Albert Hudspeth

Q: What Schools Are Affiliated With Albert Hudspeth

Albert Hudspeth is affiliated with the following schools: California Institute of Technology, Rockefeller University, Stanford University, Cornell University, University of Texas Southwestern Medical Center, Harvard University

Albert Hudspeth's AcademicInfluence.com Rankings

Albert Hudspeth

Engineering

#2775

World Rank

#3752

Historical Rank

Biomedical Engineering

#90

World Rank

#91

Historical Rank

Applied Physics

#397

World Rank

#413

Historical Rank

Electrical Engineering

#548

World Rank

#604

Historical Rank

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Engineering

Albert Hudspeth's Degrees

Masters Electrical Engineering Stanford University

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Albert Hudspeth's Published Works

Number of citations in a given year to any of this author's works

Total number of citations to an author for the works they published in a given year. This highlights publication of the most important work(s) by the author

Published Works

Vanilloid Receptor–Related Osmotically Activated Channel (VR-OAC), a Candidate Vertebrate Osmoreceptor (2000) (1265)
Movement of microtubules by single kinesin molecules (1989) (854)
How the ear's works work (1989) (781)
Sensitivity, polarity, and conductance change in the response of vertebrate hair cells to controlled mechanical stimuli. (1977) (764)
Colocalization of ion channels involved in frequency selectivity and synaptic transmission at presynaptic active zones of hair cells (1990) (636)
Compliance of the hair bundle associated with gating of mechanoelectrical transduction channels in the Bullfrog's saccular hair cell (1988) (611)
Kinetics of the receptor current in bullfrog saccular hair cells (1983) (536)
Ionic basis of the receptor potential in a vertebrate hair cell (1979) (493)
Mechanical relaxation of the hair bundle mediates adaptation in mechanoelectrical transduction by the bullfrog's saccular hair cell. (1987) (388)
Making an Effort to Listen: Mechanical Amplification in the Ear (2008) (387)
Essential nonlinearities in hearing. (2000) (382)
Voltage- and ion-dependent conductances in solitary vertebrate hair cells (1983) (355)
The cellular basis of hearing: the biophysics of hair cells. (1985) (346)
Adaptation of mechanoelectrical transduction in hair cells of the bullfrog's sacculus (1987) (327)
Mutations in a novel cochlear gene cause DFNA9, a human nonsyndromic deafness with vestibular dysfunction (1998) (323)
Active hair-bundle movements can amplify a hair cell's response to oscillatory mechanical stimuli. (1999) (322)
Kinetic analysis of voltage‐ and ion‐dependent conductances in saccular hair cells of the bull‐frog, Rana catesbeiana. (1988) (319)
Extracellular current flow and the site of transduction by vertebrate hair cells (1982) (316)
Pulling springs to tune transduction: Adaptation by hair cells (1994) (314)
Spontaneous Oscillation by Hair Bundles of the Bullfrog's Sacculus (2003) (274)
Putting ion channels to work: mechanoelectrical transduction, adaptation, and amplification by hair cells. (2000) (262)
RIM Binding Proteins (RBPs) Couple Rab3-Interacting Molecules (RIMs) to Voltage-Gated Ca2+ Channels (2002) (260)
Blockage of the transduction channels of hair cells in the bullfrog's sacculus by aminoglycoside antibiotics (1989) (257)
Integrating the active process of hair cells with cochlear function (2014) (256)
Negative hair-bundle stiffness betrays a mechanism for mechanical amplification by the hair cell. (2000) (253)
A model for electrical resonance and frequency tuning in saccular hair cells of the bull‐frog, Rana catesbeiana. (1988) (251)
DIRECTIONAL SENSITIVITY OF INDIVIDUAL VERTEBRATE HAIR CELLS TO CONTROLLED DEFLECTION OF THEIR HAIR BUNDLES * (1981) (235)
Mechanoelectrical transduction by hair cells. (1988) (234)
Plasma Membrane Ca2+-ATPase Extrudes Ca2+from Hair Cell Stereocilia (1998) (225)
