Your search keyword '"Richard D. Rabbitt"' showing total 130 results

1. Using macular velocity measurements to relate parameters of bone conduction to vestibular compound action potential responses

Author

Christopher J. Pastras, Ian S. Curthoys, Richard D. Rabbitt, and Daniel J. Brown

Subjects

Medicine, Science

Abstract

Abstract To examine mechanisms responsible for vestibular afferent sensitivity to transient bone conducted vibration, we performed simultaneous measurements of stimulus-evoked vestibular compound action potentials (vCAPs), utricular macula velocity, and vestibular microphonics (VMs) in anaesthetized guinea pigs. Results provide new insights into the kinematic variables of transient motion responsible for triggering mammalian vCAPs, revealing synchronized vestibular afferent responses are not universally sensitive to linear jerk as previously thought. For short duration stimuli (

Published

2023

2. Stem cell-derived brain organoids for controlled studies of transcranial neuromodulation

Author

Jan Kubanek, Matthew Wilson, Richard D. Rabbitt, Celeste J. Armstrong, Alexander J. Farley, H. M. Arif Ullah, and Alex Shcheglovitov

Subjects

Intracranial, Recordings, Skull, Focused ultrasound, Rhythms, Durable, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Transcranial neuromodulation methods have the potential to diagnose and treat brain disorders at their neural source in a personalized manner. However, it has been difficult to investigate the direct effects of transcranial neuromodulation on neurons in human brain tissue. Here, we show that human brain organoids provide a detailed and artifact-free window into neuromodulation-evoked electrophysiological effects. We derived human cortical organoids from induced pluripotent stem cells and implanted 32-channel electrode arrays. Each organoid was positioned in the center of the human skull and subjected to low-intensity transcranial focused ultrasound. We found that ultrasonic stimuli modulated network activity in the gamma and delta ranges of the frequency spectrum. The effects on the neural networks were a function of the ultrasound stimulation frequency. High gamma activity remained elevated for at least 20 minutes following stimulation offset. This approach is expected to provide controlled studies of the effects of ultrasound and other transcranial neuromodulation modalities on human brain tissue.

Published

2023

3. A mathematical model for mechanical activation and compound action potential generation by the utricle in response to sound and vibration

Author

Christopher J. Pastras, Nastaran Gholami, Skyler Jennings, Hong Zhu, Wu Zhou, Daniel J. Brown, Ian S. Curthoys, and Richard D. Rabbitt

Subjects

vestibular, vestibular evoked miogenic potentials, vestibular short-latency evoked potential, action potential timing, biomechanics, Neurology. Diseases of the nervous system, RC346-429

Abstract

IntroductionCalyx bearing vestibular afferent neurons innervating type I hair cells in the striolar region of the utricle are exquisitely sensitive to auditory-frequency air conducted sound (ACS) and bone conducted vibration (BCV). Here, we present experimental data and a mathematical model of utricular mechanics and vestibular compound action potential generation (vCAP) in response to clinically relevant levels of ACS and BCV. Vibration of the otoconial layer relative to the sensory epithelium was simulated using a Newtonian two-degree-of-freedom spring-mass-damper system, action potential timing was simulated using an empirical model, and vCAPs were simulated by convolving responses of the population of sensitive neurons with an empirical extracellular voltage kernel. The model was validated by comparison to macular vibration and vCAPs recorded in the guinea pig, in vivo.ResultsTransient stimuli evoked short-latency vCAPs that scaled in magnitude and timing with hair bundle mechanical shear rate for both ACS and BCV. For pulse BCV stimuli with durations 0.9 ms the magnitude increased in proportion to temporal bone jerk. Once validated using ACS and BCV data, the model was applied to predict blast-induced hair bundle shear, with results predicting acute mechanical damage to bundles immediately upon exposure.DiscussionResults demonstrate the switch from linear acceleration to linear jerk as the adequate stimulus arises entirely from mechanical factors controlling the dynamics of sensory hair bundle deflection. The model describes the switch in terms of the mechanical natural frequencies of vibration, which vary between species based on morphology and mechanical factors.

Published

2023

4. ATP and ACh Evoked Calcium Transients in the Neonatal Mouse Cochlear and Vestibular Sensory Epithelia

Author

Richard D. Rabbitt and Holly A. Holman

Subjects

development, supporting cell, hair cell, purinergic, cholinergic, sensory cell, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Hair cells in the mammalian inner ear sensory epithelia are surrounded by supporting cells which are essential for function of cochlear and vestibular systems. In mice, support cells exhibit spontaneous intracellular Ca2+ transients in both auditory and vestibular organs during the first postnatal week before the onset of hearing. We recorded long lasting (>200 ms) Ca2+ transients in cochlear and vestibular support cells in neonatal mice using the genetic calcium indicator GCaMP5. Both cochlear and vestibular support cells exhibited spontaneous intracellular Ca2+ transients (GCaMP5 ΔF/F), in some cases propagating as waves from the apical (endolymph facing) to the basolateral surface with a speed of ∼25 μm per second, consistent with inositol trisphosphate dependent calcium induced calcium release (CICR). Acetylcholine evoked Ca2+ transients were observed in both inner border cells in the cochlea and vestibular support cells, with a larger change in GCaMP5 fluorescence in the vestibular support cells. Adenosine triphosphate evoked robust Ca2+ transients predominantly in the cochlear support cells that included Hensen’s cells, Deiters’ cells, inner hair cells, inner phalangeal cells and inner border cells. A Ca2+ event initiated in one inner border cells propagated in some instances longitudinally to neighboring inner border cells with an intercellular speed of ∼2 μm per second, and decayed after propagating along ∼3 cells. Similar intercellular propagation was not observed in the radial direction from inner border cell to inner sulcus cells, and was not observed between adjacent vestibular support cells.

Published

2021

5. Developmental GAD2 Expression Reveals Progenitor-like Cells with Calcium Waves in Mammalian Crista Ampullaris

Author

Holly A. Holman, Yong Wan, and Richard D. Rabbitt

Subjects

Audiology, Molecular Biology, Developmental Neuroscience, Stem Cells Research, Science

Abstract

Summary: Sense of motion, spatial orientation, and balance in vertebrates relies on sensory hair cells in the inner ear vestibular system. Vestibular supporting cells can regenerate hair cells that are lost from aging, ototoxicity, and trauma, although not all factors or specific cell types are known. Here we report a population of GAD2-positive cells in the mouse crista ampullaris and trace GAD2 progenitor-like cells that express pluripotent transcription factors SOX2, PROX1, and CTBP2. GAD2 progenitor-like cells organize into rosettes around a central branched structure in the eminentia cruciatum (EC) herein named the EC plexus. GCaMP5G calcium indicator shows spontaneous and acetylcholine-evoked whole-cell calcium waves in neonatal and adult mice. We present a hypothetical model that outlines the lineage and potential regenerative capacity of GAD2 cells in the mammalian vestibular neuroepithelium.

Published

2020

6. Biomechanics of Third Window Syndrome

Author

Marta M. Iversen and Richard D. Rabbitt

Subjects

biomechanics, canal dehiscence, superior semicircular canal dehiscence, third window, vestibular, dizziness, Neurology. Diseases of the nervous system, RC346-429

Abstract

Third window syndrome describes a set of vestibular and auditory symptoms that arise when a pathological third mobile window is present in the bony labyrinth of the inner ear. The pathological mobile window (or windows) adds to the oval and round windows, disrupting normal auditory and vestibular function by altering biomechanics of the inner ear. The most commonly occurring third window syndrome arises from superior semicircular canal dehiscence (SSCD), where a section of bone overlying the superior semicircular canal is absent or thinned (near-dehiscence). The presentation of SSCD syndrome is well characterized by clinical audiological and vestibular tests. In this review, we describe how the third compliant window introduced by a SSCD alters the biomechanics of the inner ear and thereby leads to vestibular and auditory symptoms. Understanding the biomechanical origins of SSCD further provides insight into other third window syndromes and the potential of restoring function or reducing symptoms through surgical repair.

Published

2020

7. Spontaneous and Acetylcholine Evoked Calcium Transients in the Developing Mouse Utricle

Author

Holly A. Holman, Lauren A. Poppi, Micah Frerck, and Richard D. Rabbitt

Subjects

utricle, calcium, hair cell, supporting cell, neuron, GCaMP5G, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Spontaneous calcium transients are present during early postnatal development in the mouse retina and cochlea, and play an important role in maturation of the sensory organs and neural circuits in the central nervous system (CNS). It is not known whether similar calcium transients occur during postnatal development in the vestibular sensory organs. Here we demonstrate spontaneous intracellular calcium transients in sensory hair cells (HCs) and supporting cells (SCs) in the murine utricular macula during the first two postnatal weeks. Calcium transients were monitored using a genetically encoded calcium indicator, GCaMP5G (G5), at 100 ms-frame−1 in excised utricle sensory epithelia, including HCs, SCs, and neurons. The reporter line expressed G5 and tdTomato (tdT) in a Gad2-Cre dependent manner within a subset of utricular HCs, SCs and neurons. Kinetics of the G5 reporter limited temporal resolution to calcium events lasting longer than 200 ms. Spontaneous calcium transients lasting 1-2 s were observed in the expressing population of HCs at birth and slower spontaneous transients lasting 10-30 s appeared in SCs by P3. Beginning at P5, calcium transients could be modulated by application of the efferent neurotransmitter acetylcholine (ACh). In mature mice, calcium transients in the utricular macula occurred spontaneously, had a duration 1-2 s, and could be modulated by the exogenous application of acetylcholine (ACh) or muscarine. Long-lasting calcium transients evoked by ACh in mature mice were blocked by atropine, consistent with previous reports describing the role of muscarinic receptors expressed in calyx bearing afferents in efferent control of vestibular sensation. Large spontaneous and ACh evoked transients were reversibly blocked by the inositol trisphosphate receptor (IP3R) antagonist aminoethoxydiphenyl borate (2-APB). Results demonstrate long-lasting calcium transients are present in the utricular macula during the first postnatal week, and that responses to ACh mature over this same time period.

