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2. Volterra-series approach to stochastic nonlinear dynamics: linear response of the Van der Pol oscillator driven by white noise

Author

Belousov, Roman, Berger, Florian, and Hudspeth, A. J.

Subjects
Condensed Matter - Statistical Mechanics, Nonlinear Sciences - Chaotic Dynamics
Abstract

The Van der Pol equation is a paradigmatic model of relaxation oscillations. This remarkable nonlinear phenomenon of self-sustained oscillatory motion underlies important rhythmic processes in nature and electrical engineering. Relaxation oscillations in a real system are usually coupled to environmental noise, which further enriches their dynamics, but makes theoretical analysis of such systems and determination of the equation's parameter values a difficult task. In a companion paper we have proposed an analytic approach to a similar problem for another classical nonlinear model, the bistable Duffing oscillator. Here we extend our techniques to the case of the Van der Pol equation driven by white noise. We analyze the statistics of solutions and propose a method to estimate parameter values from the oscillator's time series. We use experimental data of active oscillations in a biological system to demonstrate how our method applies to real observations and how it can be generalized for more complex models., Comment: 12 pages, 6 figures, 1 table

Published
2019
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3. A Volterra-series approach to stochastic nonlinear dynamics: The Duffing oscillator driven by white noise

Author

Belousov, Roman, Berger, Florian, and Hudspeth, A. J.

Subjects
Condensed Matter - Statistical Mechanics
Abstract

The Duffing oscillator is a paradigm of bistable oscillatory motion in physics, engineering, and biology. Time series of such oscillations are often observed experimentally in a nonlinear system excited by a spontaneously fluctuating force. One is then interested in estimating effective parameter values of the stochastic Duffing model from these observations--a task that has not yielded to simple means of analysis. To this end we derive theoretical formulas for the statistics of the Duffing oscillator's time series. Expanding on our analytical results, we introduce methods of statistical inference for the parameter values of the stochastic Duffing model. By applying our method to time series from stochastic simulations, we accurately reconstruct the underlying Duffing oscillator. This approach is quite straightforward--similar techniques are used with linear Langevin models--and can be applied to time series of bistable oscillations that are frequently observed in experiments., Comment: 8 pages, 4 figures

Published
2019
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4. Fluctuation theory in space and time: white noise in reaction-diffusion models of morphogenesis

Author

Belousov, Roman, Jacobo, Adrian, and Hudspeth, A. J.

Subjects
Condensed Matter - Statistical Mechanics
Abstract

The precision of reaction-diffusion models for mesoscopic physical systems is limited by fluctuations. To account for this uncertainty, Van Kampen derived a stochastic Langevin-like reaction-diffusion equation that incorporates spatio-temporal white noise. The resulting solutions, however, have infinite standard deviation. Ad hoc modifications that address this issue by introducing microscopic correlations are inconvenient in many physical contexts of wide interest. We instead estimate the magnitude of fluctuations by coarse-graining solutions of the Van Kampen equation at a relevant mesoscopic scale. The ensuing theory yields fluctuations of finite magnitude. Our approach is demonstrated for a specific biophysical model--the encoding of positional information. We discuss the properties of the fluctuations and the role played by the macroscopic parameters of the underlying reaction-diffusion model. The analysis and numerical methods developed here can be applied in physical problems to predict the magnitude of fluctuations. This general approach can also be extended to other classes of dynamical systems that are described by partial differential equations., Comment: 12 pages, 3 figures

Published
2018
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5. Control of a hair bundle's mechanosensory function by its mechanical load

Author

Salvi, Joshua D., Maoileidigh, Daibhid O, Fabella, Brian A., Tobin, Melanie, and Hudspeth, A. J.

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Biological Physics, Quantitative Biology - Cell Behavior, 70K50, 92C20, 92C05, 92B25, 37N25
Abstract

Hair cells, the sensory receptors of the internal ear, subserve different functions in various receptor organs: they detect oscillatory stimuli in the auditory system, but transduce constant and step stimuli in the vestibular and lateral-line systems. We show that a hair cell's function can be controlled experimentally by adjusting its mechanical load. By making bundles from a single organ operate as any of four distinct types of signal detector, we demonstrate that altering only a few key parameters can fundamentally change a sensory cell's role. The motions of a single hair bundle can resemble those of a bundle from the amphibian vestibular system, the reptilian auditory system, or the mammalian auditory system, demonstrating an essential similarity of bundles across species and receptor organs.

