A Critique of the Critical Cochlea: Hopf—a Bifurcation—Is Better Than None

Hudspeth, A. J.; Jülicher, Frank; Martin, Pascal

doi:10.1152/jn.00437.2010

Cited by 119 publications

(138 citation statements)

References 93 publications

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“…In mammals, manifestations of the so-called cochlear amplifier are the high sensitivity and frequency selectivity with respect to weak stimuli, the compressive nonlinearity, and the generation of oto-acoustic emissions. All aspects of the active process are consistent with the notion of nonlinear oscillators at work in the cochlea [2]. This regards in particular the properties of the active wave traveling in the cochlea, which could be generically described in terms of critical oscillators and has been explored previously in the frequency (Fourier) domain [1].…”

supporting

confidence: 79%

Time-Domain Representation of Active Nonlinear Cochlear Waves

Fruth¹,

Dierkes²,

Lindner³

et al. 2011

AIP Conference Proceedings

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Abstract. The mammalian cochlea has been recognized to act as an active and nonlinear amplifier. Previously, a generic description in terms of critical oscillators has been explored in the Fourier domain. Here, we discuss a generalized variant of this model formulated in the time domain. As a first step, we verify that the model's response to periodic stimulation is similar to the original Fourier-domain model. The description in the time domain offers the possibility to study the effects of static and dynamic noise sources on the spectral statistics of spontaneous and evoked otoacoustic emissions. Keywords: active nonlinearity, spontaneous otoacoustic emissions PACS: 43.64.Bt ,43.64.Jb SUMMARYThe sense of hearing relies on active amplification of sound-induced vibrations in the inner ear. In mammals, manifestations of the so-called cochlear amplifier are the high sensitivity and frequency selectivity with respect to weak stimuli, the compressive nonlinearity, and the generation of oto-acoustic emissions. All aspects of the active process are consistent with the notion of nonlinear oscillators at work in the cochlea [2]. This regards in particular the properties of the active wave traveling in the cochlea, which could be generically described in terms of critical oscillators and has been explored previously in the frequency (Fourier) domain [1]. This one-dimensional model describes a nonlinear cochlear wave that is pumped by active oscillators.Our aim is to extend and generalize this model to include dynamical noise (originating, e.g. in the stochastic activity of outer hair cells) and static disorder (resulting from inhomogeneities of system parameters along the cochlea). In order to incorporate these features we construct a generic model of the cochlear partition in the time domain, using similar approaches as in [4,5]. Firstly, we use a hydrodynamic equation relating the pressure difference p and the displacement h of the basilar membrane. Secondly, we assume that locally basilar membrane vibrations are governed by a generic Hopf-oscillator dynamics with a best frequency that varies exponentially for the oscillators along the cochlea. We simulate this using a discretization with N = 3000 critical oscillators.As a first step, we checked whether the model's response to periodic stimulation is similar to that of the model of [1]; note that time-domain and frequency-domain models are not identical but differ in their nonlinearities. Figure 1 shows the envelope of the traveling wave of displacement h for two amplitudes of stimulation. The envelope of the time-domain model was determined by Fourier transformation of each oscillator's trajectory and is also compared to a numerical solution of the Fourier-domain model. For weak stimulation, we find a good agreement between the two methods, peak location of

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supporting

confidence: 79%

Time-Domain Representation of Active Nonlinear Cochlear Waves

Fruth¹,

Dierkes²,

Lindner³

et al. 2011

AIP Conference Proceedings

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“…33 In particular, recent works have shown that the "phase response curve," a metric of the dynamics of a neuronal oscillator perturbed by weak noise, is directly related to its linear transfer function, 25,69 so that a direct link can be made between dynamics and information encoding into neuronal spike timing. 69 Physiological studies on several species have shown and discussed essential nonlinearities of sensory encoding in auditory, 22,38 visual, 40,56,59 vestibular, 66 mechanosensory, 61 and electrosensory 14,16 systems. In many cases, nonlinearities were associated with non-weak stimuli or with the existence of bursting patterns of neural firing.…”