Published

2019

8. Otolith Membrane Herniation, not Semicircular Canal Duct Dilation, Is Associated with Decreased Caloric Responses in Ménière’s Disease

Author

Leo L. Shen, Nicholas S. Andresen, Divya A. Chari, Jacob M. Pogson, Amanda M. Lauer, Richard D. Rabbitt, John P. Carey, Felipe Santos, and Bryan K. Ward

Subjects

Otorhinolaryngology, Sensory Systems

Published

2022

9. Evidence that ultrafast non-quantal transmission underlies short-latency vestibular evoked potentials

Author

Christopher J. Pastras, Ian S. Curthoys, Mohsen Asadnia, David McAlpine, Richard D. Rabbitt, and Daniel J. Brown

Abstract

Amniotes evolved a unique calyceal postsynaptic terminal in the vestibular organs of the inner ear that underpins quantal and non-quantal transmission at the synapse of sensory hair cells and vestibular afferent neurons. The non-quantal component is of particular interest as it includes an ultrafast synaptic current thought to underlie the exquisite synchronization of action potentials in vestibular afferent fibres to dynamic stimuli such as sound and vibration. Here we demonstrate evidence that non-quantal transmission is responsible for short latency vestibular evoked potentials (vCAPs) in the guinea pig utricle. We first show that, unlike auditory nerve responses which are completely abolished, vCAPs are insensitive to local administration of the AMPA receptor agonist CNQX. Moreover, latency comparisons between presynaptic hair cell and postsynaptic neural responses reveal that the vCAP occurs without measurable synaptic delay. Finally, using a paired-pulse stimulus designed to deplete the readily releasable pool of synaptic vesicles in hair cells, we reveal that forward masking is lacking in vestibular responses, compared to the equivalent cochlear responses. Our data support the hypothesis that the fast component of non-quantal transmission at calyceal synapses is indefatigable and responsible for ultrafast responses of vestibular organs evoked by transient stimulation.SignificanceThe mammalian vestibular system drives some of the fastest reflex pathways in the nervous system, ensuring stable gaze and postural control for locomotion on land. To achieve this, terrestrial amniotes evolved a large, unique calyx afferent terminal which completely envelopes one or more pre-synaptic vestibular hair cells, which transmits mechanosensory signals mediated by quantal and nonquantal (NQ) synaptic transmission. We present several lines of data in the guinea pig that reveal the pre-synaptic transmission of the most sensitive vestibular afferents are faster than their auditory nerve counterparts. Here, we present neurophysiological and pharmacological evidence that this vestibular speed advantage arises from ultrafast NQ electrical synaptic transmission from Type I hair cells to their calyx partners.

Published

2023

10. Vestibular Compound Action Potentials and Macular Velocity Evoked by Sound and Vibration in the Guinea Pig1

Author

Christopher J. Pastras, Ian S. Curthoys, Richard D. Rabbitt, and Daniel J. Brown

Abstract

To examine mechanisms responsible for vestibular afferent sensitivity to transient air conducted sounds (ACS) and inter-aural bone conducted vibration (BCV), we performed simultaneous measurements of stimulus-evoked vestibular compound action potentials (vCAPs), utricular macula or stapes velocity, and vestibular microphonics (VMs) in the anaesthetized guinea pig. For short duration punctate stimuli (

Published

2022

11. A Parametric Blueprint for Optimum Cochlear Outer Hair Cell Design

Author

Richard D. Rabbitt and Tamara C. Bidone

Subjects

Biomaterials, Biomedical Engineering, Biophysics, Bioengineering, Biochemistry, Biotechnology

Abstract

The present work examines the hypothesis that cochlear outer hair cell (OHC) properties vary in precise proportions along the tonotopic map to optimize electro-mechanical power conversion. We tested this hypothesis using a very simple model of a single isolated OHC driving a mechanical load. Results identify three nondimensional ratios that are predicted to optimize power conversion: the ratio of the resistive-capacitive (RC) corner to the characteristic frequency (CF), the ratio of nonlinear to linear capacitance, and the ratio of OHC stiffness to cochlear load stiffness. Optimum efficiency requires all three ratios to be universal constants, independent of CF and species. The same ratios are cardinal control parameters that maximize power output by positioning the OHC operating point on the edge of a dynamic instability. Results support the hypothesis that OHC properties evolved to optimize electro-mechanical power conversion. Identification of the RC corner frequency as a control parameter reveals a powerful mechanism used by medial olivocochlear efferent system to control OHC power output. Results indicate the upper frequency limit of OHC power output is not constrained by the speed of the motor itself, but instead is likely limited by the size of the nucleus and membrane surface area available for ion-channel expression.

Published

2022

12. Analysis of outer hair cell electromechanics reveals power delivery at the upper-frequency limits of hearing

Author

Richard D. Rabbitt

Subjects

Mammals, Cell Membrane, Biomedical Engineering, Biophysics, Proteins, Bioengineering, Electric Capacitance, Biochemistry, Biomaterials, Hair Cells, Auditory, Outer, Hearing, Animals, Humans, Biotechnology

Abstract

Outer hair cells are the cellular motors in the mammalian inner ear responsible for sensitive high-frequency hearing. Motor function over the frequency range of human hearing requires expression of the protein prestin in the OHC lateral membrane, which imparts piezoelectric properties to the cell membrane. In the present report, electrical power consumption and mechanical power output of the OHC membrane–motor complex are determined using previously published voltage-clamp data from isolated OHCs and membrane patches. Results reveal that power output peaks at a best frequency much higher than implied by the low-pass character of nonlinear capacitance, and much higher than the whole-cell resistive–capacitive corner frequency. High frequency power output is enabled by a −90° shift in the phase of electrical charge displacement in the membrane, manifested electrically as emergence of imaginary-valued nonlinear capacitance.

Published

2022

13. Differential Activation of Canal and Otolith Afferents by Acoustic Tone Bursts in Rats

Author

Jun Huang, Xuehui Tang, Youguo Xu, Chunming Zhang, Tianwen Chen, Yue Yu, William Mustain, Jerome Allison, Marta M. Iversen, Richard D. Rabbitt, Wu Zhou, and Hong Zhu

Subjects

Rats, Sprague-Dawley, Otolithic Membrane, Otorhinolaryngology, Acoustic Stimulation, Animals, Correction, Acoustics, Vestibular Evoked Myogenic Potentials, Sensory Systems, Rats, Research Article

Abstract

Vestibular evoked myogenic potentials (VEMPs) are routinely used to test otolith function, but which specific vestibular afferent neurons and central circuits are activated by auditory frequency VEMP stimuli remains unclear. To examine this question, we analyzed the sensitivity of individual vestibular afferents in adult Sprague-Dawley rats to tone bursts delivered at 9 frequencies (125-4000 Hz) and 3 intensity levels (60, 70, 80 dB SL re: acoustic brainstem response (ABR) threshold). Afferent neuron tone sensitivity was quantified by the cumulative probability of evoking a spike (CPE). Based on a threshold CPE of 0.1, acoustic stimuli in the present study evoked responses in 78.2 % (390/499) of otolith afferent neurons vs. 48.4 % (431/891) of canal afferent neurons. Organ-specific vestibular inputs to the central nervous system in response to tone bursts differ based on intensity and frequency content of the stimulus. At frequencies below 500 Hz, tone bursts primarily activated both otolith afferents, even at the highest intensity tested (80 dB SL re ABR threshold). At 1500 Hz, however, tone bursts activated the canal and otolith afferents at the moderate and high intensities tested (70, 80 dB SL), but activated only otolith afferents at the low intensity tested (60 dB SL). Within an end organ, diversity of sensitivity between individual afferent neurons correlated with spontaneous discharge rate and regularity. Examination of inner ear fluid mechanics in silico suggests that the frequency response and preferential activation of the otolith organs likely arise from inner ear fluid motion trapped near the oval and round windows. These results provide insight into understanding the mechanisms of sound activation of the vestibular system and developing novel discriminative VEMP testing protocols and interpretative guidelines in humans.

Published

2022

14. The cochlear outer hair cell speed paradox

Author

Richard D. Rabbitt

Subjects

Acoustics, capacitance, Phase (waves), Context (language use), Electric Capacitance, Cell Line, otorhinolaryngologic diseases, medicine, Humans, prestin, Power output, Prestin, Cochlea, Physics, Multidisciplinary, piezoelectricity, biology, electromotility, temperature, Cell Biology, Biological Sciences, Instantaneous speed, Electrophysiology, Nonlinear capacitance, Biophysics and Computational Biology, Hair Cells, Auditory, Outer, Sound, medicine.anatomical_structure, Physical Sciences, biology.protein, sense organs, Hair cell

Abstract

Significance Mammalian hearing requires outer hair cells for amplification and tuning in the cochlea. The amplification process works at frequencies at least 10 times higher than might be expected based on electrical properties of the cells. The present report demonstrates how protein-dependent membrane piezoelectricity underlies high-frequency function, and why power output is maximum at frequencies much higher than would be predicted based on traditional experimental measurements. The interplay between electrical charge displacement and mechanical strain in the membrane motor is key. The same biophysical principles identify the origins of infrared laser-induced capacitive currents reported previously in hair cells, HEK cells, and neurons., Cochlear outer hair cells (OHCs) are among the fastest known biological motors and are essential for high-frequency hearing in mammals. It is commonly hypothesized that OHCs amplify vibrations in the cochlea through cycle-by-cycle changes in length, but recent data suggest OHCs are low-pass filtered and unable to follow high-frequency signals. The fact that OHCs are required for high-frequency hearing but appear to be throttled by slow electromotility is the “OHC speed paradox.” The present report resolves this paradox and reveals origins of ultrafast OHC function and power output in the context of the cochlear load. Results demonstrate that the speed of electromotility reflects how fast the cell can extend against the load, and does not reflect the intrinsic speed of the motor element itself or the nearly instantaneous speed at which the coulomb force is transmitted. OHC power output at auditory frequencies is revealed by emergence of an imaginary nonlinear capacitance reflecting the phase of electrical charge displacement required for the motor to overcome the viscous cochlear load.

Published

2020

15. Outer hair cell electro-mechanical power conversion

Author

Richard D. Rabbitt

Subjects

Physics, biology, business.industry, Phase (waves), Cutoff frequency, Power (physics), medicine.anatomical_structure, Distortion, medicine, biology.protein, Optoelectronics, sense organs, Hair cell, business, Prestin, Cochlea, Mechanical energy

Abstract

Outer hair cells (OHCs) are the cellular motors in the mammalian inner ear responsible for sensitive high-frequency hearing. Motor function requires expression of the protein prestin (SLC26A5) in the OHC lateral membrane, and ultrafast mechano-electrical transduction (MET) in the apical hair bundle. In the present report, electrical power consumption and mechanical power output of isolated OHCs and membrane patches are examined. Results reveal that power output by the prestin-motor complex is tuned to a best frequency and peaks at a frequency much higher than implied by the low-pass characteristic of traditional nonlinear capacitance, and much higher than the whole-cell resistive-capacitive corner frequency. The RC paradox is resolved by showing the passive membrane capacitance simply stores and releases potential energy without interfering with or diminishing power conversion by the prestin-motor complex. The NLC speed paradox is resolved by showing that the phase of the electrical charge displacement shifts 90{degrees} as the frequency is increased, as required to output power, thereby causing the real part of the NLC to be low pass while attaining motor function through the imaginary part at high frequencies. Power output by the MET-dependent hair bundle motor is also examined, with results indicating the somatic motor provides a bulk of the high-frequency power output. Results further demonstrate how nonlinearity of the prestin-motor complex and nonlinearity of the MET apparatus combine to generate distinct level-dependent cubic and quadratic distortion products near the best frequency (BF) location in the cochlea and basal to BF.