How Hearing Happens (1997) (224)
Ca2+ current–driven nonlinear amplification by the mammalian cochlea in vitro (2005) (223)
Comparison of a hair bundle's spontaneous oscillations with its response to mechanical stimulation reveals the underlying active process (2001) (222)
Mechanical amplification of stimuli by hair cells (1997) (221)
Response latency of vertebrate hair cells. (1979) (218)
Distribution of Ca2+-Activated K+ Channel Isoforms along the Tonotopic Gradient of the Chicken's Cochlea (1997) (212)
A model for amplification of hair-bundle motion by cyclical binding of Ca2+ to mechanoelectrical-transduction channels. (1998) (210)
The transduction channel of hair cells from the bull‐frog characterized by noise analysis. (1986) (204)
Clustering of Ca2+ channels and Ca(2+)-activated K+ channels at fluorescently labeled presynaptic active zones of hair cells. (1994) (197)
Stereocilia mediate transduction in vertebrate hair cells (auditory system/cilium/vestibular system). (1979) (195)
Compressive nonlinearity in the hair bundle's active response to mechanical stimulation (2001) (193)
Mechanoelectrical transduction by hair cells in the acousticolateralis sensory system. (1983) (179)
Hair cells: transduction, tuning, and transmission in the inner ear. (1988) (177)
Gap junctions between electrotonically coupled cells in tissue culture and in brown fat. (1971) (177)
Analysis of the microphonic potential of the bullfrog's sacculus (1983) (176)
Stereocilia mediate transduction in vertebrate hair cells (1979) (175)
Zebrafish TRPA1 Channels Are Required for Chemosensation But Not for Thermosensation or Mechanosensory Hair Cell Function (2008) (173)
Transfer characteristics of the hair cell's afferent synapse. (2006) (168)
Rapid, Active Hair Bundle Movements in Hair Cells from the Bullfrog’s Sacculus (1996) (166)
A two-step mechanism underlies the planar polarization of regenerating sensory hair cells (2006) (159)
The physics of hearing: fluid mechanics and the active process of the inner ear (2014) (155)
Localization of the hair cell's transduction channels at the hair bundle's top by iontophoretic application of a channel blocker (1991) (153)
Directional cell migration establishes the axes of planar polarity in the posterior lateral-line organ of the zebrafish. (2004) (150)
Detection of Ca2+ entry through mechanosensitive channels localizes the site of mechanoelectrical transduction in hair cells. (1995) (150)
Ultrastructural correlates of mechanoelectrical transduction in hair cells of the bullfrog's internal ear. (1990) (149)
Gating-spring models of mechanoelectrical transduction by hair cells of the internal ear. (1995) (149)
The Unitary Event Underlying Multiquantal EPSCs at a Hair Cell's Ribbon Synapse (2009) (146)
Identification of a 120 kd hair-bundle myosin located near stereociliary tips (1993) (145)
Expression and phylogeny of claudins in vertebrate primordia (2001) (138)
A micromechanical contribution to cochlear tuning and tonotopic organization. (1983) (133)
Regulation of Free Ca2+ Concentration in Hair-Cell Stereocilia (1998) (128)
Auditory illusions and the single hair cell (1993) (125)
The intercellular junctional complexes of retinal pigment epithelia. (1973) (125)
Vitamin A deprivation and Drosophila photopigments (1977) (117)
Direct interaction with a nuclear protein and regulation of gene silencing by a variant of the Ca2+-channel β4 subunit (2002) (115)
Displacement-clamp measurement of the forces exerted by gating springs in the hair bundle. (1993) (109)
A critique of the critical cochlea: Hopf--a bifurcation--is better than none. (2010) (108)
Molecular Anatomy of the Hair Cell's Ribbon Synapse (2010) (107)
Predominance of the alpha1D subunit in L-type voltage-gated Ca2+ channels of hair cells in the chicken's cochlea. (1997) (104)
