Hearing research
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Comparative Study
Action potentials and underlying voltage-dependent currents studied in cultured spiral ganglion neurons of the postnatal gerbil.
The excitability of cultured spiral ganglion (SG) neurons from early postnatal gerbil (P0-P1) was examined with the whole-cell patch-clamp technique. The role of voltage-gated currents in shaping the kinetics of action potentials (APs) was analyzed. Cultured SG neurons displayed spontaneous APs with a low rate (< 0.1 Hz). ⋯ More importantly, inactivation properties of the potassium current provided a direct explanation for the cumulative broadening of APs. This work demonstrated that SG neurons were able to fire APs long before hearing commences in gerbil. Possible roles of spontaneous APs in the development of the cochlea and the role of voltage-gated currents in the function of SG neurons under normal and pathological conditions are discussed.
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Current theories assume that the outer hair cells (OHC) are responsible for the sharp tuning and exquisite sensitivity of the ear whereas inner hair cells (IHC) are mainly responsible for transmitting acoustic information to the central nervous system. To further evaluate this model, we used a single (38 mg/kg) or double dose (38 mg/kg, 2 times) of carboplatin to produce a moderate (20-28%) or severe (60-95%) IHC loss while sparing a large proportion of the OHCs. The surviving OHCs were functionally intact as indicated by normal cochlear microphonic (CM) potentials and distortion product otoacoustic emissions (DPOAE). ⋯ These results indicate that intact IHCs can retain relatively normal sensitivity and tuning despite massive IHC loss in surrounding regions of the cochlea. However, the spontaneous and driven discharge rates of neurons in the carboplatin-treated animals were significantly lower than normal. These changes could conceivably be due to sublethal damage to surviving IHCs or to postsynaptic dysfunction in the auditory nerve.
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Comparative Study
Chronic electrical stimulation of the auditory nerve at high stimulus rates: a physiological and histopathological study.
A major factor associated with recent improvements in the clinical performance of cochlear implant patients has been the development of speech-processing strategies based on high stimulation rates. While these processing strategies show clear clinical advantage, we know little of their long-term safety implications. The present study was designed to evaluate the physiological and histopathological effects of long-term intracochlear electrical stimulation using these high rates. ⋯ Finally, electrode impedance, measured at completion of the chronic stimulation program, showed close correlation with the degree of tissue response adjacent to the electrode array. These results indicated that chronic intracochlear electrical stimulation, using carefully controlled charge-balanced biphasic current pulses at stimulus rates of up to 2000 pps/channel, does not appear to adversely affect residual auditory nerve elements or the cochlea in general. This study provides an important basis for the safe application of improved speech-processing strategies based on high-rate electrical stimulation.
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Comparative Study
Effects of chronic high-rate electrical stimulation on the cochlea and eighth nerve in the deafened guinea pig.
This study was undertaken to examine the effects of chronic high-rate stimulation on the eighth nerve and cochlea. Fifty-four male pigmented guinea pigs were deafened and implanted with single ball electrodes in scala tympani. Four groups of animals received chronic electrical stimulation at a level of 5 microCol/cm2/ph for 1000 h as follows: Group A: 1000 Hz, 100 microseconds/ph duration, 100 microA peak; Group B: 250 Hz, 100 microseconds/ph duration, 100 microA peak; Group C: 2750 Hz, 36 microseconds/ph duration, 250 microA peak; Group D: 250 Hz, 400 microseconds/ph duration, 25 microA peak. ⋯ All stimulation conditions enhanced survival of SGCs compared to unimplanted ears and implanted non-stimulated ears (Group F). There were no statistically significant differences in SGC survival between any stimulated groups, including Group E stimulated once a week. In conclusion, high-rate stimulation, under the conditions of this study, provides no additional risks and the same benefits to SGC survival as low-rate stimulation.
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Comparative Study
Otoconial formation in the chick: changing patterns of tetracycline incorporation during embryonic development and after hatching.
The antibiotic tetracycline (TC) is incorporated into calcifying tissues and serves as a fluorescent marker for identifying calcifying sites in bone and otoconia. Fluorescent labeling was performed at different stages in chick embryos and newly hatched chicks. The stagewise changes in the intensity, location and time course of fluorescent labeling were assessed. ⋯ TC, which competes for calcium binding sites, may inhibit the formation of some otoconia. The formation of giant otoconia may reflect subtle changes in the crystallization microenvironment on these occasions. In brief, the results suggest that: (a) otoconial formation in the saccule precedes that of the utricle and lagena; (b) otoconial formation occurs during the early period (beginning the 6th ED); (c) otoconial formation is stratified, with those in the upper layer forming first and those in the lower layer forming last.