Electrical response properties of avian lagena type II hair cells: a model system for vestibular filtering

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Am J Physiol Regul Integr Comp Physiol 276: R943-R953, 1999;
0363-6119/99 $5.00

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Vol. 276, Issue 4, R943-R953, April 1999

Electrical response properties of avian lagena type II hair cells: a model system for vestibular filtering

Anthony J. Ricci¹ and Manning J. Correia¹^,²

Departments of ¹ Otolaryngology and ² Physiology and Biophysics, University of Texas Medical Branch at Galveston, Galveston, Texas 77555-1031

Data presented represent the first electrical recordings from avian lagena type II hair cells. The perforated-patch variantof the whole cell recording technique was used to investigatehow the macroscopic currents shaped the voltage response of thehair cells. Voltage-clamp data separated cells into two broadclasses on the basis of differences in activation rates, ratesand degree of inactivation, and pharmacological sensitivity. Current-clamprecordings revealed low-quality membrane voltage oscillations(Q_c < 1) during pulse current injections. Oscillation frequencycorrelated with activation rate of the macroscopic currents. Thequality of membrane oscillations (Q_c) varied linearly with frequencyfor cells with little inactivation. For cells with rapid inactivation,no relationship was found between Q_c and frequency. Rapid inactivationmay serve to extend the bandwidth of vestibular hair cells. Thefrequency measured from voltage responses to pulsed currents mayreflect the corner frequency of the cell. The filtering propertiesof avian lagena hair cells are like those found in all other vestibularend organs, suggesting that the electrical membrane propertiesof these cells are not responsible for specializing them to aparticular stimulusmodality.

perforated patch; vestibular end organs; potassium channels; membrane filter; inactivation

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