Mechanical properties of sensory hair bundles are reflected in their Brownian motion measured with a laser differential interferometer. (1989) (103)
Parvalbumin 3 is an Abundant Ca2+ Buffer in Hair Cells (2002) (100)
Coherent motion of stereocilia assures the concerted gating of hair-cell transduction channels (2009) (99)
Chemiluminescence detection of proteins from single cells. (1991) (99)
High-purity isolation of bullfrog hair bundles and subcellular and topological localization of constituent proteins (1991) (98)
Molecular markers for cell types of the inner ear and candidate genes for hearing disorders. (1998) (97)
Supernumerary neuromasts in the posterior lateral line of zebrafish lacking peripheral glia. (2005) (93)
COEXISTENCE OF GAP AND SEPTATE JUNCTIONS IN AN INVERTEBRATE EPITHELIUM (1971) (92)
The selectivity of the hair cell's mechanoelectrical-transduction channel promotes Ca2+ flux at low Ca2+ concentrations. (1997) (92)
Specificity of Afferent Synapses onto Plane-Polarized Hair Cells in the Posterior Lateral Line of the Zebrafish (2008) (90)
Hair-bundle movements elicited by transepithelial electrical stimulation of hair cells in the sacculus of the bullfrog (2003) (88)
Effects of extracellular Ca2+ concentration on hair-bundle stiffness and gating-spring integrity in hair cells. (1997) (88)
How the ear's works work: mechanoelectrical transduction and amplification by hair cells. (2005) (88)
Mechanical responses of the organ of corti to acoustic and electrical stimulation in vitro. (2005) (87)
Sensory systems (1998) (86)
NOVA2-mediated RNA regulation is required for axonal pathfinding during development (2016) (84)
Mechanical stimulation and micromanipulation with piezoelectric bimorph elements (1980) (84)
The transmembrane inner ear (Tmie) protein is essential for normal hearing and balance in the zebrafish (2009) (81)
Dynamic gene expression by putative hair-cell progenitors during regeneration in the zebrafish lateral line (2014) (78)
Hair-bundle stiffness dominates the elastic reactance to otolithic-membrane shear (1993) (75)
Hair cell-specific splicing of mRNA for the alpha1D subunit of voltage-gated Ca2+ channels in the chicken's cochlea. (1997) (75)
The ionic channels of a vertebrate hair cell (1986) (73)
Mutation of the zebrafish choroideremia gene encoding Rab escort protein 1 devastates hair cells. (2004) (71)
Hair-bundle mechanics and a model for mechanoelectrical transduction by hair cells. (1992) (71)
Myosin-I nomenclature (2001) (70)
Radixin is a constituent of stereocilia in hair cells. (2004) (69)
The Hair Cells of the Inner Ear (1983) (68)
Adenine nucleoside diphosphates block adaptation of mechanoelectrical transduction in hair cells. (1993) (65)
Calmodulin controls adaptation of mechanoelectrical transduction by hair cells of the bullfrog's sacculus. (1996) (65)
The Spatial Pattern of Cochlear Amplification (2012) (63)
Calmodulin and calmodulin-binding proteins in hair bundles. (1993) (63)
A nonsense mutation in the gene encoding a zebrafish myosin VI isoform causes defects in hair-cell mechanotransduction. (2004) (60)
The entry and clearance of Ca2+ at individual presynaptic active zones of hair cells from the bullfrog's sacculus. (1996) (60)
Analysis and functional evaluation of the hair-cell transcriptome (2007) (59)
Forces between clustered stereocilia minimize friction in the ear on a subnanometre scale (2011) (57)
Modeling the active process of the cochlea: phase relations, amplification, and spontaneous oscillation. (1995) (53)
Effects of cochlear loading on the motility of active outer hair cells (2013) (53)
Morphology and responses to light of the somata, axons, and terminal regions of individual photoreceptors of the giant barnacle (1977) (52)
The diverse effects of mechanical loading on active hair bundles (2012) (51)
Adaptive shift in the domain of negative stiffness during spontaneous oscillation by hair bundles from the internal ear. (2005) (51)
