LOC, but there is some speculation that MOC and LOC strengths are related in individuals [35], so LOC strength might be inferable from MOC strength.…”

mentioning

confidence: 99%

“…Recent work has shown that another effect of noise damage, even at moderate noise-exposure levels that do not result in permanent hearing loss, is a permanent cochlear-nerve deficit affecting high-threshold, low-and medium-SR fibers [15,29], which are important for supra-threshold temporal processing [2]. The underlying cause presumably is glutamate excitotoxicity [38]. Why it preferentially affects low-and medium-SR fibers is not known [2] but may be due to low mitochondrial content [38].…”

mentioning

confidence: 99%