Published
2017
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6. The Critical Thing about the Ear’s Sensory Hair Cells.

Author

Hudspeth, A. J. and Martin, Pascal

Subjects
*HAIR cells, *EAR, *EXTERNAL ear, *INNER ear, *SOUND energy, *VESTIBULAR apparatus, *COCHLEA
Abstract

The capabilities of the human ear are remarkable. We can normally detect acoustic stimuli down to a threshold sound-pressure level of 0 dB (decibels) at the entrance to the external ear, which elicits eardrum vibrations in the picometer range. From this threshold up to the onset of pain, 120 dB, our ears can encompass sounds that differ in power by a trillionfold. The comprehension of speech and enjoyment of music result from our ability to distinguish between tones that differ in frequency by only 0.2%. All these capabilities vanish upon damage to the ear’s receptors, the mechanoreceptive sensory hair cells. Each cochlea, the auditory organ of the inner ear, contains some 16,000 such cells that are frequency-tuned between ∼20 Hz (cycles per second) and 20,000 Hz. Remarkably enough, hair cells do not simply capture sound energy: they can also exhibit an active process whereby sound signals are amplified, tuned, and scaled. This article describes the active process in detail and offers evidence that its striking features emerge from the operation of hair cells on the brink of an oscillatory instability—one example of the critical phenomena that are widespread in physics. [ABSTRACT FROM AUTHOR]

Published
2024
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7. Nanomechanics of wild-type and mutant dimers of the inner-ear tip-link protein protocadherin 15.

Author

Villasante, Camila M., Xinyue Deng, Cohen, Joel E., and Hudspeth, A. J.

Subjects
INNER ear, ION channels, CADHERINS, HAIR cells, DEAFNESS
Abstract

Mechanical force controls the opening and closing of mechanosensitive ion channels atop the hair bundles of the inner ear. The filamentous tip link connecting transduction channels to the tallest neighboring stereocilium modulates the force transmitted to the channels and thus changes their probability of opening. Each tip link comprises four molecules: a dimer of protocadherin 15 (PCDH15) and a dimer of cadherin 23, all of which are stabilized by Ca2+ binding. Using a high-speed optical trap to examine dimeric PCDH15, we find that the protein's mechanical properties are sensitive to Ca2+ and that the molecule exhibits limited unfolding at a physiological Ca2+ concentration. PCDH15 can therefore modulate its stiffness without undergoing large unfolding events under physiological conditions. The experimentally determined stiffness of PCDH15 accords with published values for the stiffness of the gating spring, the mechanical element that controls the opening of mechanotransduction channels. When PCDH15 exhibits a point mutation, V507D, associated with nonsyndromic hearing loss, unfolding events occur more frequently under tension and refolding events occur less often than for the wild-type protein. Our results suggest that the maintenance of appropriate tension in the gating spring is critical to the appropriate transmission of force to transduction channels, and hence to hearing. [ABSTRACT FROM AUTHOR]

Published
2024
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9. Identification of Bifurcations from Observations of Noisy Biological Oscillators

Author

Salvi, Joshua D., Maoiléidigh, Dáibhid Ó, and Hudspeth, A. J.

Subjects
Physics - Biological Physics, Quantitative Biology - Cell Behavior, Quantitative Biology - Neurons and Cognition
Abstract

Hair bundles are biological oscillators that actively transduce mechanical stimuli into electrical signals in the auditory, vestibular, and lateral-line systems of vertebrates. A bundle's function can be explained in part by its operation near a particular type of bifurcation, a qualitative change in behavior. By operating near different varieties of bifurcation, the bundle responds best to disparate classes of stimuli. We show how to determine the identity of and proximity to distinct bifurcations despite the presence of substantial environmental noise., Comment: 6 figures, 1 supporting material

Published
2016
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11. The physics of hearing: fluid mechanics and the active process of the inner ear

Author

Reichenbach, T. and Hudspeth, A. J.