Establishment of tight junctions between epithelial cells. (1975) (49)
A novel conserved cochlear gene, OTOR: identification, expression analysis, and chromosomal mapping. (2000) (48)
Highly Specific Alternative Splicing of Transcripts Encoding BK Channels in the Chicken's Cochlea Is a Minor Determinant of the Tonotopic Gradient (2010) (47)
A ratchet mechanism for amplification in low-frequency mammalian hearing (2010) (47)
Elasticity of individual protocadherin 15 molecules implicates tip links as the gating springs for hearing (2019) (44)
Passive signal propagation and membrane properties in median photoreceptors of the giant barnacle (1977) (44)
Rearrangements between differentiating hair cells coordinate planar polarity and the establishment of mirror symmetry in lateral-line neuromasts (2012) (42)
Control of a hair bundle’s mechanosensory function by its mechanical load (2015) (41)
Small-molecule inhibition of Lats kinases may promote Yap-dependent proliferation in postmitotic mammalian tissues (2020) (41)
To fuse or not to fuse? (1993) (39)
Effects of salicylates and aminoglycosides on spontaneous otoacoustic emissions in the Tokay gecko. (2000) (39)
Frequency Tuning and Ionic Conductances in Hair Cells of the Bullfrog’s Sacculus (1938) (38)
RIM Binding Proteins ( RBPs ) Couple Rab 3-Interacting Molecules ( RIMs ) to Voltage-Gated Ca 2 (2002) (38)
Molecular cloning of a myosin I beta isozyme that may mediate adaptation by hair cells of the bullfrog's internal ear. (1994) (37)
Interactions between Hair Cells Shape Spontaneous Otoacoustic Emissions in a Model of the Tokay Gecko's Cochlea (2010) (37)
Vital staining of specific monoamine-containing cells in the leech nervous system (2004) (37)
Association of β-catenin with the α-subunit of neuronal large-conductance Ca2+-activated K+ channels (2004) (37)
SoxC transcription factors are essential for the development of the inner ear (2015) (37)
Transgenic labeling of hair cells in the zebrafish acousticolateralis system. (2010) (36)
Waves on Reissner's membrane: a mechanism for the propagation of otoacoustic emissions from the cochlea. (2012) (34)
The Hair Cell as a Presynaptic Terminal a (1991) (34)
Contribution of active hair-bundle motility to nonlinear amplification in the mammalian cochlea (2012) (32)
A search for factors specifying tonotopy implicates DNER in hair-cell development in the chick's cochlea. (2011) (32)
The Ear's Gears: Mechanoelectrical Transduction by Hair Cells (1994) (32)
Transduction and tuning by vertebrate hair cells (1983) (31)
Daple coordinates organ-wide and cell-intrinsic polarity to pattern inner-ear hair bundles (2017) (31)
The Structural and Functional Differentiation of Hair Cells in a Lizard's Basilar Papilla Suggests an Operational Principle of Amniote Cochleas (2007) (30)
Mechanoelectrical transduction by hair cells of the bullfrog's sacculus. (1989) (30)
Connectomics of the zebrafish's lateral-line neuromast reveals wiring and miswiring in a simple microcircuit (2018) (30)
Expression patterns of the RGS9-1 anchoring protein R9AP in the chicken and mouse suggest multiple roles in the nervous system (2003) (29)
Cytoarchitectonic mapping by microdensitometry. (1976) (29)
Three-dimensional Architecture of Hair-bundle Linkages Revealed by Electron-microscopic Tomography (2008) (28)
Mutation of the atrophin2 gene in the zebrafish disrupts signaling by fibroblast growth factor during development of the inner ear. (2006) (27)
Efferent Control of the Electrical and Mechanical Properties of Hair Cells in the Bullfrog's Sacculus (2010) (27)
A new era for neurons (1988) (26)
Anomalous Brownian motion discloses viscoelasticity in the ear’s mechanoelectrical-transduction apparatus (2012) (26)
Identification of Bifurcations from Observations of Noisy Biological Oscillators (2016) (26)
Reaction–diffusion model of hair-bundle morphogenesis (2014) (26)
A hydrodynamic sensory antenna used by killifish for nocturnal hunting (2011) (25)
