- Title
- Preliminary characterization of voltage-activated whole-cell currents in developing human vestibular hair cells and calyx afferent terminals
- Creator
- Lim, Rebecca; Drury, Hannah R.; Camp, Aaron J.; Tadros, Melissa A.; Callister, Robert J.; Brichta, Alan M.
- Relation
- Journal of the Association for Research in Otolaryngology Vol. 15, Issue 5, p. 755-766
- Publisher Link
- http://dx.doi.org/10.1007/s10162-014-0471-y
- Publisher
- Springer
- Resource Type
- journal article
- Date
- 2014
- Description
- We present preliminary functional data from human vestibular hair cells and primary afferent calyx terminals during fetal development. Whole-cell recordings were obtained from hair cells or calyx terminals in semi-intact cristae prepared from human fetuses aged between 11 and 18 weeks gestation (WG). During early fetal development (11–14 WG), hair cells expressed whole-cell conductances that were qualitatively similar but quantitatively smaller than those observed previously in mature rodent type II hair cells. As development progressed (15–18 WG), peak outward conductances increased in putative type II hair cells but did not reach amplitudes observed in adult human hair cells. Type I hair cells express a specific low-voltage activating conductance, G K,L. A similar current was first observed at 15 WG but remained relatively small, even at 18 WG. The presence of a “collapsing” tail current indicates a maturing type I hair cell phenotype and suggests the presence of a surrounding calyx afferent terminal. We were also able to record from calyx afferent terminals in 15–18 WG cristae. In voltage clamp, these terminals exhibited fast inactivating inward as well as slower outward conductances, and in current clamp, discharged a single action potential during depolarizing steps. Together, these data suggest the major functional characteristics of type I and type II hair cells and calyx terminals are present by 18 WG. Our study also describes a new preparation for the functional investigation of key events that occur during maturation of human vestibular organs.
- Subject
- electrophysiology; human; hair cells; vestibular; development
- Identifier
- http://hdl.handle.net/1959.13/1063232
- Identifier
- uon:17231
- Identifier
- ISSN:1525-3961
- Language
- eng
- Full Text
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