Topography of Auditory Nerve Projections to the Cochlear Nucleus in Cats after Neonatal Deafness and Electrical Stimulation by a Cochlear Implant

Leake, Patricia A.; Hradek, Gary T.; Bonham, Ben H.; Snyder, Russell L.

doi:10.1007/s10162-008-0127-x

Cited by 29 publications

(19 citation statements)

References 97 publications

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“…Surprisingly, despite the significantly shorter deafness durations and higher SGC survival, training-induced enhancements in temporal following ability in these animals remained significantly below that of behaviorally trained long-deaf animals [LDS(ϩ) group]. These findings underscore that the potent efficacy of training-induced temporal plasticity is not limited by long-term deafness and its deleterious effects on peripheral (e.g., Leake and Hradek 1988;Vollmer et al 2007) and central morpholog (e.g., Leake et al 2008;Lustig et al 1994;Nishiyama et al 2000).…”

Section: Discussionmentioning

confidence: 65%

Behavioral training restores temporal processing in auditory cortex of long-deaf cats

Vollmer

Beitel

2011

Journal of Neurophysiology

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Temporal auditory processing is poor in prelingually hearing-impaired patients fitted with cochlear prostheses as adults. In an animal model of prelingual long-term deafness, we investigated the effects of behavioral training on temporal processing in the adult primary auditory cortex (AI). Neuronal responses to pulse trains of increasing frequencies were recorded in three groups of neonatally deafened cats that received a cochlear prosthesis after >3 yr of deafness: 1) acutely implanted animals that received no electric stimulation before study, 2) animals that received chronic-passive stimulation for several weeks to months before study, and 3) animals that received chronic-passive stimulation and additional behavioral training (signal detection). A fourth group of normal adult cats that was deafened acutely and implanted served as controls. The neuronal temporal response parameters of interest included the stimulus rate that evoked the maximum number of phase-locked spikes [best repetition rate (BRR)], the stimulus rate that produced 50% of the spike count at BRR (cutoff rate), the peak-response latency, and the first spike latency and timing-jitter. All long-deaf animals demonstrated a severe reduction in spiral ganglion cell density (mean, <6% of normal). Long-term deafness resulted in a significantly reduced temporal following capacity and spike-timing precision of cortical neurons in all parameters tested. Neurons in deaf animals that received only chronic-passive stimulation showed a gain in BRR but otherwise were similar to deaf cats that received no stimulation. In contrast, training with behaviorally relevant stimulation significantly enhanced all temporal processing parameters to normal levels with the exception of minimum latencies. These results demonstrate the high efficacy of learning-based remodeling of fundamental timing properties in cortical processing even in the adult, long-deaf auditory system, suggesting rehabilitative strategies for patients with long-term hearing loss.

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Section: Discussionmentioning

confidence: 65%

Behavioral training restores temporal processing in auditory cortex of long-deaf cats

Vollmer

Beitel

2011

Journal of Neurophysiology

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“…Alteration in the SG neuronal membrane properties or channels also could account for the observed EABR threshold reductions. Alternatively, it should also be noted that previous animal studies have shown that lower EABR thresholds are correlated with better SG survival in the cochlear region near the stimulating electrodes (Leake et al 2008b). Thus, it may be possible that some neurons initially unresponsive to electrical stimulation, due to ototoxic drug administration effects, become viable and responsive during BDNF treatment.…”

Section: Longitudinal Eabr Threshold Datamentioning

confidence: 98%

“…Electrical stimulation from a CI has also been shown to promote SG survival in vivo in deafened adult guinea pigs (Hartshorn et al 1991;Kanzaki et al 2002;Lousteau 1987;Miller 2001;Miller and Altschuler 1995;Mitchell et al 1997) and in cats deafened early in life (Leake et al 1999(Leake et al , 2007(Leake et al , 2008b). In our laboratory, studies of cats deafened prior to hearing onset have shown that multichannel CI electrical stimulation applied over several months results in substantial improvement in SG neural survival (Leake et al 1999(Leake et al , 2007(Leake et al , 2008a above that seen in the contralateral deafened cochleae. Other studies, however, have not found evidence of trophic effects of electrical stimulation (Araki et al 1998;Coco et al 2007;Li et al 1999;Shepherd et al 1994).…”

Section: Introductionmentioning

confidence: 99%

“…These disparities in findings suggest that differences among animal models, methods of stimulation (e.g., the position of stimulating electrodes, applied signals, and efficacy in exciting neurons across a broad sector of the spiral ganglion), and/or methods of analysis of SG density are critically important. But even in studies showing highly significant trophic effects, electrical stimulation only partly prevents SG degeneration after deafness (Leake et al 2008b). Thus, there has been considerable recent interest in neurotrophic agents that might be used in conjunction with cochlear implantation to enhance SG and auditory nerve survival (see Staecker et al 2010).…”

Section: Introductionmentioning

confidence: 99%

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Effects of Brain-Derived Neurotrophic Factor (BDNF) and Electrical Stimulation on Survival and Function of Cochlear Spiral Ganglion Neurons in Deafened, Developing Cats

