Steady-state stiffness of utricular hair cells depends on macular location and hair bundle structure

Spoon, Corrie; Moravec, W. J.; Rowe, Michael H.; Grant, J. Wally; Peterson, E. H.

doi:10.1152/jn.00469.2011

Cited by 23 publications

(16 citation statements)

References 54 publications

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“…Striola receptors are predominantly amphora-shaped type I receptors (37) and have short stiff hair bundles (44, 49), apparently loosely attached to the overlying otolithic membrane (38). This fluid motion within the fluid-filled hole in the gel-filament layer of the otolithic membrane produces a drag force on the hair bundle, causing it to deflect.…”

Section: Physiological Datamentioning

confidence: 99%

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Sustained and Transient Vestibular Systems: A Physiological Basis for Interpreting Vestibular Function

et al. 2017

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Otolithic afferents with regular resting discharge respond to gravity or low-frequency linear accelerations, and we term these the static or sustained otolithic system. However, in the otolithic sense organs, there is anatomical differentiation across the maculae and corresponding physiological differentiation. A specialized band of receptors called the striola consists of mainly type I receptors whose hair bundles are weakly tethered to the overlying otolithic membrane. The afferent neurons, which form calyx synapses on type I striolar receptors, have irregular resting discharge and have low thresholds to high frequency (e.g., 500 Hz) bone-conducted vibration and air-conducted sound. High-frequency sound and vibration likely causes fluid displacement which deflects the weakly tethered hair bundles of the very fast type I receptors. Irregular vestibular afferents show phase locking, similar to cochlear afferents, up to stimulus frequencies of kilohertz. We term these irregular afferents the transient system signaling dynamic otolithic stimulation. A 500-Hz vibration preferentially activates the otolith irregular afferents, since regular afferents are not activated at intensities used in clinical testing, whereas irregular afferents have low thresholds. We show how this sustained and transient distinction applies at the vestibular nuclei. The two systems have differential responses to vibration and sound, to ototoxic antibiotics, to galvanic stimulation, and to natural linear acceleration, and such differential sensitivity allows probing of the two systems. A 500-Hz vibration that selectively activates irregular otolithic afferents results in stimulus-locked eye movements in animals and humans. The preparatory myogenic potentials for these eye movements are measured in the new clinical test of otolith function—ocular vestibular-evoked myogenic potentials. We suggest 500-Hz vibration may identify the contribution of the transient system to vestibular controlled responses, such as vestibulo-ocular, vestibulo-spinal, and vestibulo-sympathetic responses. The prospect of particular treatments targeting one or the other of the transient or sustained systems is now being realized in the clinic by the use of intratympanic gentamicin which preferentially attacks type I receptors. We suggest that it is valuable to view vestibular responses by this sustained-transient distinction.

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Section: Physiological Datamentioning

confidence: 99%

“…Hair cell height and stiffness have been demonstrated to vary across the macula surface (39, 49, 53–55). The cells which do show high-frequency phase locking are from calyx-bearing afferents originating from the striola (21) with shorter stiffer receptor hair cells.…”

Section: Physiological Datamentioning

confidence: 99%

Sustained and Transient Vestibular Systems: A Physiological Basis for Interpreting Vestibular Function

et al. 2017

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“…This turtle species will retain their HC stiffness for periods of 5 h or more with exposure to this bHBSS artificial perilymph solution (Spoon et al 2011). This HC bundle stiffness retention time is well beyond any data collection period utilized here, the maximum being 2 h.…”