The steady-state response of the cerebral cortex to the beat of music reflects both the comprehension of music and attention (2015) (25)
Controlled bending of high-resistance glass microelectrodes. (1978) (25)
Direct mechanical stimulation of tip links in hair cells through DNA tethers (2016) (24)
Notch-Mediated Determination of Hair-Bundle Polarity in Mechanosensory Hair Cells of the Zebrafish Lateral Line (2019) (24)
Auditory neuroscience: development, transduction, and integration. (2000) (24)
Correlation Between the Kinetic Properties of Ionic Channels and the Frequency of Membrane-Potential Resonance in Hair Cells of the Bullfrog (1986) (23)
Elastic force restricts growth of the murine utricle (2017) (23)
Activity-independent specification of synaptic targets in the posterior lateral line of the larval zebrafish (2009) (21)
ATPase activity of myosin in hair bundles of the bullfrog's sacculus. (1997) (20)
Dual contribution to amplification in the mammalian inner ear. (2010) (19)
Calcium Ions Promote Rapid Mechanically Evoked Movements of Hair Bundles (1990) (19)
Association of beta-catenin with the alpha-subunit of neuronal large-conductance Ca2+-activated K+ channels. (2004) (19)
Characterization of fluo-3 labelling of dense bodies at the hair cell's presynaptic active zone (1996) (17)
The recovery of local transepithelial resistance following single-cell lesions. (1982) (17)
Models for mechanoelectrical transduction by hair cells. (1985) (16)
Transneuronal transport in the auditory system of the cat (1978) (15)
Homeostatic enhancement of sensory transduction (2017) (15)
An In Toto Approach to Dissecting Cellular Interactions in Complex Tissues. (2017) (14)
Modeling the resonant release of synaptic transmitter by hair cells as an example of biological oscillators with cooperative steps (2010) (14)
Mechanochemical symmetry breaking during morphogenesis of lateral-line sensory organs (2020) (12)
Thermal Excitation of the Mechanotransduction Apparatus of Hair Cells (2018) (12)
Frequency-Selective Exocytosis by Ribbon Synapses of Hair Cells in the Bullfrog's Amphibian Papilla (2012) (12)
Unidirectional mechanical amplification as a design principle for an active microphone. (2011) (11)
The Auditory-Brainstem Response to Continuous, Non-repetitive Speech Is Modulated by the Speech Envelope and Reflects Speech Processing (2016) (11)
Identification with a recombinant antibody of an inner-ear cytokeratin, a marker for hair-cell differentiation. (2000) (10)
Volterra-series approach to stochastic nonlinear dynamics: Linear response of the Van der Pol oscillator driven by white noise. (2019) (10)
Bilateral Spontaneous Otoacoustic Emissions Show Coupling between Active Oscillators in the Two Ears (2018) (10)
Imaging electrical resonance in hair cells (2011) (8)
Discrimination of Low-Frequency Tones Employs Temporal Fine Structure (2012) (7)
Fast, Automated Implementation of Temporally Precise Blind Deconvolution of Multiphasic Excitatory Postsynaptic Currents (2012) (7)
Two deaf mice, two deaf mice… (1998) (7)
Gating Compliance, a Reduction in Hair-Bundle Stiffness Associated with the Gating of Transduction Channels in Hair Cells from the Bullfrog’s Sacculus (1989) (6)
Volterra-series approach to stochastic nonlinear dynamics: The Duffing oscillator driven by white noise. (2019) (6)
Relative stereociliary motion in a hair bundle opposes amplification at distortion frequencies (2012) (6)
Divalent counterions tether membrane-bound carbohydrates to promote the cohesion of auditory hair bundles. (2011) (6)
Mechanical Frequency Tuning by Sensory Hair Cells, the Receptors and Amplifiers of the Inner Ear (2021) (5)
SnapShot: Auditory Transduction (2013) (5)
Hearing and Deafness (2000) (5)
Chemomechanical regulation of myosin Ic cross-bridges: Deducing the elastic properties of an ensemble from single-molecule mechanisms (2017) (5)