Leake

Stakhovskaya

Hetherington

et al. 2013

JARO

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Both neurotrophic support and neural activity are required for normal postnatal development and survival of cochlear spiral ganglion (SG) neurons. Previous studies in neonatally deafened cats demonstrated that electrical stimulation (ES) from a cochlear implant can promote improved SG survival but does not completely prevent progressive neural degeneration. Neurotrophic agents combined with an implant may further improve neural survival. Short-term studies in rodents have shown that brain-derived neurotrophic factor (BDNF) promotes SG survival after deafness and may be additive to trophic effects of stimulation. Our recent study in neonatally deafened cats provided the first evidence of BDNF neurotrophic effects in the developing auditory system over a prolonged duration Leake et al. (J Comp Neurol 519:1526-1545. Ten weeks of intracochlear BDNF infusion starting at 4 weeks of age elicited significant improvement in SG survival and larger soma size compared to contralateral. In the present study, the same deafening and BDNF infusion procedures were combined with several months of ES from an implant. After combined BDNF + ES, a highly significant increase in SG numerical density (950 % improvement re: contralateral) was observed, which was significantly greater than the neurotrophic effect seen with ES-only over comparable durations. Combined BDNF + ES also resulted in a higher density of myelinated radial nerve fibers within the osseous spiral lamina. However, substantial ectopic and disorganized sprouting of these fibers into the scala tympani also occurred, which may be deleterious to implant function. EABR thresholds improved (re: initial thresholds at time of implantation) on the chronically stimulated channels of the implant. Terminal electrophysiological studies recording in the inferior colliculus (IC) revealed that the basic cochleotopic organization was intact in the midbrain in all studied groups. In deafened controls or after ES-only, lower IC thresholds were correlated with more selective activation widths as expected, but no such correlation was seen after BDNF + ES due to much greater variability in both measures.

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“…Digital images of sections were captured using a Zeiss Axioskop 2, a 2.5× objective and a Zeiss AxioCam MRc5 digital camera. Cytoarchitectural criteria according to Kiang et al, (1975); Leake et al, (2002); Leake et al,(2008); Stakhovskaya et al, (2008) were utilized to outline the three individual CN subdivisions in each imaged section (excluding the cochlear nerve root). The boundary between the DCN and the PVCN was defined by the intermediate acoustic stria in caudal sections and using the granule cell layer as a landmark in more rostral sections.…”

Section: Methodsmentioning

confidence: 99%

Effects of brain-derived neurotrophic factor (BDNF) on the cochlear nucleus in cats deafened as neonates

2016

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Many previous studies have shown significant neurotrophic effects of intracochlear delivery of BDNF in preventing degeneration of cochlear spiral ganglion (SG) neurons after deafness in rodents and our laboratory has shown similar results in developing cats deafened prior to hearing onset. This study examined the morphology of the cochlear nucleus (CN) in a group of neonatally deafened cats from a previous study in which infusion of BDNF elicited a significant improvement in survival of the SG neurons. Five cats were deafened by systemic injections of neomycin sulfate (60mg/kg, SQ, SID) starting one day after birth, and continuing for 16–18 days until auditory brainstem response (ABR) testing demonstrated profound bilateral hearing loss. The animals were implanted unilaterally at about 1 month of age using custom-designed electrodes with a drug-delivery cannula connected to an osmotic pump. BDNF (94μg/ml; 0.25μl/hr) was delivered for 10 weeks. The animals were euthanized and studied at 14–23 weeks of age. Consistent with the neurotrophic effects of BDNF on SG survival, the total CN volume in these animals was significantly larger on the BDNF-treated side than on the contralateral side. However, total CN volume, both ipsi- and contralateral to the implants in these deafened juvenile animals, was markedly smaller than the CN in normal adult animals, reflecting the severe effects of deafness on the central auditory system during development. Data from the individual major CN subdivisions (DCN, Dorsal Cochlear Nucleus; PVCN, Posteroventral Cochlear Nucleus; AVCN, Anteroventral Cochlear Nucleus) also were analyzed. A significant difference was observed between the BDNF-treated and control sides only in the AVCN. Measurements of the cross-sectional areas of spherical cells showed that cells were significantly larger in the AVCN ipsilateral to the implant than on the contralateral side. Further, the numerical density of spherical cells was significantly lower in the AVCN ipsilateral to the implant than on the contralateral side, consistent with the larger AVCN volume observed with BDNF treatment. Together, findings indicate significant neurotrophic effects of intracochlear BDNF infusion on the developing CN.

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Topography of Auditory Nerve Projections to the Cochlear Nucleus in Cats after Neonatal Deafness and Electrical Stimulation by a Cochlear Implant

Cited by 29 publications

References 97 publications

Behavioral training restores temporal processing in auditory cortex of long-deaf cats

Behavioral training restores temporal processing in auditory cortex of long-deaf cats

Effects of Brain-Derived Neurotrophic Factor (BDNF) and Electrical Stimulation on Survival and Function of Cochlear Spiral Ganglion Neurons in Deafened, Developing Cats

Effects of brain-derived neurotrophic factor (BDNF) on the cochlear nucleus in cats deafened as neonates

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