Section: Specimen Preparation and Tissue Preservationmentioning

confidence: 99%

Experimental Measurement of Utricle System Dynamic Response to Inertial Stimulus

Dunlap

Grant

2014

JARO

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The membranous utricle sac of the red-eared turtle was mounted in a piezoelectric actuated platform mounted on the stage of a light microscope. The piezoelectric actuator oscillated the base of the neuroepithelium along a linear axis. Displacements were in the plane of the utricle and consisted of a linear sinusoidal-sweep signal starting at 0 and increasing to 500 Hz over 5 s. This inertial stimulus caused measurable shear displacement of the otoconial layer's dorsal surface, resulting in shear deformation of the gelatinous and column filament layers. Displacements of the otoconial layer and a reference point on the neuroepithelium were filmed at 2,000 frames/s with a high-speed video camera during oscillations. Image registration was performed on the video to track displacements with a resolution better than 15 nm. The displacement waveforms were then matched to a linear second-order model of the dynamic system. The model match identified two system mechanical parameters-the natural circular frequency ω n and the damping ratio ζ-that characterized the utricle dynamic response. The median values found for the medial-lateral axis on 20 utricles with 95 % confidence intervals in parenthesis were as follows: ω n = 374 (353, 396)Hz and ζ=0.50 (0.47, 0.53). The anteriorposterior axis values were not significantly different: ω n = 409 (390, 430)Hz and ζ=0.53 (0.48, 0.57). The results have two relevant and significant dynamic system findings: (1) a higher than expected natural frequency and (2) significant under damping. Previous to this study, utricular systems were treated as overdamped and with natural frequencies much lower that measured here. Both of these system performance findings result in excellent utricle time response to acceleration stimuli and a broad frequency bandwidth up to 100 Hz. This study is the first to establish the upper end of this mechanical system frequency response of the utricle in any animal. ρ e -Density of the endolymph; ρ OL -Density of the OL; ω -Excitation frequency; ω n -Undamped natural circular frequency; ζ -Viscous damping factor or damping ratio; γ -Effective shear strain of the SL; τ -Shear stress of the SL acting on the ventral surface of the OL; δ -Deflection of otoconial membrane caused by shear force

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“…In addition, striolar bundles have kinocilia heights that are very close to the thickness of (i.e: they do not protrude into) the CFL. These properties and the "buttressing," described in Spoon et al (2011b) indicate the striola bundles interaction with the OM is strong. Therefore the measured stiffness (41.6 ± 25.4 pN/µm (Grant et al, 2007)) is assumed to fully contribute to the shear resistance of the CFL; that is to say the in-vitro measurement of the physiological stiffness of the hair bundle should be very close to as if it would behave in-vivo (Spoon et al, 2011b).…”

Section: Methodsmentioning

confidence: 89%

“…Typical methods that characterize bundle stiffness require measurements at the kinocilium tip: Force applied at the tip of kinocilium divided by linear displacement at the tip of kinocilium (Crawford et al, 1985; Flock et al, 1984; Howard et al, 1986; Spoon et al, 2005; Spoon et al, 2011b; Strelioff et al, 1984). These experiments are then modeled with finite elements using Euler-Bernoulli beam theory (Cotton et al, 2004a; Cotton et al, 2004b; Nam et al, 2005; Silber et al, 2004) which includes the mechanics of bundle and the effect of both moments and shear on the displacement and bending (Beer et al, 2006).…”

Section: Methodsmentioning

confidence: 99%

Turtle utricle dynamic behavior using a combined anatomically accurate model and experimentally measured hair bundle stiffness

Davis

Grant

2014

Hearing Research

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Anatomically correct turtle utricle geometry was incorporated into two finite element models. The geometrically accurate model included appropriately shaped macular surface and otoconial layer, compact gel and column filament (or shear) layer thicknesses and thickness distributions. The first model included a shear layer where the effects of hair bundle stiffness was included as part of the shear layer modulus. This solid model’s undamped natural frequency was matched to an experimentally measured value. This frequency match established a realistic value of the effective shear layer Young’s modulus of 16 Pascals. We feel this is the most accurate prediction of this shear layer modulus and fits with other estimates (Kondrachuk, 2001b). The second model incorporated only beam elements in the shear layer to represent hair cell bundle stiffness. The beam element stiffness’s were further distributed to represent their location on the neuroepithelial surface. Experimentally measured striola hair cell bundles mean stiffness values were used in the striolar region and the mean extrastriola hair cell bundles stiffness values were used in this region. The results from this second model indicated that hair cell bundle stiffness contributes approximately 40% to the overall stiffness of the shear layer– hair cell bundle complex. This analysis shows that high mass saccules, in general, achieve high gain at the sacrifice of frequency bandwidth. We propose the mechanism by which this can be achieved is through increase the otoconial layer mass. The theoretical difference in gain (deflection per acceleration) is shown for saccules with large otoconial layer mass relative to saccules and utricles with small otoconial layer mass. Also discussed is the necessity of these high mass saccules to increase their overall system shear layer stiffness. Undamped natural frequencies and mode shapes for these sensors are shown.

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Steady-state stiffness of utricular hair cells depends on macular location and hair bundle structure

Cited by 23 publications

References 54 publications

Sustained and Transient Vestibular Systems: A Physiological Basis for Interpreting Vestibular Function

Sustained and Transient Vestibular Systems: A Physiological Basis for Interpreting Vestibular Function

Experimental Measurement of Utricle System Dynamic Response to Inertial Stimulus

Turtle utricle dynamic behavior using a combined anatomically accurate model and experimentally measured hair bundle stiffness

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