Published

2021

16. Semicircular canal biomechanics in health and disease

Author

Richard D. Rabbitt

Subjects

inner ear, Ménière’s disease, Benign paroxysmal positional vertigo, genetic structures, Physiology, Review, motion sensation, neural encoding of movement, 03 medical and health sciences, 0302 clinical medicine, otorhinolaryngologic diseases, medicine, Animals, Humans, Inner ear, 030304 developmental biology, Vestibular system, Crista ampullaris, 0303 health sciences, Tullio phenomena, vestibular, Semicircular canal, crista ampullaris, business.industry, caloric, General Neuroscience, Biomechanics, Anatomy, medicine.disease, Semicircular Canals, labyrinth, Biomechanical Phenomena, medicine.anatomical_structure, Vestibular Diseases, benign paroxysmal positional vertigo, sense organs, business, 030217 neurology & neurosurgery, alcohol nystagmus, canal dehiscence

Abstract

The semicircular canals are responsible for sensing angular head motion in three-dimensional space and for providing neural inputs to the central nervous system (CNS) essential for agile mobility, stable vision, and autonomic control of the cardiovascular and other gravity-sensitive systems. Sensation relies on fluid mechanics within the labyrinth to selectively convert angular head acceleration into sensory hair bundle displacements in each of three inner ear sensory organs. Canal afferent neurons encode the direction and time course of head movements over a broad range of movement frequencies and amplitudes. Disorders altering canal mechanics result in pathological inputs to the CNS, often leading to debilitating symptoms. Vestibular disorders and conditions with mechanical substrates include benign paroxysmal positional nystagmus, direction-changing positional nystagmus, alcohol positional nystagmus, caloric nystagmus, Tullio phenomena, and others. Here, the mechanics of angular motion transduction and how it contributes to neural encoding by the semicircular canals is reviewed in both health and disease.

Published

2019

17. Correction to: Differential Activation of Canal and Otolith Afferents by Acoustic Tone Bursts in Rats

Author

Jun Huang, Xuehui Tang, Youguo Xu, Chunming Zhang, Tianwen Chen, Yue Yu, William Mustain, Jerome Allison, Marta M. Iversen, Richard D. Rabbitt, Wu Zhou, and Hong Zhu

Subjects

Otorhinolaryngology, Sensory Systems

Published

2022

18. Cooperativity of K v 7.4 channels confers ultrafast electromechanical sensitivity and emergent properties in cochlear outer hair cells

Author

Nipavan Chiamvimonvat, Seojin Park, Maria C. Perez-Flores, Xiao-Dong Zhang, Wenying Wang, Valeriy Timofeyev, Ebenezer N. Yamoah, Hyo Jeong Kim, Vladimir Yarov-Yarovoy, Hannah A. Ledford, Jeong H. Lee, Choong Ryoul Sihn, and Richard D. Rabbitt

Subjects

Physics, 0303 health sciences, Multidisciplinary, technology, industry, and agriculture, Cooperativity, Gating, Optogenetics, 03 medical and health sciences, 0302 clinical medicine, Drag, biological sciences, Biophysics, sense organs, Sensitivity (control systems), Ultrashort pulse, 030217 neurology & neurosurgery, Cochlea, 030304 developmental biology, Audio frequency

Abstract

The mammalian cochlea relies on active electromotility of outer hair cells (OHCs) to resolve sound frequencies. OHCs use ionic channels and somatic electromotility to achieve the process. It is unclear, though, how the kinetics of voltage-gated ionic channels operate to overcome extrinsic viscous drag on OHCs at high frequency. Here, we report ultrafast electromechanical gating of clustered Kv7.4 in OHCs. Increases in kinetics and sensitivity resulting from cooperativity among clustered-Kv7.4 were revealed, using optogenetics strategies. Upon clustering, the half-activation voltage shifted negative, and the speed of activation increased relative to solitary channels. Clustering also rendered Kv7.4 channels mechanically sensitive, confirmed in consolidated Kv7.4 channels at the base of OHCs. Kv7.4 clusters provide OHCs with ultrafast electromechanical channel gating, varying in magnitude and speed along the cochlea axis. Ultrafast Kv7.4 gating provides OHCs with a feedback mechanism that enables the cochlea to overcome viscous drag and resolve sounds at auditory frequencies.

Published

2020

19. ACh-induced hyperpolarization and decreased resistance in mammalian type II vestibular hair cells

Author

Paivi M. Jordan, Hannah R. Drury, Joseph C. Holt, Hessam Tabatabaee, Lauren Ashlee Poppi, Robert J. Callister, Alan M. Brichta, Richard D. Rabbitt, Americo A. Migliaccio, Phillip Jobling, and Rebecca Lim

Subjects

Male, 0301 basic medicine, Small-Conductance Calcium-Activated Potassium Channels, Physiology, Efferent, Receptors, Nicotinic, Exocytosis, Membrane Potentials, Hair Cells, Vestibular, Mice, 03 medical and health sciences, 0302 clinical medicine, Potassium Channel Blockers, otorhinolaryngologic diseases, medicine, Animals, Vestibular Hair Cell, Vestibular system, Chemistry, General Neuroscience, Strychnine, Hyperpolarization (biology), Acetylcholine, Cell biology, Mice, Inbred C57BL, 030104 developmental biology, Nicotinic agonist, medicine.anatomical_structure, Apamin, Female, sense organs, Hair cell, Corrigendum, Neuroscience, 030217 neurology & neurosurgery, Research Article, Type II Hair Cell

Abstract

In the mammalian vestibular periphery, electrical activation of the efferent vestibular system (EVS) has two effects on afferent activity: 1) it increases background afferent discharge and 2) decreases afferent sensitivity to rotational stimuli. Although the cellular mechanisms underlying these two contrasting afferent responses remain obscure, we postulated that the reduction in afferent sensitivity was attributed, in part, to the activation of α9- containing nicotinic acetylcholine (ACh) receptors (α9*nAChRs) and small-conductance potassium channels (SK) in vestibular type II hair cells, as demonstrated in the peripheral vestibular system of other vertebrates. To test this hypothesis, we examined the effects of the predominant EVS neurotransmitter ACh on vestibular type II hair cells from wild-type (wt) and α9-subunit nAChR knockout (α9−/−) mice. Immunostaining for choline acetyltransferase revealed there were no obvious gross morphological differences in the peripheral EVS innervation among any of these strains. ACh application onto wt type II hair cells, at resting potentials, produced a fast inward current followed by a slower outward current, resulting in membrane hyperpolarization and decreased membrane resistance. Hyperpolarization and decreased resistance were due to gating of SK channels. Consistent with activation of α9*nAChRs and SK channels, these ACh-sensitive currents were antagonized by the α9*nAChR blocker strychnine and SK blockers apamin and tamapin. Type II hair cells from α9−/− mice, however, failed to respond to ACh at all. These results confirm the critical importance of α9nAChRs in efferent modulation of mammalian type II vestibular hair cells. Application of exogenous ACh reduces electrical impedance, thereby decreasing type II hair cell sensitivity. NEW & NOTEWORTHY Expression of α9 nicotinic subunit was crucial for fast cholinergic modulation of mammalian vestibular type II hair cells. These findings show a multifaceted efferent mechanism for altering hair cell membrane potential and decreasing membrane resistance that should reduce sensitivity to hair bundle displacements.

Published

2018

20. Wave Mechanics of the Vestibular Semicircular Canals

Author

Marta M. Iversen and Richard D. Rabbitt

Subjects

0301 basic medicine, Rotation, Endolymph, Acoustics, Membranous labyrinth, Biophysics, Models, Biological, Vibration, Bony labyrinth, Motion, 03 medical and health sciences, 0302 clinical medicine, Circular motion, Physical Stimulation, Pressure, otorhinolaryngologic diseases, medicine, Animals, Humans, Computer Simulation, Inner ear, Physics, Vestibular system, Systems Biophysics, Viscosity, Batrachoidiformes, Semicircular Canals, Biomechanical Phenomena, Sound, 030104 developmental biology, medicine.anatomical_structure, Head Movements, Hydrodynamics, Linear Models, sense organs, 030217 neurology & neurosurgery

Abstract

The semicircular canals are biomechanical sensors responsible for detecting and encoding angular motion of the head in 3D space. Canal afferent neurons provide essential inputs to neural circuits responsible for representation of self-position/orientation in space, and to compensatory circuits including the vestibulo-ocular and vestibulo-collic reflex arcs. In this work we derive, to our knowledge, a new 1D mathematical model quantifying canal biomechanics based on the morphology, dynamics of the inner ear fluids, and membranous labyrinth deformability. The model takes the form of a dispersive wave equation and predicts canal responses to angular motion, sound, and mechanical stimulation. Numerical simulations were carried out for the morphology of the human lateral canal using known physical properties of the endolymph and perilymph in three diverse conditions: surgical plugging, rotation, and mechanical indentation. The model reproduces frequency-dependent attenuation and phase shift in cases of canal plugging. During rotation, duct deformability extends the frequency bandwidth and enhances the high frequency gain. Mechanical indentation of the membranous duct at high frequencies evokes traveling waves that move away from the location of indentation and at low frequencies compels endolymph displacement along the canal. These results demonstrate the importance of the conformal perilymph-filled bony labyrinth to pressure changes and to high frequency sound and vibration.

Published

2017

21. Keeping your eye on the ball

Author

Richard D. Rabbitt, Henrique von Gersdorff, and Marta M. Iversen

Subjects

Synaptic cleft, Physiology, Anatomy, Biology, Synaptic Transmission, Article, Phase locking, Turtles, Hair Cells, Auditory, Synapses, Potassium, Ball (bearing), Animals, Vestibular Hair Cell

Abstract

In the vertebrate nervous system, ions accumulate in diffusion-limited synaptic clefts during ongoing activity. Such accumulation can be demonstrated at large appositions such as the hair cell – calyx afferent synapses present in central regions of the turtle vestibular semicircular canal epithelia. Type I hair cells influence discharge rates in their calyx afferents by modulating the potassium concentration in the synaptic cleft, [K(+)](c), which regulates potassium-sensitive conductances in both hair cell and afferent. Dual recordings from synaptic pairs have demonstrated that, despite a decreased driving force due to potassium accumulation, hair cell depolarization elicits sustained outward currents in the hair cell, and a maintained inward current in the afferent. We used kinetic and pharmacological dissection of the hair cell conductances to understand the interdependence of channel gating and permeation in the context of such restricted extracellular spaces. Hair cell depolarization leads to calcium influx and activation of a large calcium-activated potassium conductance, G(BK), that can be blocked by agents that disrupt calcium influx or buffer the elevation of [Ca(2+)](i), as well as by the specific K(Ca)1.1 blocker Iberiotoxin. Efflux of K(+) through G(BK) can rapidly elevate [K(+)](c), which speeds the activation and slows the inactivation and deactivation of a second potassium conductance, G(K(LV)). Elevation of [K(+)](c) or chelation of [Ca(2+)](c) linearizes the G(K(LV)) steady-state I–V curve, consistent with a K(+)-dependent relief of Ca(2+)-inactivation of G(K(LV)). As a result, this potassium-sensitive hair cell conductance pairs with the potassium-sensitive HCN conductance in the afferent and creates resistive coupling at the synaptic cleft.