Subjects
Quantitative Biology - Neurons and Cognition, Nonlinear Sciences - Adaptation and Self-Organizing Systems, Physics - Biological Physics, Quantitative Biology - Tissues and Organs
Abstract

Most sounds of interest consist of complex, time-dependent admixtures of tones of diverse frequencies and variable amplitudes. To detect and process these signals, the ear employs a highly nonlinear, adaptive, real-time spectral analyzer: the cochlea. Sound excites vibration of the eardrum and the three miniscule bones of the middle ear, the last of which acts as a piston to initiate oscillatory pressure changes within the liquid-filled chambers of the cochlea. The basilar membrane, an elastic band spiraling along the cochlea between two of these chambers, responds to these pressures by conducting a largely independent traveling wave for each frequency component of the input. Because the basilar membrane is graded in mass and stiffness along its length, however, each traveling wave grows in magnitude and decreases in wavelength until it peaks at a specific, frequency-dependent position: low frequencies propagate to the cochlear apex, whereas high frequencies culminate at the base. The oscillations of the basilar membrane deflect hair bundles, the mechanically sensitive organelles of the ear's sensory receptors, the hair cells. As mechanically sensitive ion channels open and close, each hair cell responds with an electrical signal that is chemically transmitted to an afferent nerve fiber and thence into the brain. In addition to transducing mechanical inputs, hair cells amplify them [...], Comment: 86 pages, 24 figures

Published
2014
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16. Waves on Reissner's membrane: a mechanism for the propagation of otoacoustic emissions from the cochlea

Author

Reichenbach, Tobias, Stefanovic, Aleksandra, Nin, Fumiaki, and Hudspeth, A. J.

Subjects
Quantitative Biology - Tissues and Organs, Physics - Biological Physics, Physics - Computational Physics
Abstract

Sound is detected and converted into electrical signals within the ear. The cochlea not only acts as a passive detector of sound, however, but can also produce tones itself. These otoacoustic emissions are a striking manifestation of the cochlea's mechanical active process. A controversy remains of how these mechanical signals propagate back to the middle ear, from which they are emitted as sound. Here we combine theoretical and experimental studies to show that mechanical signals can be transmitted by waves on Reissner's membrane, an elastic structure within the cochea. We develop a theory for wave propagation on Reissner's membrane and its role in otoacoustic emissions. Employing a scanning laser interferometer, we measure traveling waves on Reissner's membrane in the gerbil, guinea pig, and chinchilla. The results accord with the theory and thus support a role for Reissner's membrane in otoacoustic emissions., Comment: 30 pages, 6 figures, and Supplemental information

Published
2012
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17. Frequency decoding of periodically timed action potentials through distinct activity patterns in a random neural network

Author

Reichenbach, Tobias and Hudspeth, A. J.

Subjects
Quantitative Biology - Neurons and Cognition, Condensed Matter - Disordered Systems and Neural Networks, Physics - Biological Physics
Abstract

Frequency discrimination is a fundamental task of the auditory system. The mammalian inner ear, or cochlea, provides a place code in which different frequencies are detected at different spatial locations. However, a temporal code based on spike timing is also available: action potentials evoked in an auditory-nerve fiber by a low-frequency tone occur at a preferred phase of the stimulus-they exhibit phase locking-and thus provide temporal information about the tone's frequency. In an accompanying psychoacoustic study, and in agreement with previous experiments, we show that humans employ this temporal information for discrimination of low frequencies. How might such temporal information be read out in the brain? Here we demonstrate that recurrent random neural networks in which connections between neurons introduce characteristic time delays, and in which neurons require temporally coinciding inputs for spike initiation, can perform sharp frequency discrimination when stimulated with phase-locked inputs. Although the frequency resolution achieved by such networks is limited by the noise in phase locking, the resolution for realistic values reaches the tiny frequency difference of 0.2% that has been measured in humans., Comment: 16 pages, 5 figures, and supplementary information

Published
2012
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18. Discrimination of low-frequency tones employs temporal fine structure

Author

Reichenbach, Tobias and Hudspeth, A. J.

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Biological Physics, Quantitative Biology - Quantitative Methods
Abstract

An auditory neuron can preserve the temporal fine structure of a low-frequency tone by phase-locking its response to the stimulus. Apart from sound localization, however, little is known about the role of this temporal information for signal processing in the brain. Through psychoacoustic studies we provide direct evidence that humans employ temporal fine structure to discriminate between frequencies. To this end we construct tones that are based on a single frequency but in which, through the concatenation of wavelets, the phase changes randomly every few cycles. We then test the frequency discrimination of these phase-changing tones, of control tones without phase changes, and of short tones that consist of a single wavelets. For carrier frequencies below a few kilohertz we find that phase changes systematically worsen frequency discrimination. No such effect appears for higher carrier frequencies at which temporal information is not available in the central auditory system., Comment: 12 pages, 3 figures

Published
2012
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19. Relative stereociliary motion in a hair bundle opposes amplification at distortion frequencies

Author

Kozlov, Andrei S., Risler, Thomas, Hinterwirth, Armin J., and Hudspeth, A. J.

