Nesrien Mohamed Mohammad Al-Amin Frances Meredith Olivia Kalmanson Anna Dondzillo Stephen Cass Samuel Gubbels Katherine Janet Rennie ^*

• University of Colorado Anschutz Medical Campus, Aurora, Colorado, United States

Our sense of balance depends heavily on signals originating in vestibular hair cells of the inner ear.Many studies have been carried out in rodent vestibular hair cells and data from hair cells of human vestibular organs are scant. In this study we report electrophysiological recordings from isolated vestibular sensory hair cells obtained from patients undergoing translabyrinthine surgeries for vestibular schwannoma removal. Previous studies have reported that hair cell loss and regeneration may occur in vestibular schwannoma patients and hair cell replacement is a promising therapeutic avenue to correct vestibular dysfunction. We found membrane features of isolated human vestibular hair cells resemble those of mature rodent hair cells in several electrophysiological and pharmacological aspects. Type I vestibular hair cells were found to have more negative resting potentials and low voltage-activated K + currents compared to type II hair cells which had delayed rectifier outward K + currents that activated above resting potential. Identifying physiological properties of human hair cells and understanding their roles in vestibular function is needed to inform future inner ear therapies.