How the ear's works work: mechanoelectrical transduction and amplification by hair cells of the internal ear. (2001) (5)
The contribution of transduction channels and adaptation motors to the hair cell’s active process (2003) (4)
The hair cells of the inner ear. They are exquisitely sensitive transducers that in human beings mediate the senses of hearing and balance. A tiny force applied to the top of the cell produces an electrical signal at the bottom. (1983) (4)
The elasticity of individual protocadherin 15 molecules implicates cadherins as the gating springs for hearing (2018) (4)
Rapid mechanical stimulation of inner-ear hair cells by photonic pressure (2021) (4)
Notch-Mediated Polarity Decisions in Mechanosensory Hair Cells (2018) (4)
Modeling Active Non-Markovian Oscillations. (2022) (4)
Confocal-microscopic visualization of membrane addition during synaptic exocytosis at presynaptic active zones of hair cells. (1996) (4)
A library of bacteriophage-displayed antibody fragments directed against proteins of the inner ear. (2000) (4)
AN EXPERIMENTAL PREPARATION OF THE MAMMALIAN COCHLEA THAT DISPLAYS COMPRESSIVE NONLINEARITY IN VITRO (2006) (4)
A New Twist on Tip Links (2018) (3)
Fast recovery of disrupted tip links induced by mechanical displacement of hair bundles (2020) (3)
A Ratchet Mechanism for Low-Frequency Hearing in Mammals (2010) (3)
Measurement of hindered diffusion in complex geometries for high-speed studies of single-molecule forces (2021) (3)
Sinusoidal-signal detection by active, noisy oscillators on the brink of self-oscillation (2018) (3)
Three-dimensional Organotypic Cultures of Vestibular and Auditory Sensory Organs. (2018) (3)
Unidirectional Amplification as a Mechanism for Low‐Frequency Hearing in Mammals (2011) (3)
Hair Cells, Sensory Transduction (1988) (2)
Micromechanical properties of the alligator lizard's basilar papilla contribute to frequency tuning (1986) (2)
Vibrational modes and damping in the cochlear partition (2015) (2)
Role of YAP in early ectodermal specification and a Huntington's Disease model of human neurulation (2022) (2)
Otoacoustic Emission through Waves on Reissner's Membrane (2012) (2)
The ionic basis of electrical resonance in hair cells of the bullfrog's sacculus (1986) (2)
Depicting pseudotime-lagged causality across single-cell trajectories for accurate gene-regulatory inference (2022) (1)
Connectomics of the zebrafish’s lateral-line neuromast reveals wiring and miswiring in a simple microcircuit (2018) (1)
Author response: NOVA2-mediated RNA regulation is required for axonal pathfinding during development (2016) (1)
Symmetry breaking during morphogenesis of a mechanosensory organ (2019) (1)
Role of YAP in early ectodermal specification and a Huntington’s Disease model of human neurulation (2021) (1)
Introduction Auditory neuroscience : Development , transduction , and integration (2000) (1)
Frequency decoding of periodically timed action potentials through distinct activity patterns in a random neural network (2012) (1)
Ensemble-variance analysis of transduction in saccular hair cells (1986) (1)
Mechanical AJ Hudspeth amplification of stimuli by hair cells (2001) (1)
Characterization of active hair-bundle motility by a mechanical-load clamp (2015) (1)
Editorial overview (1994) (1)
Molecular description of cSlo, a Ca-2+-activated K+ channel expressed in the chickens brain and internal ear (1997) (1)
Transforming Difficult Conversations into Learning Conversations (2019) (0)
The mechanoelectrical-transduction channel of the bullfrogs saccular hair cell is highly Ca-2+-selective (1997) (0)
Characterization of active hair-bundle motion: a source for auditory-organ amplificatory phenomena? (1995) (0)
Violation of the fluctuation-response relation from a linear model of hair bundle oscillations (2022) (0)
Motile Hair Cells Distinguish Mechanical Signals from Noise Best When They Operate on the Brink of Spontaneous Oscillation (2018) (0)