Published

2020

22. Cooperativity of K

Author

Maria C, Perez-Flores, Jeong H, Lee, Seojin, Park, Xiao-Dong, Zhang, Choong-Ryoul, Sihn, Hannah A, Ledford, Wenying, Wang, Hyo Jeong, Kim, Valeriy, Timofeyev, Vladimir, Yarov-Yarovoy, Nipavan, Chiamvimonvat, Richard D, Rabbitt, and Ebenezer N, Yamoah

Subjects

integumentary system, KCNQ Potassium Channels, Temperature, SciAdv r-articles, Life Sciences, Cell Line, Cochlea, Electrophysiological Phenomena, Hair Cells, Auditory, Outer, Mice, otorhinolaryngologic diseases, Animals, Humans, Health and Medicine, Ion Channel Gating, Research Articles, Mechanical Phenomena, Research Article

Abstract

Acquired mechanical sensitivity of clustered Kv7.4 in outer hair cell sculpts fast cycle-by-cycle sound amplification and tuning., The mammalian cochlea relies on active electromotility of outer hair cells (OHCs) to resolve sound frequencies. OHCs use ionic channels and somatic electromotility to achieve the process. It is unclear, though, how the kinetics of voltage-gated ionic channels operate to overcome extrinsic viscous drag on OHCs at high frequency. Here, we report ultrafast electromechanical gating of clustered Kv7.4 in OHCs. Increases in kinetics and sensitivity resulting from cooperativity among clustered-Kv7.4 were revealed, using optogenetics strategies. Upon clustering, the half-activation voltage shifted negative, and the speed of activation increased relative to solitary channels. Clustering also rendered Kv7.4 channels mechanically sensitive, confirmed in consolidated Kv7.4 channels at the base of OHCs. Kv7.4 clusters provide OHCs with ultrafast electromechanical channel gating, varying in magnitude and speed along the cochlea axis. Ultrafast Kv7.4 gating provides OHCs with a feedback mechanism that enables the cochlea to overcome viscous drag and resolve sounds at auditory frequencies.

Published

2019

23. BODIPY-Conjugated Xyloside Primes Fluorescent Glycosaminoglycans in the Inner Ear of Opsanus tau

Author

Vy M. Tran, Mausam Kalita, Lynn N. Nguyen, Richard D. Rabbitt, Holly A. Holman, Sailaja Arungundram, and Balagurunathan Kuberan

Subjects

Boron Compounds, 0301 basic medicine, Chondroitin sulfate B, Biology, 03 medical and health sciences, Utricle, otorhinolaryngologic diseases, medicine, Animals, Inner ear, Glycosaminoglycans, Microscopy, Confocal, Xylose, Optical Imaging, Models, Theoretical, Kinocilium, Batrachoidiformes, Sensory Systems, Xyloside, Crista, 030104 developmental biology, medicine.anatomical_structure, Microscopy, Fluorescence, Otorhinolaryngology, Biochemistry, Ear, Inner, Biophysics, sense organs, Hair cell, Saccule, Research Article

Abstract

We report on a new xyloside conjugated to BODIPY, BX and its utility to prime fluorescent glycosaminoglycans (BX-GAGs) within the inner ear in vivo. When BX is administered directly into the endolymphatic space of the oyster toadfish (Opsanus tau) inner ear, fluorescent BX-GAGs are primed and become visible in the sensory epithelia of the semicircular canals, utricle, and saccule. Confocal and 2-photon microscopy of vestibular organs fixed 4 h following BX treatment, reveal BX-GAGs constituting glycocalyces that envelop hair cell kinocilium, nerve fibers, and capillaries. In the presence of GAG-specific enzymes, the BX-GAG signals are diminished, suggesting that chondroitin sulfates are the primary GAGs primed by BX. Results are consistent with similar click-xylosides in CHO cell lines, where the xyloside enters the Golgi and preferentially initiates chondroitin sulfate B production. Introduction of BX produces a temporary block of hair cell mechanoelectrical transduction (MET) currents in the crista, reduction in background discharge rate of afferent neurons, and a reduction in sensitivity to physiological stimulation. A six-degree-of-freedom pharmacokinetic mathematical model has been applied to interpret the time course and spatial distribution of BX and BX-GAGs. Results demonstrate a new optical approach to study GAG biology in the inner ear, for tracking synthesis and localization in real time.

Published

2016

24. Heat pulse excitability of vestibular hair cells and afferent neurons

Author

Peter J. Boutros, Richard D. Rabbitt, Hessam Tabatabaee, Lauren Ashlee Poppi, Charles C. Della Santina, Joong Ho Ahn, Rebecca Lim, and Alan M. Brichta

Subjects

Male, 0301 basic medicine, Chinchilla, Hot Temperature, Patch-Clamp Techniques, Sensory Receptor Cells, Physiology, Models, Neurological, Heat pulse, Biophysics, Action Potentials, Electric Capacitance, Membrane Potentials, Hair Cells, Vestibular, Mice, 03 medical and health sciences, 0302 clinical medicine, Cellular and Molecular Properties of Neurons, biology.animal, Potassium Channel Blockers, Animals, Patch clamp, Vestibular Hair Cell, Crista ampullaris, Membrane potential, Vestibular system, biology, Chemistry, General Neuroscience, Semicircular Canals, Mice, Inbred C57BL, 030104 developmental biology, Mice, Inbred CBA, Calcium, Female, sense organs, Peptides, Neuroscience, 030217 neurology & neurosurgery

Abstract

In the present study we combined electrophysiology with optical heat pulse stimuli to examine thermodynamics of membrane electrical excitability in mammalian vestibular hair cells and afferent neurons. We recorded whole cell currents in mammalian type II vestibular hair cells using an excised preparation (mouse) and action potentials (APs) in afferent neurons in vivo (chinchilla) in response to optical heat pulses applied to the crista (Δ T ≈ 0.25°C per pulse). Afferent spike trains evoked by heat pulse stimuli were diverse and included asynchronous inhibition, asynchronous excitation, and/or phase-locked APs synchronized to each infrared heat pulse. Thermal responses of membrane currents responsible for APs in ganglion neurons were strictly excitatory, with Q10≈ 2. In contrast, hair cells responded with a mix of excitatory and inhibitory currents. Excitatory hair cell membrane currents included a thermoelectric capacitive current proportional to the rate of temperature rise (d T/d t) and an inward conduction current driven by Δ T. An iberiotoxin-sensitive inhibitory conduction current was also evoked by Δ T, rising in

Published

2016

25. Sound abnormally stimulates the vestibular system in canal dehiscence syndrome by generating pathological fluid-mechanical waves

Author

C. C. Della Santina, Wu Zhou, Marta M. Iversen, John P. Carey, Richard D. Rabbitt, and Hong Zhu

Subjects

lcsh:Medicine, Sensory system, Nystagmus, Vibration, Article, Nystagmus, Pathologic, 03 medical and health sciences, 0302 clinical medicine, medicine, otorhinolaryngologic diseases, Animals, Inner ear, lcsh:Science, 030223 otorhinolaryngology, Vestibular system, Physics, Multidisciplinary, Semicircular canal, lcsh:R, Oval window, Anatomy, Syndrome, Batrachoidiformes, Semicircular Canals, Biomechanical Phenomena, medicine.anatomical_structure, Sound, Acoustic Stimulation, Vertigo, lcsh:Q, sense organs, Vestibule, Labyrinth, medicine.symptom, Tullio phenomenon, Mechanical wave, 030217 neurology & neurosurgery

Abstract

Individuals suffering from Tullio phenomena experience dizziness, vertigo, and reflexive eye movements (nystagmus) when exposed to seemingly benign acoustic stimuli. The most common cause is a defect in the bone enclosing the vestibular semicircular canals of the inner ear. Surgical repair often corrects the problem, but the precise mechanisms underlying Tullio phenomenon are not known. In the present work we quantified the phenomenon in an animal model of the condition by recording fluid motion in the semicircular canals and neural activity evoked by auditory-frequency stimulation. Results demonstrate short-latency phase-locked afferent neural responses, slowly developing sustained changes in neural discharge rate, and nonlinear fluid pumping in the affected semicircular canal. Experimental data compare favorably to predictions of a nonlinear computational model. Results identify the biophysical origin of Tullio phenomenon in pathological sound-evoked fluid-mechanical waves in the inner ear. Sound energy entering the inner ear at the oval window excites fluid motion at the location of the defect, giving rise to traveling waves that subsequently excite mechano-electrical transduction in the vestibular sensory organs by vibration and nonlinear fluid pumping.

Published

2018

26. The quantal component of synaptic transmission from sensory hair cells to the vestibular calyx

Author

Mary Anne Mann, Richard D. Rabbitt, and Stephen M. Highstein

Subjects

Patch-Clamp Techniques, Physiology, Postsynaptic Current, Biophysics, Lagena, In Vitro Techniques, Biology, Neurotransmission, Synaptic Transmission, Calyx, Synapse, Cellular and Molecular Properties of Neurons, Hair Cells, Auditory, medicine, Animals, Patch clamp, Probability, Vestibular system, musculoskeletal, neural, and ocular physiology, General Neuroscience, Excitatory Postsynaptic Potentials, Electric Stimulation, Turtles, medicine.anatomical_structure, nervous system, Synapses, Excitatory postsynaptic potential, Vestibule, Labyrinth, Neuroscience

Abstract

Spontaneous and stimulus-evoked excitatory postsynaptic currents (EPSCs) were recorded in calyx nerve terminals from the turtle vestibular lagena to quantify key attributes of quantal transmission at this synapse. On average, EPSC events had a magnitude of ∼42 pA, a rise time constant of τ0 ∼229 μs, decayed to baseline with a time constant of τR ∼690 μs, and carried ∼46 fC of charge. Individual EPSCs varied in magnitude and decay time constant. Variability in the EPSC decay time constant was hair cell dependent and due in part to a slow protraction of the EPSC in some cases. Variability in EPSC size was well described by an integer summation of unitary quanta, with each quanta of glutamate gating a unitary postsynaptic current of ∼23 pA. The unitary charge was ∼26 fC for EPSCs with a simple exponential decay and increased to ∼48 fC for EPSCs exhibiting a slow protraction. The EPSC magnitude and the number of simultaneous unitary quanta within each event increased with presynaptic stimulus intensity. During tonic hair cell depolarization, both the EPSC magnitude and event rate exhibited adaptive run down over time. Present data from a reptilian calyx are remarkably similar to noncalyceal vestibular synaptic terminals in diverse species, indicating that the skewed EPSC size distribution and multiquantal release might be an ancestral property of inner ear ribbon synapses.

Published

2015

27. Low-intensity ultrasound activates vestibular otolith organs through acoustic radiation force

Author

Jessica Chen, Dennis L. Parker, Douglas A. Christensen, Micah J. Frerck, Holly A. Holman, Richard D. Rabbitt, and Marta M. Iversen

Subjects

0301 basic medicine, Male, Time Factors, Acoustics and Ultrasonics, Acoustics, Vestibular evoked myogenic potential, Sensory system, Biology, Mechanotransduction, Cellular, 03 medical and health sciences, Otolithic Membrane, 0302 clinical medicine, Arts and Humanities (miscellaneous), Utricle, medicine, otorhinolaryngologic diseases, Animals, Inner ear, Neurons, Afferent, Acoustic radiation force, Otolith, Vestibular system, Psychological and Physiological Acoustics, Batrachoidiformes, Vestibular Evoked Myogenic Potentials, 030104 developmental biology, medicine.anatomical_structure, Ultrasonic Waves, Female, Saccule, sense organs, Neuroscience, 030217 neurology & neurosurgery

Abstract

The present study examined the efficacy of 5 MHz low-intensity focused ultrasound (LiFU) as a stimulus to remotely activate inner ear vestibular otolith organs. The otolith organs are the primary sensory apparati responsible for detecting orientation of the head relative to gravity and linear acceleration in three-dimensional space. These organs also respond to loud sounds and vibration of the temporal bone. The oyster toadfish, Opsanus tau, was used to facilitate unobstructed acoustic access to the otolith organs in vivo. Single-unit responses to amplitude-modulated LiFU were recorded in afferent neurons identified as innervating the utricle or the saccule. Neural responses were equivalent to direct mechanical stimulation, and arose from the nonlinear acoustic radiation force acting on the otolithic mass. The magnitude of the acoustic radiation force acting on the otolith was measured ex vivo. Results demonstrate that LiFU stimuli can be tuned to mimic directional forces occurring naturally during physiological movements of the head, loud air conducted sound, or bone conducted vibration.