Subjects
Quantitative Biology - Subcellular Processes, Physics - Biological Physics, Physics - Data Analysis, Statistics and Probability, Quantitative Biology - Quantitative Methods
Abstract

Direct gating of mechanoelectrical-transduction channels by mechanical force is a basic feature of hair cells that assures fast transduction and underpins the mechanical amplification of acoustic inputs. But the associated nonlinearity - the gating compliance - inevitably distorts signals. Because reducing distortion would make the ear a better detector, we sought mechanisms with that effect. Mimicking in vivo stimulation, we used stiff probes to displace individual hair bundles at physiological amplitudes and measured the coherence and phase of the relative stereociliary motions with a dual-beam differential interferometer. Although stereocilia moved coherently and in phase at the stimulus frequencies, large phase lags at the frequencies of the internally generated distortion products indicated dissipative relative motions. Tip links engaged these relative modes and decreased the coherence in both stimulated and free hair bundles. These results show that a hair bundle breaks into a highly dissipative serial arrangement of stereocilia at distortion frequencies, precluding their amplification., Comment: 33 pages in total, including the main article with one table and three figures, as well as the supplemental information that itself contains two figures

Published
2012
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20. Forces between clustered stereocilia minimize friction in the ear on a subnanometre scale

Author

Kozlov, Andrei S., Baumgart, Johannes, Risler, Thomas, Versteegh, Corstiaen P. C., and Hudspeth, A. J.

Subjects
Quantitative Biology - Subcellular Processes, Physics - Biological Physics, Physics - Computational Physics, Physics - Fluid Dynamics, Quantitative Biology - Quantitative Methods
Abstract

The detection of sound begins when energy derived from acoustic stimuli deflects the hair bundles atop hair cells. As hair bundles move, the viscous friction between stereocilia and the surrounding liquid poses a fundamental challenge to the ear's high sensitivity and sharp frequency selectivity. Part of the solution to this problem lies in the active process that uses energy for frequency-selective sound amplification. Here we demonstrate that a complementary part involves the fluid-structure interaction between the liquid within the hair bundle and the stereocilia. Using force measurement on a dynamically scaled model, finite-element analysis, analytical estimation of hydrodynamic forces, stochastic simulation and high-resolution interferometric measurement of hair bundles, we characterize the origin and magnitude of the forces between individual stereocilia during small hair-bundle deflections. We find that the close apposition of stereocilia effectively immobilizes the liquid between them, which reduces the drag and suppresses the relative squeezing but not the sliding mode of stereociliary motion. The obliquely oriented tip links couple the mechanotransduction channels to this least dissipative coherent mode, whereas the elastic horizontal top connectors stabilize the structure, further reducing the drag. As measured from the distortion products associated with channel gating at physiological stimulation amplitudes of tens of nanometres, the balance of forces in a hair bundle permits a relative mode of motion between adjacent stereocilia that encompasses only a fraction of a nanometre. A combination of high-resolution experiments and detailed numerical modelling of fluid-structure interactions reveals the physical principles behind the basic structural features of hair bundles and shows quantitatively how these organelles are adapted to the needs of sensitive mechanotransduction., Comment: 21 pages, including 3 figures. For supplementary information, please see the online version of the article at http://www.nature.com/nature

Published
2012
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21. Unidirectional mechanical amplification as a design principle for an active microphone

Author

Reichenbach, Tobias and Hudspeth, A. J.

Subjects
Physics - Instrumentation and Detectors, Physics - Biological Physics, Quantitative Biology - Quantitative Methods
Abstract

Amplification underlies the operation of many biological and engineering systems. Simple electrical, optical, and mechanical amplifiers are reciprocal: the backward coupling of the output to the input equals the forward coupling of the input to the output. Unidirectional amplifiers that occur often in electrical and optical systems are special non-reciprocal devices in which the output does not couple back to the input even though the forward coupling persists. Here we propose a scheme for unidirectional mechanical amplification that we utilize to construct an active microphone. We show that amplification improves the microphone's threshold for detecting weak signals and that unidirectionality prevents distortion., Comment: 4 pages, 3 figures plus supplementary information

Published
2011
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22. Dual contribution to amplification in the mammalian inner ear

Author

Reichenbach, Tobias and Hudspeth, A. J.