Acoustic Coupling between Active Oscillators Allows for their Synchronization and Explains Identical-Frequency Sounds Emitted from the Two Ears (2020) (0)
Anomalous Brownian motion and viscoelasticity of the ear's mechanoelectrical transducer (2009) (0)
Signal detection by active, noisy hair bundles (2018) (0)
13-P053 Signaling factors in the specification of the cochlear tonotopic gradient (2009) (0)
Analysis of alkaline phosphatase expression in the regenerating zebrafish lateral line (2011) (0)
Cytoarchitectoni c mappingbymicrodensitometry (1976) (0)
Stimulation of hair cells with ultraviolet light (2018) (0)
The Ear Has Three Functional Parts External Ear (2009) (0)
TheUnitaryEventUnderlyingMultiquantalEPSCsataHair Cell'sRibbonSynapse (2009) (0)
The auditory-brainstem response to continuous , 1 non-repetitive speech is modulated by the speech 2 envelope and reflects speech processing 3 Running title : Auditory-brainstem response to continuous , non-repetitive 4 speech 5 (2016) (0)
Author response: Direct mechanical stimulation of tip links in hair cells through DNA tethers (2016) (0)
Author response: Elastic force restricts growth of the murine utricle (2017) (0)
Measurement of hindered diffusion in complex geometries for high-speed single-molecule experiments (2020) (0)
The Energetic Ear (2015) (0)
Regulation of Elastically Coupled Myosin IC Molecules (2017) (0)
Cytoarchitectonic mapping by microdensitometry ( visual cortex / monkey / computer ) (0)
Molecular cloning of a myosin 113 isozyme that may mediate adaptation by hair cells of the bullfrog ' s internal ear ( auditory system / hair bundle / motor molecule / vestibular system ) (0)
HOW THE EAR'S WORKS WORK: TRANSDUCTION AND AMPLIFICATION BY HAIR CELLS (2001) (0)
Highly Speciﬁc Alternative Splicing of Transcripts Encoding BK Channels in the Chicken’s Cochlea Is a Minor Determinant of the Tonotopic Gradient (cid:1) † (2010) (0)
Single-Molecule Mechanics of the Molecular Spring that Underlies Hearing (2019) (0)
Emission of sound from the mammalian inner ear (2013) (0)
Mechanochemical symmetry breaking during morphogenesis of lateral-line sensory organs (2020) (0)
Semaphorin7A patterns neural circuitry in the lateral line of the zebrafish (2022) (0)
Mechanoelectrical transduction by vertebrate hair cells (1988) (0)
Homeostatic enhancement of active mechanotransduction (2018) (0)
Friction and Adhesion in the Hair Bundle's Glycocalyx (2010) (0)
Editorial overview (1991) (0)
An Active Mechanism for Signal Detection in the Mammalian Ear (2012) (0)
Fluctuation theory in space and time: White noise in reaction-diffusion models of morphogenesis (2018) (0)
Sensory systems (1992) (0)
Supporting Information for “ Homeostatic Enhancement of Sensory Transduction ” (2017) (0)
Synchronization of spontaneous otoacoustic emissions in the tokay gecko (2018) (0)
Manipulation with Magnetic Tweezers of Mechanosensitive Ion Channels and Adaptation Motors in Hair Cells of the Inner Ear (2015) (0)
Using light to study sound: Stimulating hair cells with photonic pressure. (2023) (0)
Damping Properties of the Hair Bundle (2011) (0)
Author response: Connectomics of the zebrafish's lateral-line neuromast reveals wiring and miswiring in a simple microcircuit (2018) (0)
Sensory systems (2000) (0)
Development of an improved inhibitor of Lats kinases to promote regeneration of mammalian organs (2022) (0)
How hearing happens: mechanoelectrical transduction and amplification by hair cells of the internal ear (2001) (0)
Three-dimensional architecture of hair-cell linkages as revealed by electron-microscopic tomography (2006) (0)
High‐Frequency Power Gain in the Mammalian Cochlea (2011) (0)
Motors and Forces from a Theoretical Perspective (2018) (0)

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Published Works

What Schools Are Affiliated With Albert Hudspeth?

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