Published

2017

28. Efferent modulation of hair cell function

Author

William E. Brownell and Richard D. Rabbitt

Subjects

Sound localization, Cochlear amplifier, medicine.medical_specialty, Efferent, Audiology, Efferent Pathways, Article, Hearing, Hair Cells, Auditory, otorhinolaryngologic diseases, medicine, Animals, Humans, Auditory system, Inner ear, Vestibular Hair Cell, Vestibular system, business.industry, Cochlea, medicine.anatomical_structure, Acoustic Stimulation, Otorhinolaryngology, Surgery, sense organs, Hair cell, business

Abstract

Purpose of review This review covers the articles published between 2010 and early 2011 that presented new findings on inner-ear efferents and their ability to modulate hair cell function. Recent findings Studies published within the review period have increased our understanding of efferent mechanisms on hair cells in the cochlear and vestibular sensory epithelium and provide insights on efferent contributions to the plasticity of bilateral auditory processing. The central nervous system controls the sensitivity of hair cells to physiological stimuli by regulating the gain of hair cell electromechanical amplification and modulating the efficiency of hair cell-eighth nerve transmission. A notable advance in the last year has been animal and human studies that have examined the contribution of the olivocochlear efferents to sound localization, particularly in a noisy environment. Summary Acoustic activation of olivocochlear fibers provides a clinical test for the integrity of the peripheral auditory system and has provided new understanding about the function and limitations of the cochlear amplifier. Although similar tests may be possible in the efferent vestibular system, they have not yet been developed. The structural and functional similarities of the sensory epithelia in the inner ear offer hope that testing procedures may be developed that will allow reliable testing of the vestibular hair cell function.

Published

2011

29. Intracellular calcium transients evoked by pulsed infrared radiation in neonatal cardiomyocytes

Author

Suhrud M. Rajguru, Richard D. Rabbitt, Gregory M. Dittami, Richard A. Lasher, and Robert W. Hitchcock

Subjects

Ruthenium red, Physiology, Ryanodine receptor, Pulse (signal processing), Chemistry, Calcium in biology, law.invention, chemistry.chemical_compound, Nuclear magnetic resonance, Confocal microscopy, law, Myocyte, Uniporter, Intracellular

Abstract

Neonatal rat ventricular cardiomyocytes were used to investigate mechanisms underlying transient changes in intracellular free Ca2+ concentration ([Ca2+]i) evoked by pulsed infrared radiation (IR, 1862 nm). Fluorescence confocal microscopy revealed IR-evoked [Ca2+]i events with each IR pulse (3-4 ms pulse⁻¹, 9.1-11.6 J cm⁻² pulse⁻¹). IR-evoked [Ca2+]i events were distinct from the relatively large spontaneous [Ca2+]i transients, with IR-evoked events exhibiting smaller amplitudes (0.88 ΔF/F0 vs. 1.99 ΔF/F0) and shorter time constants (τ =0.64 s vs. 1.19 s, respectively). Both IR-evoked [Ca2+]i events and spontaneous [Ca2+]i transients could be entrained by the IR pulse (0.2-1 pulse s⁻¹), provided the IR dose was sufficient and the radiation was applied directly to the cell. Examination of IR-evoked events during peak spontaneous [Ca2+]i periods revealed a rapid drop in [Ca2+]i, often restoring the baseline [Ca2+]i concentration, followed by a transient increase in [Ca2+]i.Cardiomyocytes were challenged with pharmacological agents to examine potential contributors to the IR-evoked [Ca2+]i events. Three compounds proved to be the most potent, reversible inhibitors: (1) CGP-37157 (20 μM, n =12), an inhibitor of the mitochondrial Na+/Ca2+ exchanger (mNCX), (2) Ruthenium Red (40 μM, n =13), an inhibitor of the mitochondrial Ca2+ uniporter (mCU), and (3) 2-aminoethoxydiphenylborane (10 μM, n =6), an IP3 channel antagonist. Ryanodine blocked the spontaneous [Ca2+]i transients but did not alter the IR-evoked events in the same cells. This pharmacological array implicates mitochondria as the major intracellular store of Ca2+ involved in IR-evoked responses reported here. Results support the hypothesis that 1862 nm pulsed IR modulates mitochondrial Ca2+ transport primarily through actions on mCU and mNCX.

Published

2011

30. Infrared photostimulation of the crista ampullaris

Author

Stephen M. Highstein, Gregory M. Dittami, Claus Peter Richter, Richard D. Rabbitt, Agnella Izzo Matic, and Suhrud M. Rajguru

Subjects

Crista ampullaris, medicine.anatomical_structure, Semicircular canal, Physiology, Postsynaptic potential, Chemistry, medicine, Time constant, Neurotransmission, Stimulus (physiology), Neuroscience, Photostimulation, Tonic (physiology)

Abstract

The present results show that the semicircular canal crista ampullaris of the toadfish, Opsanus tau, is sensitive to infrared radiation (IR) applied in vivo. IR pulse trains (∼1862 nm, ∼200 μs pulse⁻¹) delivered to the sensory epithelium by an optical fibre evoked profound changes in phasic and tonic discharge rates of postsynaptic afferent neurons. Phasic afferent responses to pulsed IR occurred with a latency of

Published

2011

31. GCAMP Calcium Imaging Reveals Kinetics and Location of MET Channels in Mammalian Semicircular Canal Hair Cells

Author

Micah D. Frerck, Richard D. Rabbitt, and Holly A. Holman

Subjects

medicine.anatomical_structure, Calcium imaging, Semicircular canal, Chemistry, GCaMP, Kinetics, Biophysics, medicine

Published

2018

32. Mechanical amplification by hair cells in the semicircular canals

Author

Richard D. Rabbitt, Richard Boyle, and Stephen M. Highstein

Subjects

Vestibular system, Multidisciplinary, Semicircular canal, Efferent, Hair Cells, Ampulla, Sensory system, Anatomy, Biological Sciences, Stimulus (physiology), Biology, Batrachoidiformes, Mechanotransduction, Cellular, Semicircular Canals, Motion, medicine.anatomical_structure, otorhinolaryngologic diseases, medicine, Animals, Inner ear, sense organs, Mechanotransduction, Neuroscience, Transduction (physiology)

Abstract

Sensory hair cells are the essential mechanotransducers of the inner ear, responsible not only for the transduction of sound and motion stimuli but also, remarkably, for nanomechanical amplification of sensory stimuli. Here we show that semicircular canal hair cells generate a mechanical nonlinearity in vivo that increases sensitivity to angular motion by amplification at low stimulus strengths. Sensitivity at high stimulus strengths is linear and shows no evidence of amplification. Results suggest that the mechanical work done by hair cells contributes ∼ 97 zJ/cell of amplification per stimulus cycle, improving sensitivity to angular velocity stimuli below ∼ 5 °/s (0.3-Hz sinusoidal motion). We further show that mechanical amplification can be inhibited by the brain via activation of efferent synaptic contacts on hair cells. The experimental model was the oyster toadfish, Opsanus tau . Physiological manifestation of mechanical amplification and efferent control in a teleost vestibular organ suggests the active motor process in sensory hair cells is ancestral. The biophysical basis of the motor(s) remains hypothetical, but a key discriminating question may involve how changes in somatic electrical impedance evoked by efferent synaptic action alter function of the motor(s).

Published

2010

33. Efferent Control of Hair Cell and Afferent Responses in the Semicircular Canals

Author

Richard D. Rabbitt, Stephen M. Highstein, and Richard Boyle

Subjects

Patch-Clamp Techniques, Physiology, Efferent, Motion Perception, Action Potentials, Biology, Biophysical Phenomena, Membrane Potentials, Physical Stimulation, Afferent, Hair Cells, Auditory, Reaction Time, otorhinolaryngologic diseases, medicine, Animals, Inner ear, Electric stimulation, Afferent Pathways, Extramural, General Neuroscience, Neural Inhibition, Articles, Batrachoidiformes, Electric Stimulation, Semicircular Canals, medicine.anatomical_structure, Inhibitory Postsynaptic Potentials, sense organs, Hair cell, Neuroscience

Abstract

The sensations of sound and motion generated by the inner ear are controlled by the brain through extensive centripetal innervation originating within the brain stem. In the semicircular canals, brain stem efferent neurons make synaptic contacts with mechanosensory hair cells and with the dendrites of afferent neurons. Here, we examine the relative contributions of efferent action on hair cells and afferents. Experiments were performed in vivo in the oyster toadfish, Opsanus tau. The efferent system was activated via electrical pulses to the brain stem and sensory responses to motion stimuli were quantified by simultaneous voltage recording from afferents and intracellular current- and/or voltage-clamp recordings from hair cells. Results showed synaptic inputs to both afferents and hair cells leading to relatively long-latency intracellular signaling responses: excitatory in afferents and inhibitory in hair cells. Generally, the net effect of efferent action was an increase in afferent background discharge and a simultaneous decrease in gain to angular motion stimuli. Inhibition of hair cells was likely the result of a ligand-gated opening of a major basolateral conductance. The reversal potential of the efferent-evoked current was just below the hair cell resting potential, thus resulting in a small hyperpolarization. The onset latency averaged about 90 ms and latency to peak response was 150–400 ms. Hair cell inhibition often outlasted afferent excitation and, in some cases, latched hair cells in the “off” condition for >1 s following cessation of stimulus. These features endow the animal with a powerful means to adjust the sensitivity and dynamic range of motion sensation.

Published

2009

34. Dynamic Displacement of Normal and Detached Semicircular Canal Cupula

Author

Stephen M. Highstein, Richard Boyle, Curtis King, Angela M. Yamauchi, Richard D. Rabbitt, and Kathryn D. Breneman

Subjects

Time Factors, Endolymph, Motion Perception, Action Potentials, Article, inner ear micromechanics, Afferent Neurons, Motion, 03 medical and health sciences, 0302 clinical medicine, Physical Stimulation, Afferent, medicine, Animals, Craniocerebral Trauma, Humans, Neurons, Afferent, 030304 developmental biology, Vestibular system, 0303 health sciences, vestibular, cupula regeneration, Semicircular canal, Chemistry, Time constant, Relaxation process, Anatomy, Batrachoidiformes, Adaptation, Physiological, Semicircular Canals, Sensory Systems, angular motion sensation, medicine.anatomical_structure, Otorhinolaryngology, sense organs, afferent response dynamics, Displacement (fluid), 030217 neurology & neurosurgery

Abstract

The dynamic displacement of the semicircular canal cupula and modulation of afferent nerve discharge were measured simultaneously in response to physiological stimuli in vivo. The adaptation time constant(s) of normal cupulae in response to step stimuli averaged 36 s, corresponding to a mechanical lower corner frequency for sinusoidal stimuli of 0.0044 Hz. For stimuli equivalent to 40–200 deg/s of angular head velocity, the displacement gain of the central region of the cupula averaged 53 nm per deg/s. Afferents adapted more rapidly than the cupula, demonstrating the presence of a relaxation process that contributes significantly to the neural representation of angular head motions by the discharge patterns of canal afferent neurons. We also investigated changes in time constants of the cupula and afferents following detachment of the cupula at its apex—mechanical detachment that occurs in response to excessive transcupular endolymph pressure. Detached cupulae exhibited sharply reduced adaptation time constants (300 ms–3 s, n = 3) and can be explained by endolymph flowing rapidly over the apex of the cupula. Partially detached cupulae reattached and normal afferent discharge patterns were recovered 5–7 h following detachment. This regeneration process may have relevance to the recovery of semicircular canal function following head trauma.

