Browsing by Author "Minter, Ricki"

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    Challenges for stem cells to functionally repair the damaged auditory nerve.
    (Informa Healthcare, 2013-01) Needham, Karina; Minter, Ricki; Shepherd, Robert; Nayagam, Bryony
    INTRODUCTION: In the auditory system, a specialized subset of sensory neurons are responsible for correctly relaying precise pitch and temporal cues to the brain. In individuals with severe-to-profound sensorineural hearing impairment these sensory auditory neurons can be directly stimulated by a cochlear implant, which restores sound input to the brainstem after the loss of hair cells. This neural prosthesis therefore depends on a residual population of functional neurons in order to function effectively. AREAS COVERED: In severe cases of sensorineural hearing loss where the numbers of auditory neurons are significantly depleted, the benefits derived from a cochlear implant may be minimal. One way in which to restore function to the auditory nerve is to replace these lost neurons using differentiated stem cells, thus re-establishing the neural circuit required for cochlear implant function. Such a therapy relies on producing an appropriate population of electrophysiologically functional neurons from stem cells, and on these cells integrating and reconnecting in an appropriate manner in the deaf cochlea. EXPERT OPINION: Here we review progress in the field to date, including some of the key functional features that stem cell-derived neurons would need to possess and how these might be enhanced using electrical stimulation from a cochlear implant.
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    Time-dependent activity of primary auditory neurons in the presence of neurotrophins and antibiotics
    (Elsevier, 2017-04) Cai, Helen; Gillespie, Lisa; Wright, Tess; Brown, William; Minter, Ricki; Nayagam, Bryony; O'Leary, Stephen; Needham, Karina
    In vitro cultures provide a valuable tool in studies examining the survival, morphology and function of cells in the auditory system. Primary cultures of primary auditory neurons have most notably provided critical insights into the role of neurotrophins in cell survival and morphology. Functional studies have also utilized in vitro models to study neuronal physiology and the ion channels that dictate these patterns of activity. Here we examine what influence time-in-culture has on the activity of primary auditory neurons, and how this affects our interpretation of neurotrophin and antibiotic-mediated effects in this population. Using dissociated cell culture we analyzed whole-cell patch-clamp recordings of spiral ganglion neurons grown in the presence or absence of neurotrophins and/or penicillin and streptomycin for 1-3 days in vitro. Firing threshold decreased, and both action potential number and latency increased over time regardless of treatment, whilst input resistance was lowest where neurotrophins were present. Differences in firing properties were seen with neurotrophin concentration but were not consistently maintained over the 3 days in vitro. The exclusion of antibiotics from culture media influenced most firing properties at 1 day in vitro in both untreated and neurotrophin-treated conditions. The only difference still present at 3 days was an increase in input resistance in neurotrophin-treated neurons. These results highlight the potential of neurotrophins and antibiotics to influence neural firing patterns in vitro in a time-dependent manner, and advise the careful consideration of their impact on SGN function in future studies.