Section: Introductionmentioning

confidence: 99%

Sensory coding in oscillatory electroreceptors of paddlefish

Neiman

Russell²

2011

Chaos: An Interdisciplinary Journal of Nonlinear Science

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Coherence and information theoretic analyses were applied to quantitate the response properties and the encoding of time-varying stimuli in paddlefish electroreceptors (ERs), studied in vivo. External electrical stimuli were Gaussian noise waveforms of varied frequency band and strength, including naturalistic waveforms derived from zooplankton prey. Our coherence analyses elucidated the role of internal oscillations and transduction processes in shaping the 0.5-20 Hz best frequency tuning of these electroreceptors, to match the electrical signals emitted by zooplankton prey. Stimulus-response coherence fell off above approximately 20 Hz, apparently due to intrinsic limits of transduction, but was detectable up to 40-50 Hz. Aligned with this upper fall off was a narrow band of intense internal noise at $25 Hz, due to prominent membrane potential oscillations in cells of sensory epithelia, which caused a narrow deadband of external insensitivity. Using coherence analysis, we showed that more than 76% of naturalistic stimuli of weak strength, $1 lV=cm, was linearly encoded into an afferent spike train, which transmitted information at a rate of $30 bits=s. Stimulus transfer to afferent spike timing became essentially nonlinear as the stimulus strength was increased to induce bursting firing. Strong stimuli, as from nearby zooplankton prey, acted to synchronize the bursting responses of afferents, including across populations of electroreceptors, providing a plausible mechanism for reliable information transfer to higher-order neurons through noisy synapses. Rhythmical activity underlies various complex physiological processes in central nervous systems. Peripheral sensory receptors, on the other hand, are often considered as "passive" systems with relatively simple and linear dynamics. Nevertheless, self-sustained oscillations have been observed in several types of peripheral sensory receptors. This paper reports on stimulus encoding in electroreceptors (ERs) of paddlefish, which use passive electrosense to feed on zooplankton. A single peripheral electroreceptor in paddlefish is a complex system comprised of several thousands of sensory epithelial cells innervated by a few primary sensory neurons (afferents). It embeds distinct oscillators: one resides in a population of epithelial cells, synaptically coupled to another oscillator in afferent terminals. In contrast to auditory receptors, which resonate to sound waves of certain frequency, neither epithelial nor afferent rhythms of electroreceptors match the low-frequency bioelectric signals emitted by zooplankton prey. We applied Gaussian noise stimuli to study how oscillators embedded in paddlefish electroreceptors shape the linear and nonlinear responses of electroreceptors, and to characterize quantitatively how external stimuli, including bioelectrical signals from zooplankton prey, are encoded into the timing of afferent firing.

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“…Please cite this article in press as: Albert and Kozlov, Comparative Aspects of Hearing in Vertebrates and Insects with Antennal Ears, Current Biology (2016), http://dx.doi.org/10.1016/j.cub.2016 to maintain the system's control parameters in the desired range in order to benefit functionally from the oscillatory instability) [12]. Thus, natural selection has produced ears that operate close to a bifurcation [12], which produces amplification, frequency selectivity, and a gain control -characteristics that underlie sensitive hearing in vertebrates as well as in some insects.…”

Section: Curbio 13179mentioning

confidence: 99%

Comparative Aspects of Hearing in Vertebrates and Insects with Antennal Ears

Albert¹,

Kozlov

2016

Current Biology

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The evolution of hearing in terrestrial animals has resulted in remarkable adaptations enabling exquisitely sensitive sound detection by the ear and sophisticated sound analysis by the brain. In this review, we examine several such characteristics, using examples from insects and vertebrates. We focus on two strong and interdependent forces that have been shaping the auditory systems across taxa: the physical environment of auditory transducers on the small, subcellular scale, and the sensory-ecological environment within which hearing happens, on a larger, evolutionary scale. We briefly discuss acoustical feature selectivity and invariance in the central auditory system, highlighting a major difference between insects and vertebrates as well as a major similarity. Through such comparisons within a sensory ecological framework, we aim to emphasize general principles underlying acute sensitivity to airborne sounds.Introduction Auditory physiology offers a distinctive perspective on the interaction between a sensory system and its environment. On the one hand, auditory systems in vertebrates and insects with sensitive hearing are capable of remarkable performances on multiple levels, both within the sensory periphery where the minute energies associated with sound are converted into electrical signals, as well as within higher-order brain areas where complex natural stimuli such as human speech are processed. For example, displacements caused by acoustical stimuli in the inner ear at the threshold of hearing are sub-nanometer and comparable to the distance between atoms in molecules [1]. Furthermore, thermal fluctuations in the ear's mechanotransduction apparatus not only are significant, but also can be larger than the faintest audible signals, making signal detection a challenging task [2]. Ascending the sensory hierarchy, one encounters other marvels of evolution, such as the ability of individual neurons to encode -using millisecond-long action potentials -inter-aural time differences of only about ten microseconds, and to use this information to localize the source of the sound [3,4]. No engineered system has yet been designed that could understand distorted speech in a noisy and reverberating environment with multiple speakers. That our auditory system achieves this feat is testament to its remarkable performance.On the other hand, an engineer could argue that the auditory system's performance is objectively poor, even in animals with sensitive hearing: at the very first step, during the mechanoelectrical transduction in the inner ear, external sounds are distorted, or even completely suppressed, while new tones are generated by the ear itself [5]. Forward and backward masking, illusory percepts of nonexistent tones (such as the Zwicker illusion [6]), perceptual merging of separate auditory streams, the precedence effect suppressing the perception of echoes that has been demonstrated in insects and vertebrates [7,8] (and which some blind people can unsuppress), auditory hallucinations, and a frustrating inab...

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A Critique of the Critical Cochlea: Hopf—a Bifurcation—Is Better Than None

Cited by 119 publications

References 93 publications

Time-Domain Representation of Active Nonlinear Cochlear Waves

Time-Domain Representation of Active Nonlinear Cochlear Waves

Sensory coding in oscillatory electroreceptors of paddlefish

Comparative Aspects of Hearing in Vertebrates and Insects with Antennal Ears

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