Published

2009

35. Afferent Responses During Experimentally Induced Semicircular Canalithiasis

Author

Richard D. Rabbitt and Suhrud M. Rajguru

Subjects

Male, Oyster toadfish, Time Factors, Benign paroxysmal positional vertigo, Physiology, Action Potentials, Lumen (anatomy), Nystagmus, Article, Nystagmus, Pathologic, Tonic (physiology), Physical Stimulation, Vertigo, otorhinolaryngologic diseases, medicine, Animals, Vestibular system, Afferent Pathways, biology, Semicircular canal, Chemistry, General Neuroscience, Anatomy, Batrachoidiformes, medicine.disease, biology.organism_classification, Semicircular Canals, Disease Models, Animal, medicine.anatomical_structure, Vestibular Diseases, Female, sense organs, medicine.symptom

Abstract

Benign paroxysmal positional vertigo (BPPV) is a common vestibular disorder that results in brief periods of vertigo and nystagmus, when the head is tipped relative to gravity. Symptoms are commonly attributed to the pathological presence of heavy calcium carbonate particles within the lumen of the semicircular canal(s)—a condition termed canalithiasis. In the present work, we induced canalithiasis in an animal model (oyster toadfish, Opsanus tau) by introducing heavy glass microbeads into the lumen of the lateral semicircular canal. Bead movement under the action of gravity and canal afferent nerve discharge were recorded in vivo. When the head was oriented nose-down, beads moved toward the nose and the lateral canal afferent discharge rate increased. Afferents that normally encoded angular velocity during oscillatory head rotations responded with tonic increases in the discharge rate during gravity-dependent bead movement. Other afferents, such as the units that rapidly adapt to a step increase in angular head velocity, responded with an initial increase in discharge rate followed by a period of adaptation. Afferent responses occurred in the complete absence of head movement and quantify the pathological inputs to the brain that arise from canalithiasis. The magnitude and time course of the responses reported here are sufficient to explain the symptoms of BPPV.

Published

2007

36. Xyloside primed glycosaminoglycans alter hair bundle micromechanical coupling and synaptic transmission: Pharmacokinetics

Author

Richard D. Rabbitt, Balagurunathan Kuberan, Vy M. Tran, Lynn Y. Nguyen, Sailaja Arungundram, Holly A. Holman, and Mausam Kalita

Subjects

Endolymph, Stimulation, Anatomy, Kinocilium, Biology, Neurotransmission, Synapse, Crista, medicine.anatomical_structure, otorhinolaryngologic diseases, medicine, Biophysics, Inner ear, sense organs, Hair cell

Abstract

Glycosaminoglycans (GAGs) are ubiquitous in the inner ear, and disorders altering their structure or production often result in debilitating hearing and balance deficits. The specific mechanisms responsible for loss of hair-cell function are not well understood. We recently reported that introduction of a novel BODIPY conjugated xyloside (BX) into the endolymph primes fluorescent GAGs in vivo [6, 15]. Confocal and two-photon fluorescence imaging revealed rapid turnover and assembly of a glycocalyx enveloping the kinocilia and extending into the cupula, a structure that presumably serves as a mechanical link between the hair bundle and the cupula. Extracellular fluorescence was also observed around the basolateral surface of hair cells and surrounding afferent nerve projections into the crista. Single unit afferent recordings during mechanical hair bundle stimulation revealed temporary interruption of synaptic transmission following BX administration followed by recovery, demonstrating an essential role for GAGs in function of the hair cell synapse. In the present work we present a pharmacokinetic model to quantify the time course of BX primed GAG production and turnover in the ear.

Published

2015

37. Photometric recording of transmembrane potential in outer hair cells

Author

Richard D. Rabbitt, John S. Oghalai, Peter Saggau, Takashi Nakagawa, and William E. Brownell

Subjects

Male, Materials science, Stereocilia (inner ear), Guinea Pigs, Biomedical Engineering, Phase (waves), Pyridinium Compounds, Sensitivity and Specificity, Signal, Article, Membrane Potentials, Cellular and Molecular Neuroscience, Optics, Animals, Cells, Cultured, Group delay and phase delay, Membrane potential, business.industry, Amplifier, Reproducibility of Results, Equipment Design, Equipment Failure Analysis, Hair Cells, Auditory, Outer, Light intensity, Spectrometry, Fluorescence, Amplitude, Microscopy, Fluorescence, Luminescent Measurements, Female, sense organs, business

Abstract

Cochlear outer hair cells (OHCs) are polarized epithelial cells that have mechanoelectrical transduction channels within their apical stereocilia and produce electromotile force along their lateral wall. Phase shifts, or time delays, in the transmembrane voltage occurring at different axial locations along the cell may contribute to our understanding of how these cells operate at auditory frequencies. We developed a method to optically measure the phase of the OHC transmembrane potential using the voltage-sensitive dye (VSD) di-8-ANEPPS. The exit aperture of a fibre-optic light source was driven in two dimensions so that a 24 microm spot of excitation light could be positioned along the length of the OHC. We used the whole-cell patch-clamp technique in the current-clamp mode to stimulate the OHC at the base. The photometric response and the voltage response were monitored with a photodetector and patch-clamp amplifier, respectively. The photometric response was used to measure the regional changes in the membrane potential in response to maintained (dc) and sinusoidal (ac) current stimuli applied at the base of the cell. We used a neutral density filter to lower the excitation light intensity and reduce phototoxicity. A sensitive detector and lock-in amplifier were used to measure the small ac VSD signal. This permitted measurements of the ac photometric response below the noise floor of the static fluorescence. The amplitude and phase components of the photometric response were recorded for stimuli up to 800 Hz. VSD data at 400-800 Hz show the presence of a small phase delay between the stimulus voltage at the base of the cell and the local membrane potential measured along the lateral wall. Results are consistent with the hypothesis that OHCs exhibit inhomogeneous membrane potentials that vary with position in analogy with the voltage in nerve axons.

Published

2006

38. How Endolymph Pressure Modulates Semicircular Canal Primary Afferent Discharge

Author

Richard D. Rabbitt, R. Boyle, Angela M. Yamauchi, and Stephen M. Highstein

Subjects

Vestibular system, Semicircular canal, Endolymph, Chemistry, General Neuroscience, Anatomy, Stimulus (physiology), medicine.disease, Perilymph, Pressure sensor, Semicircular Canals, General Biochemistry, Genetics and Molecular Biology, medicine.anatomical_structure, History and Philosophy of Science, otorhinolaryngologic diseases, medicine, Animals, sense organs, Endolymphatic hydrops, Ampulla

Abstract

Histological observation of endolymphatic hydrops in subjects suffering from Meniere's disease/syndrome and the presence of vestibular symptoms in experimentally induced endolymphatic hydrops have led to considerable debate regarding the potential role of inner-ear pressure. Could a condition influencing endolymphatic volume regulation lead to transient changes in translabyrinthine pressure sufficiently large to alter primary afferent discharge rates? To investigate this question we built a highly sensitive laser-based pressure sensor and recorded endolymphatic pressure modulations within the horizontal semicircular canal ampulla in response to mechanical stimuli for simple head rotation and controlled volume injection. The most sensitive primary afferents responded to changes in endolymph pressures as low as 0.005 Pa (re: perilymph)--a pressure considerably lower than that observed in most experimentally induced hydropic conditions. This threshold pressure was generated by a approximately 25 picoliter volume injection stimulus. Semicircular canal afferent responses to endolymphatic pressure can be explained on the basis of pressure-induced hydrops, which causes dilation of the ampulla, deformation of the cupula, hair bundle movement, and afferent discharge. Primary afferent responses to maintained stimuli were transient in nature and recovered to pre-stimulus background discharge rates following a period of adaptation. Results demonstrate that the semicircular canals are indeed sensitive to small changes in translabyrinthine pressure in addition to head-movement-related changes in transcupular pressure.

Published

2006

39. Determinants of Spatial and Temporal Coding by Semicircular Canal Afferents

Author

Stephen M. Highstein, Richard D. Rabbitt, Gay R. Holstein, and Richard D. Boyle

Subjects

Angular acceleration, genetic structures, Physiology, Motion Perception, Angular velocity, Article, Hair Cells, Vestibular, Acceleration, Circular motion, otorhinolaryngologic diseases, medicine, Animals, Humans, Physics, Vestibular system, Afferent Pathways, Quantitative Biology::Neurons and Cognition, Semicircular canal, General Neuroscience, Dynamics (mechanics), Labyrinthine Fluids, Reflex, Vestibulo-Ocular, Mechanics, Semicircular Canals, Biomechanical Phenomena, medicine.anatomical_structure, Head Movements, Space Perception, Synapses, Neural Networks, Computer, sense organs, Displacement (fluid), Signal Transduction

Abstract

The vestibular semicircular canals are internal sensors that signal the magnitude, direction, and temporal properties of angular head motion. Fluid mechanics within the 3-canal labyrinth code the direction of movement and integrate angular acceleration stimuli over time. Directional coding is accomplished by decomposition of complex angular accelerations into 3 biomechanical components—one component exciting each of the 3 ampullary organs and associated afferent nerve bundles separately. For low-frequency angular motion stimuli, fluid displacement within each canal is proportional to angular acceleration. At higher frequencies, above the lower corner frequency, real-time integration is accomplished by viscous forces arising from the movement of fluid within the slender lumen of each canal. This results in angular velocity sensitive fluid displacements. Reflecting this, a subset of afferent fibers indeed report angular acceleration to the brain for low frequencies of head movement and report angular velocity for higher frequencies. However, a substantial number of afferent fibers also report angular acceleration, or a signal between acceleration and velocity, even at frequencies where the endolymph displacement is known to follow angular head velocity. These non-velocity-sensitive afferent signals cannot be attributed to canal biomechanics alone. The responses of non-velocity-sensitive cells include a mathematical differentiation (first-order or fractional) imparted by hair-cell and/or afferent complexes. This mathematical differentiation from velocity to acceleration cannot be attributed to hair cell ionic currents, but occurs as a result of the dynamics of synaptic transmission between hair cells and their primary afferent fibers. The evidence for this conclusion is reviewed below.

