Mechanical amplification of stimuli by hair cells
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Cited by (170)
2.16 - Genetics of Mechanoreceptor Evolution and Development
2020, The Senses: A Comprehensive Reference: Volume 1-7, Second EditionModeling the characteristics of spontaneous otoacoustic emissions in lizards
2020, Hearing ResearchCitation Excerpt :Active processes are those mechanisms that, at low sound levels, induce larger micromechanical responses of the sensory cells to stimuli than would be produced passively. Such active processes can be identified by a number of signature characteristics (Hudspeth, 1997; Manley, 2001). One manifestation of the active process is the spontaneous production of mechanical energy by the auditory organs in the complete absence of any external stimuli.
The collusion of flexoelectricity and Hopf bifurcation in the hearing mechanism
2019, Journal of the Mechanics and Physics of SolidsNoise-induced Cochlear Synaptopathy and Signal Processing Disorders
2019, NeuroscienceBio-inspired fluidic thermal angular accelerometer with inherent linear acceleration rejection
2018, Sensors and Actuators, A: PhysicalCitation Excerpt :Nature takes advantage of physical effects from the macroscale to the nanoscale [1]. By taking full advantage of these effects, sensory systems found in nature have reached performances that are nearly physics-limited: the visual system resolution is at the one photon level [2] and performance of the hair cells in the mammalian auditory system and the wind cricket’s flow sensor is nearing the thermal noise limit [3,4]. For the vestibular or balance system, nature -through natural selection- has evolved over thousands of years a power-efficient, elegant sensor design to sense rotational movement, and inherently reject linear motion [5,6].
The cochlear amplifier: Is it hair bundle motion of outer hair cells?
2014, Journal of Otology