Subjects
Quantitative Biology - Tissues and Organs, Physics - Biological Physics
Abstract

The inner ear achieves a wide dynamic range of responsiveness by mechanically amplifying weak sounds. The enormous mechanical gain reported for the mammalian cochlea, which exceeds a factor of 4,000, poses a challenge for theory. Here we show how such a large gain can result from an interaction between amplification by low-gain hair bundles and a pressure wave: hair bundles can amplify both their displacement per locally applied pressure and the pressure wave itself. A recently proposed ratchet mechanism, in which hair-bundle forces do not feed back on the pressure wave, delineates the two effects. Our analytical calculations with a WKB approximation agree with numerical solutions., Comment: 4 pages, 4 figures

Published
2010
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23. A ratchet mechanism for amplification in low-frequency mammalian hearing

Author

Reichenbach, Tobias and Hudspeth, A. J.

Subjects
Quantitative Biology - Neurons and Cognition, Physics - Biological Physics
Abstract

The sensitivity and frequency selectivity of hearing result from tuned amplification by an active process in the mechanoreceptive hair cells. In most vertebrates the active process stems from the active motility of hair bundles. The mammalian cochlea exhibits an additional form of mechanical activity termed electromotility: its outer hair cells (OHCs) change length upon electrical stimulation. The relative contributions of these two mechanisms to the active process in the mammalian inner ear is the subject of intense current debate. Here we show that active hair-bundle motility and electromotility can together implement an efficient mechanism for amplification that functions like a ratchet: sound-evoked forces acting on the basilar membrane are transmitted to the hair bundles whereas electromotility decouples active hair-bundle forces from the basilar membrane. This unidirectional coupling can extend the hearing range well below the resonant frequency of the basilar membrane. It thereby provides a concept for low-frequency hearing that accounts for a variety of unexplained experimental observations from the cochlear apex, including the shape and phase behavior of apical tuning curves, their lack of significant nonlinearities, and the shape changes of threshold tuning curves of auditory nerve fibers along the cochlea. The ratchet mechanism constitutes a general design principle for implementing mechanical amplification in engineering applications., Comment: 6 pages, 4 figures, plus Supplementary Information. Animation available on the PNAS website (http://dx.doi.org/10.1073/pnas.0914345107).

Published
2010
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24. Coherent motion of stereocilia assures the concerted gating of hair-cell transduction channels

Author

Kozlov, Andrei S., Risler, Thomas, and Hudspeth, A. J.

Subjects
Quantitative Biology - Subcellular Processes, Physics - Biological Physics, Quantitative Biology - Quantitative Methods
Abstract

The hair cell's mechanoreceptive organelle, the hair bundle, is highly sensitive because its transduction channels open over a very narrow range of displacements. The synchronous gating of transduction channels also underlies the active hair-bundle motility that amplifies and tunes responsiveness. The extent to which the gating of independent transduction channels is coordinated depends on how tightly individual stereocilia are constrained to move as a unit. Using dual-beam interferometry in the bullfrog's sacculus, we found that thermal movements of stereocilia located as far apart as a bundle's opposite edges display high coherence and negligible phase lag. Because the mechanical degrees of freedom of stereocilia are strongly constrained, a force applied anywhere in the hair bundle deflects the structure as a unit. This feature assures the concerted gating of transduction channels that maximizes the sensitivity of mechanoelectrical transduction and enhances the hair bundle's capacity to amplify its inputs., Comment: 24 pages, including 6 figures, published in 2007

Published
2009
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28. Essential nonlinearities in hearing

Author

Eguiluz, V. M., Ospeck, M., Choe, Y., Hudspeth, A. J., and Magnasco, M. O.

Subjects
Nonlinear Sciences - Chaotic Dynamics
Abstract

Our hearing organ, the cochlea, evidently poises itself at a Hopf bifurcation to maximize tuning and amplification. We show that in this condition several effects are expected to be generic: compression of the dynamic range, infinitely shrap tuning at zero input, and generation of combination tones. These effects are "essentially" nonlinear in that they become more marked the smaller the forcing: there is no audible sound soft enough not to evoke them. All the well-documented nonlinear aspects of hearing therefore appear to be consequences of the same underlying mechanism., Comment: 4 pages, 3 figures

Published
2000
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