Published

2005

40. Hair-Cell Versus Afferent Adaptation in the Semicircular Canals

Author

Stephen M. Highstein, Richard Boyle, G. R. Holstein, and Richard D. Rabbitt

Subjects

Patch-Clamp Techniques, Time Factors, Physiology, Biology, Models, Biological, Article, Afferent Neurons, Membrane Potentials, Afferent, Hair Cells, Auditory, otorhinolaryngologic diseases, medicine, Animals, Patch clamp, Electric stimulation, Afferent Pathways, Communication, Semicircular canal, business.industry, General Neuroscience, Batrachoidiformes, Adaptation, Physiological, Electric Stimulation, Semicircular Canals, medicine.anatomical_structure, Time course, sense organs, Hair cell, Adaptation, business, Microelectrodes, Neuroscience

Abstract

The time course and extent of adaptation in semicircular canal hair cells was compared to adaptation in primary afferent neurons for physiological stimuli in vivo to study the origins of the neural code transmitted to the brain. The oyster toadfish, Opsanus tau, was used as the experimental model. Afferent firing-rate adaptation followed a double-exponential time course in response to step cupula displacements. The dominant adaptation time constant varied considerably among afferent fibers and spanned six orders of magnitude for the population (∼1 ms to >1,000 s). For sinusoidal stimuli (0.1–20 Hz), the rapidly adapting afferents exhibited a 90° phase lead and frequency-dependent gain, whereas slowly adapting afferents exhibited a flat gain and no phase lead. Hair-cell voltage and current modulations were similar to the slowly adapting afferents and exhibited a relatively flat gain with very little phase lead over the physiological bandwidth and dynamic range tested. Semicircular canal microphonics also showed responses consistent with the slowly adapting subset of afferents and with hair cells. The relatively broad diversity of afferent adaptation time constants and frequency-dependent discharge modulations relative to hair-cell voltage implicate a subsequent site of adaptation that plays a major role in further shaping the temporal characteristics of semicircular canal afferent neural signals.

Published

2005

41. Substrate Curvature Influences the Direction of Nerve Outgrowth

Author

Roy M. Smeal, Patrick A. Tresco, Richard D. Rabbitt, and Roy Biran

Subjects

Nervous system, Neurite, Nervous tissue, Models, Neurological, Biomedical Engineering, Adhesion, Anatomy, Biology, Curvature, Axons, Nerve Regeneration, Rats, Rats, Sprague-Dawley, medicine.anatomical_structure, Animals, Newborn, Neurites, medicine, Biophysics, Animals, Computer Simulation, Axon, Cytoskeleton, Process (anatomy), Cells, Cultured

Abstract

Nerve outgrowth in the developing nervous system utilizes a variety of attractive and repulsive molecules found in the extracellular environment. In addition, physical cues may play an important regulatory role in determining directional outgrowth of nervous tissue. Here, by culturing nerve cells on filamentous surfaces and measuring directional growth, we tested the hypothesis that substrate curvature is sufficient to influence the directional outgrowth of nerve cells. We found that the mean direction of neurite outgrowth aligned with the direction of minimum principle curvature, and the spatial variance in outgrowth direction was directly related to the maximum principle curvature. As substrate size approached the size of an axon, adherent neurons extended processes that followed the direction of the long axis of the substrate similar to what occurs during development along pioneering axons and radial glial fibers. A simple Boltzmann model describing the interplay between adhesion and bending stiffness of the nerve process was found to be in close agreement with the data suggesting that cell stiffness and substrate curvature can act together in a manner that is sufficient to direct nerve outgrowth in the absence of contrasting molecular cues. The study highlights the potential importance of cellular level geometry as a fidelity-enhancing cue in the developing and regenerating nervous system.

Published

2005

42. Convergence of excitatory and inhibitory hair cell transmitters shapes vestibular afferent responses

Author

Gay R. Holstein, Richard D. Rabbitt, Giorgio P. Martinelli, Victor L. Friedrich, Richard D. Boyle, and Stephen M. Highstein

Subjects

Male, Angular acceleration, Acceleration, Models, Neurological, Angular velocity, Biology, Inhibitory postsynaptic potential, Propanolamines, Hair Cells, Vestibular, Afferent, otorhinolaryngologic diseases, medicine, Animals, gamma-Aminobutyric Acid, Vestibular system, Afferent Pathways, Multidisciplinary, Dynamics (mechanics), Anatomy, Biological Sciences, Batrachoidiformes, Phosphinic Acids, Electrophysiology, medicine.anatomical_structure, Receptors, GABA-B, Excitatory postsynaptic potential, Female, sense organs, Hair cell, GABA-B Receptor Antagonists, Neuroscience

Abstract

The vestibular semicircular canals respond to angular acceleration that is integrated to angular velocity by the biofluid mechanics of the canals and is the primary origin of afferent responses encoding velocity. Surprisingly, some afferents actually report angular acceleration. Our data indicate that hair-cell/afferent synapses introduce a mathematical derivative in these afferents that partially cancels the biomechanical integration and results in discharge rates encoding angular acceleration. We examined the role of convergent synaptic inputs from hair cells to this mathematical differentiation. A significant reduction in the order of the differentiation was observed for low-frequency stimuli after γ-aminobutyric acid type B receptor antagonist administration. Results demonstrate that γ-aminobutyric acid participates in shaping the temporal dynamics of afferent responses.

Published

2004

43. Ultrastructural observations of efferent terminals in the crista Ampullaris of the toadfish, opsanus tau

Author

Richard Boyle, G. R. Holstein, Richard D. Rabbitt, Stephen M. Highstein, and Giorgio P. Martinelli

Subjects

Male, Nervous system, Efferent, Presynaptic Terminals, Synaptic Membranes, Biology, Efferent Pathways, Synaptic Transmission, Feedback, Synapse, Hair Cells, Vestibular, Neurons, Efferent, Hair Cells, Auditory, medicine, Animals, Inner ear, Calcium Signaling, Postural Balance, Crista ampullaris, Neurotransmitter Agents, Tissue Embedding, Semicircular canal, Histocytochemistry, General Neuroscience, Anatomy, Batrachoidiformes, Semicircular Canals, Microscopy, Electron, Crista, medicine.anatomical_structure, Female, Synaptic Vesicles, Hair cell, Neuroscience

Abstract

The present study was conducted to visualize the ultrastructural features of vestibular efferent boutons in the oyster toadfish, Opsanus tau. The crista ampullaris of the horizontal semicircular canal was processed for and examined by routine transmission electron microscopy. The results demonstrate that such boutons vary in size and shape, and contain a heterogeneous population of lucent vesicles with scattered dense core vesicles. Efferent contacts with hair cells are characterized by local vesicle accumulations in the presynaptic terminal and a subsynaptic cistern in the postsynaptic region of the hair cell. Serial efferent to hair cell to afferent synaptic arrangements are common, particularly in the central portion of the crista. However, direct contacts between efferent terminals and afferent neurites were not observed in our specimens. The existence of serial synaptic contacts, often with a row of vesicles in the efferent boutons lining the efferent-afferent membrane apposition, suggests that the efferent influence on the crista may involve both synaptic and nonsynaptic, secretory mechanisms. Further, it is suggested that differences in more subtle aspects of synaptic architecture and/or transmitter and receptor localization and interaction may render the efferent innervation of the peripheral crista less effective in influencing sensory processing.

Published

2004

44. Three-Dimensional Biomechanical Model of Benign Paroxysmal Positional Vertigo

Author

Marytheresa A. Ifediba, Richard D. Rabbitt, and Suhrud M. Rajguru

Subjects

Benign paroxysmal positional vertigo, Movement, Vestibular disorders, Posture, Biomedical Engineering, Lithiasis, Models, Biological, Peak response, Vertigo, otorhinolaryngologic diseases, medicine, Humans, Computer Simulation, Ampulla, Semicircular canal, biology, business.industry, Anatomy, Vestibular Function Tests, medicine.disease, biology.organism_classification, Semicircular Canals, Biomechanical Phenomena, medicine.anatomical_structure, Biomechanical model, sense organs, business

Abstract

A morphologically descriptive 3-canal mathematical model was developed to quantify the biomechanical origins of gravity-dependent semicircular canal responses under pathological conditions of canalithiasis and cupulolithiasis--conditions associated with the vestibular disorder benign paroxysmal positional vertigo (BPPV). The model describes the influence of displaced calcium carbonate debris (particles) located within the labyrinth on the time-dependent responses of the ampullary organs. The particles were modeled as spheres free to move in the canal lumen (canalithiasis) or adhered to a cupula (cupulolithiasis). The model predicts canal responses to the diagnostic Dix-Hallpike maneuver, and to a modified Epley canalith repositioning (CRP) treatment. Results for canalithiasis predict activation latencies and response magnitudes consistent with clinical observations during the Dix-Hallpike maneuver. The magnitude of the response evoked by the Dix-Hallpike test was primarily due to the total weight of the particles while the latency to peak response was due to the time required for the stone to move from the ampulla to the posterior apex of the canal. Results further illustrate the effectiveness of the Epley CRP in repositioning the particles and relieving the symptoms of the canalithiasis type of BPPV.

Published

2004

45. ?-Aminobutyric acid is present in a spatially discrete subpopulation of hair cells in the crista ampullaris of the toadfishOpsanus tau

Author

Stephen M. Highstein, Victor L. Friedrich, Giorgio P. Martinelli, Richard D. Rabbitt, and Scott C. Henderson

Subjects

Population, Fluorescent Antibody Technique, Glutamic Acid, Hair Cells, Vestibular, Glutamatergic, Species Specificity, Animals, Tissue Distribution, Neurons, Afferent, Columbidae, education, gamma-Aminobutyric Acid, Toadfish, Crista ampullaris, education.field_of_study, biology, General Neuroscience, Glutamate receptor, Colocalization, Batrachoidiformes, biology.organism_classification, Cell biology, Crista, GABAergic, Vestibule, Labyrinth, sense organs, Neuroscience

Abstract

Although γ-aminobutyric acid (GABA) and glutamate are known to be present in the vestibular sensory epithelia of a variety of species, the functional relationship between these two transmitters is not clear. The present study addresses the three-dimensional spatial distribution of GABA and glutamate immunoreactivity in the vestibular labyrinth of the oyster toadfish by using whole end organs labeled by immunofluorescence with monoclonal anti-GABA and/or antiglutamate antibodies and visualized as whole mounts by multiphoton confocal microscopy. We find glutamate-immunoreactive hair cells present throughout the sensory epithelium. In contrast, prominent GABA immunoreactivity is restricted to a small population of hair cells located in the central region of the crista. Double immunofluorescence reveals two distinct staining patterns in GABA-labeled hair cells. Most (∼80%) GABA-labeled cells show trace levels of glutamate, appropriate for the metabolic/synthetic role of cytoplasmic glutamate. The remainder of the GABA-stained cells contain substantial levels of both GABA and glutamate, suggesting transmitter colocalization. In the toadfish utricle, glutamatergic hair cells are present throughout the macula. GABA-immunoreactive hair cells follow the arc of the striola, and most GABA-labeled receptor cells coexpress glutamate. The localization of GABA was explored in other species as well. In the pigeon, GABAergic hair cells are present throughout the crista ampullaris. Our findings demonstrate that multiple, neurochemically distinct types of hair cells are present in vestibular sensory epithelia. These observations, together with the excitatory activity generally associated with 8th nerve afferent fibers, strongly suggest that GABA serves an important, specific, and complex role in determining primary afferent response dynamics. J. Comp. Neurol. 471:1–10, 2004. © 2004 Wiley-Liss, Inc.

