G Zucca scite author profile

The electrophysiological properties of developing vestibular hair cells have been investigated in a chick crista slice preparation, from embryonic day 10 (E10) to E21 (when hatching would occur). Patch-clamp whole-cell experiments showed that different types of ion channels are sequentially expressed during development. An inward Ca(2+) current and a slow outward rectifying K(+) current (I(K(V))) are acquired first, at or before E10, followed by a rapid transient K(+) current (I(K(A))) at E12, and by a small Ca-dependent K(+) current (I(KCa)) at E14. Hair cell maturation then proceeds with the expression of hyperpolarization-activated currents: a slow I(h) appears first, around E16, followed by the fast inward rectifier I(K1) around E19. From the time of its first appearance, I(K(A)) is preferentially expressed in peripheral (zone 1) hair cells, whereas inward rectifying currents are preferentially expressed in intermediate (zone 2) and central (zone 3) hair cells. Each conductance conferred distinctive properties on hair cell voltage response. Starting from E15, some hair cells, preferentially located at the intermediate region, showed the amphora shape typical of type I hair cells. From E17 (a time when the afferent calyx is completed) these cells expressed I(K, L), the signature current of mature type I hair cells. Close to hatching, hair cell complements and regional organization of ion currents appeared similar to those reported for the mature avian crista. By the progressive acquisition of different types of inward and outward rectifying currents, hair cell repolarization after both positive- and negative-current injections is greatly strengthened and speeded up.

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Why Do Benign Paroxysmal Positional Vertigo Episodes Recover Spontaneously?

Zucca

Valli

et al. 1998

VES

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It is well known that most episodes of benign paroxysmal positional vertigo (BPPV), even in untreated, recover spontaneously in 2 to 6 weeks. In the present study, we put forward the hypothesis that this is mainly due to the fact that endolymph, owing to its low calcium content (20μM) is able to dissolve otoconia. To support this, the fate of frog saccular otoconia immersed in normal endolymph (Ca2+ content 20μM) and in Ca2+-rich endolymphatic fluids (up to 500μM) was studied by observing the crystals at regular intervals for 3 weeks. The results demonstrated that normal endolymph can dissolve otoconia very rapidly (in about 20 hours). When the endolymphatic Ca2+ content was increased (50 to 200μM) otoconia dissolution time was slowed down (about 100 to 130 hours, respectively) and completely stopped when the endolymphatic Ca2+ content was of 500μM. The present results therefore suggest that the major process involved in the spontaneous recovery of BPPV episodes is the capability of the endolymph to dissolve dislodged otoconia.

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Na⁺ Currents in Vestibular Type I and Type II Hair Cells of the Embryo and Adult Chicken

Masetto

Bosica

Correia

et al. 2003

Journal of Neurophysiology

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In birds, type I and type II hair cells differentiate before birth. Here we describe that chick hair cells, from the semicircular canals, begin expressing a voltage-dependent Na current (INa) from embryonic day 14 (E14) and continue to express the current up to hatching (E21). During this period, INa was present in most (31/43) type I hair cells irrespective of their position in the crista, in most type II hair cells located far from the planum semilunatum (48/63), but only occasionally in type II hair cells close to the planum semilunatum (2/35). INa activated close to -60 mV, showed fast time- and voltage-dependent activation and inactivation, and was completely, and reversibly, blocked by submicromolar concentrations of tetrodotoxin (Kd = 17 nM). One peculiar property of INa concerns its steady-state inactivation, which is complete at -60 mV (half-inactivating voltage = -96 mV). INa was found in type I and type II hair cells from the adult chicken as well, where it had similar, although possibly not identical, properties and regional distribution. Current-clamp experiments showed that INa could contribute to the voltage response provided that the cell membrane was depolarized from holding potentials more negative than -80 mV. When recruited, INa produced a significant acceleration of the cell membrane depolarization, which occasionally elicited a large rapid depolarization followed by a rapid repolarization (action-potential-like response). Possible physiological roles for INa in the embryo and adult chicken are discussed.

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The metabotropic glutamate receptors of the vestibular organs

et al. 1998

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Regional distribution of calcium currents in frog semicircular canal hair cells

et al. 2001

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G Zucca

Membrane Properties of Chick Semicircular Canal Hair Cells In Situ During Embryonic Development

Why Do Benign Paroxysmal Positional Vertigo Episodes Recover Spontaneously?

Na⁺ Currents in Vestibular Type I and Type II Hair Cells of the Embryo and Adult Chicken

The metabotropic glutamate receptors of the vestibular organs

Regional distribution of calcium currents in frog semicircular canal hair cells

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G Zucca

Membrane Properties of Chick Semicircular Canal Hair Cells In Situ During Embryonic Development

Why Do Benign Paroxysmal Positional Vertigo Episodes Recover Spontaneously?

Na+ Currents in Vestibular Type I and Type II Hair Cells of the Embryo and Adult Chicken

The metabotropic glutamate receptors of the vestibular organs

Regional distribution of calcium currents in frog semicircular canal hair cells

Contact Info

Product

Resources

About

Na⁺ Currents in Vestibular Type I and Type II Hair Cells of the Embryo and Adult Chicken