Published

2004

46. An electric impedance based microelectromechanical system flow sensor for ionic solutions

Author

H. Edward Ayliffe and Richard D. Rabbitt

Subjects

Materials science, business.industry, Applied Mathematics, Electrical engineering, Analytical chemistry, Ionic bonding, Electrolyte, Article, Flow measurement, Volumetric flow rate, Ion, Diffusion layer, Electrode, Fluid dynamics, business, Instrumentation, Engineering (miscellaneous)

Abstract

Microfluidic devices with channel cross sections measuring 4 × 10 μm(2) instrumented with gold microelectrodes were used to sense flow rates of ionic solutions on the basis of electric impedance (EI) measured perpendicular to the flow. Negative pressures were applied to access ports of the microdevices to generate flow of saline solutions (physiologic concentrations 0.9%) through the micro-EI recording zone with flow rates between 2.4 and 4.8 μl min(-1). The EI spectra (100 Hz-20 MHz) recorded under flow conditions were compared with the no-flow condition. Changes in the magnitude of EI (at 350 Hz) for flow rates as low as 2.4 μl min(-1) were statistically significant compared with the no-flow condition. The observed dependence of EI on flow rate is attributed to the relative difference between the rate of migration of charge-balancing electrolyte ions to the electrode surface and the rate of removal of the same ions by forced convection. An electrochemical convection-diffusion model was used to study the observed dependence on flow. Simulations support the conceptual model that passing DC current from the gold electrodes into the ionic solution results in an increase in ionic concentration near the electrode surface (due to the inward migration of counter-balancing ions). When the fluid flow rates increase, these counter-balancing ions are replaced by the bulk solution, thereby lowering the average ionic concentration within the recording zone. This local concentration drop results in an increase in the real part of the impedance.

Published

2003

47. Strain Measurement in Coronary Arteries Using Intravascular Ultrasound and Deformable Images

Author

Alexander I. Veress, Richard D. Rabbitt, Grant T. Gullberg, Jeffrey A. Weiss, and D. Geoffrey Vince

Subjects

Materials science, Finite Element Analysis, Biomedical Engineering, Image registration, Coronary Artery Disease, Sensitivity and Specificity, Physiology (medical), Image Interpretation, Computer-Assisted, Intravascular ultrasound, medicine, Humans, Computer Simulation, Image warping, Ultrasonography, Interventional, Stochastic Processes, medicine.diagnostic_test, Pixel, business.industry, Ultrasound, Models, Cardiovascular, Reproducibility of Results, Arteries, Elasticity (physics), Coronary Vessels, Elasticity, Coronary arteries, medicine.anatomical_structure, Subtraction Technique, Stress, Mechanical, Deformation (engineering), business, Algorithms, Biomedical engineering

Abstract

Atherosclerotic plaque rupture is responsible for the majority of myocardial infarctions and acute coronary syndromes. Rupture is initiated by mechanical failure of the plaque cap, and thus study of the deformation of the plaque in the artery can elucidate the events that lead to myocardial infarction. Intravascular ultrasound (IVUS) provides high resolution in vitro and in vivo cross-sectional images of blood vessels. To extract the deformation field from sequences of IVUS images, a registration process must be performed to correlate material points between image pairs. The objective of this study was to determine the efficacy of an image registration technique termed Warping to determine strains in plaques and coronary arteries from paired IVUS images representing two different states of deformation. The Warping technique uses pointwise differences in pixel intensities between image pairs to generate a distributed body force that acts to deform a finite element model. The strain distribution estimated by image-based Warping showed excellent agreement with a known forward finite element solution, representing the gold standard, from which the displaced image was created. The Warping technique had a low sensitivity to changes in material parameters or material model and had a low dependency on the noise present in the images. The Warping analysis was also able to produce accurate strain distributions when the constitutive model used for the Warping analysis and the forward analysis was different. The results of this study demonstrate that Warping in conjunction with in vivo IVUS imaging will determine the change in the strain distribution resulting from physiological loading and may be useful as a diagnostic tool for predicting the likelihood of plaque rupture through the determination of the relative stiffness of the plaque constituents.

Published

2002

48. Evidence that protons act as neurotransmitters at vestibular hair cell–calyx afferent synapses

Author

Mary Anne Mann, Stephen M. Highstein, and Richard D. Rabbitt

Subjects

Neurotransmitter Agents, Multidisciplinary, Synaptic cleft, Postsynaptic Current, Neurotransmission, Biology, Biological Sciences, Inhibitory postsynaptic potential, Calyx, Hair Cells, Vestibular, Postsynaptic potential, otorhinolaryngologic diseases, Excitatory postsynaptic potential, sense organs, Protons, Neuroscience, Vestibular Hair Cell

Abstract

Present data support the conclusion that protons serve as an important neurotransmitter to convey excitatory stimuli from inner ear type I vestibular hair cells to postsynaptic calyx nerve terminals. Time-resolved pH imaging revealed stimulus-evoked extrusion of protons from hair cells and a subsequent buildup of [H(+)] within the confined chalice-shaped synaptic cleft (ΔpH ∼ -0.2). Whole-cell voltage-clamp recordings revealed a concomitant nonquantal excitatory postsynaptic current in the calyx terminal that was causally modulated by cleft acidification. The time course of [H(+)] buildup limits the speed of this intercellular signaling mechanism, but for tonic signals such as gravity, protonergic transmission offers a significant metabolic advantage over quantal excitatory postsynaptic currents--an advantage that may have driven the proliferation of postsynaptic calyx terminals in the inner ear vestibular organs of contemporary amniotes.

Published

2014

49. Input–Output Functions of Vestibular Afferent Responses to Air-Conducted Clicks in Rats

Author

Jerome Allison, Adel Maklad, Steve Highstein, Wu Zhou, Xuehui Tang, Wei Wei, Hong Zhu, Richard D. Rabbitt, and William Mustain

Subjects

Male, medicine.medical_specialty, Time Factors, Action Potentials, Otolithic membrane, Audiology, Extraocular muscles, Rats, Sprague-Dawley, Otolithic Membrane, medicine, otorhinolaryngologic diseases, Reaction Time, Animals, Neurons, Afferent, Otolith, Vestibular system, Semicircular canal, business.industry, Anatomy, Sensory Systems, Semicircular Canals, Rats, medicine.anatomical_structure, Sound, Otorhinolaryngology, Acoustic Stimulation, Vestibule, Models, Animal, Brainstem, Saccule, sense organs, Vestibule, Labyrinth, business, Research Article

Abstract

Sound-evoked vestibular myogenic potentials recorded from the sternocleidomastoid muscles (the cervical vestibular-evoked myogenic potential or cVEMP) and the extraocular muscles (the ocular VEMP or oVEMP) have proven useful in clinical assessment of vestibular function. VEMPs are commonly interpreted as a test of saccular function, based on neurophysiological evidence showing activation of saccular afferents by intense acoustic click stimuli. However, recent neurophysiological studies suggest that the clicks used in clinical VEMP tests activate vestibular end organs other than the saccule. To provide the neural basis for interpreting clinical VEMP testing results, the present study examined the extent to which air-conducted clicks differentially activate the various vestibular end organs at several intensities and durations in Sprague–Dawley rats. Single unit recordings were made from 562 vestibular afferents that innervated the otoliths [inferior branch otolith (IO) and superior branch otolith (SO)], the anterior canal (AC), the horizontal canal (HC), and the posterior canal (PC). Clicks higher than 60 dB SL (re-auditory brainstem response threshold) activated both semicircular canal and otolith organ afferents. Clicks at or below 60 dB SL, however, activated only otolith organ afferents. Longer duration clicks evoked larger responses in AC, HC, and SO afferents, but not in IO afferents. Intra-axonal recording and labeling confirmed that sound sensitive vestibular afferents innervated the horizontal and anterior canal cristae as well as the saccular and utricular maculae. Interestingly, all sound sensitive afferents are calyx-bearing fibers. These results demonstrate stimulus-dependent acoustic activation of both semicircular canals and otolith organs, and suggest that sound activation of vestibular end organs other than the saccule should not be ruled out when designing and interpreting clinical VEMP tests.

Published

2013

50. Influence of Surgical Plugging on Horizontal Semicircular Canal Mechanics and Afferent Response Dynamics

Author

Richard Boyle, Richard D. Rabbitt, and Stephen M. Highstein

Subjects

Male, Rotation, Physiology, Horizontal semicircular canal, Vestibular disorders, Biomechanical Phenomena, Afferent, Occlusion, Pressure, Animals, Humans, Medicine, Saimiri, Afferent Pathways, business.industry, General Neuroscience, Dynamics (mechanics), Fishes, Anatomy, Surgical Instruments, Semicircular Canals, Vestibular Diseases, Female, business

Abstract

Mechanical occlusion of one or more of the semicircular canals is a surgical procedure performed clinically to treat certain vestibular disorders and used experimentally to assess individual contributions of separate canals and/or otoliths to vestibular neural pathways. The present experiments were designed to determine if semicircular canal afferent nerve modulation to angular head acceleration is blocked by occlusion of the endolymphatic duct, and if not, what mechanism(s) might account for a persistent afferent response. The perilymphatic space was opened to gain acute access to the horizontal canal (HC) in the oyster toadfish, Opsanus tau. Firing rate responses of HC afferents to sinusoidal whole-body rotation were recorded in the unoccluded control condition, during the process of duct occlusion, and in the plugged condition. The results show that complete occlusion of the duct did not block horizontal canal sensitivity; individual afferents often exhibited a robust firing rate modulation in response to whole-body rotation in the plugged condition. At high stimulus frequencies (about8 Hz) the average sensitivity (afferent gain; spikes/s per degrees /s of head velocity) in the plugged condition was nearly equal to that observed for unoccluded controls in the same animals. At low stimulus frequencies (about0.1 Hz), the average sensitivity in the plugged condition was attenuated by more than two orders of magnitude relative to unoccluded controls. The peak afferent firing rate for sinusoidal stimuli was phase advanced approximately 90 degrees in plugged canals relative to their control counterparts for stimulus frequencies approximately 0.1-2 Hz. Data indicate that afferents normally sensitive to angular velocity in the control condition became sensitive to angular acceleration in the plugged condition, whereas afferents sensitive to angular acceleration in the control condition became sensitive to the derivative of acceleration or angular jerk in the plugged condition. At higher frequencies (8 Hz), the phase of afferents in the plugged condition became nearly equal, on average, to that observed in controls. A three-dimensional biomechanical model of the HC was developed to interpret the residual response in the plugged condition. Labyrinthine fluids were modeled as incompressible and Newtonian; the membranous duct, osseous canal and temporal bone were modeled as visco-elastic materials. The predicted attenuation and phase shift in cupular responses were in close agreement with the observed changes in afferent response dynamics after canal plugging. The model attributes the response of plugged canals to labyrinthine fluid pressure gradients that lead to membranous duct deformation, a spatial redistribution of labyrinthine fluids and cupular displacement. Validity of the model was established through its ability to predict: the relationship between plugged canal responses and unoccluded controls (present study), the relationship between afferent responses recorded during mechanical indentation of the membranous duct and physiological head rotation, the magnitude and phase of endolymphatic pressure generated during HC duct indentation, and previous model results for cupular gain and phase in the rigid-duct case. The same model was adjusted to conform to the morphology of the squirrel monkey and of the human to investigate the possible influence of canal plugging in primates. Membranous duct stiffness and perilymphatic cavity stiffness were identified as the most salient model parameters. Simulations indicate that canal plugging may be the most effective in relatively small species having small labyrinths, stiff round windows, and stiff bony perilymphatic enclosures.

Published

1999