[HTML][HTML] Topographic spread of inferior colliculus activation in response to acoustic and intracochlear electric stimulation

RL Snyder, JA Bierer, JC Middlebrooks - Journal of the Association for …, 2004 - Springer
RL Snyder, JA Bierer, JC Middlebrooks
Journal of the Association for Research in Otolaryngology, 2004Springer
The design of contemporary multichannel cochlear implants is predicated on the
presumption that they activate multiple independent sectors of the auditory nerve array. The
independence of these channels, however, is limited by the spread of activation from each
intracochlear electrode across the auditory nerve array. In this study, we evaluated factors
that influence intracochlear spread of activation using two types of intracochlear
electrodes:(1) a clinical-type device consisting of a linear series of ring contacts positioned …
Abstract
The design of contemporary multichannel cochlear implants is predicated on the presumption that they activate multiple independent sectors of the auditory nerve array. The independence of these channels, however, is limited by the spread of activation from each intracochlear electrode across the auditory nerve array. In this study, we evaluated factors that influence intracochlear spread of activation using two types of intracochlear electrodes: (1) a clinical-type device consisting of a linear series of ring contacts positioned along a silicon elastomer carrier, and (2) a pair of visually placed (VP) ball electrodes that could be positioned independently relative to particular intracochlear structures, e.g., the spiral ganglion. Activation spread was estimated by recording multineuronal evoked activity along the cochleotopic axis of the central nucleus of the inferior colliculus (ICC). This activity was recorded using silicon-based single-shank, 16-site recording probes, which were fixed within the ICC at a depth defined by responses to acoustic tones. After deafening, electric stimuli consisting of single biphasic electric pulses were presented with each electrode type in various stimulation configurations (monopolar, bipolar, tripolar) and/or various electrode orientations (radial, off-radial, longitudinal). The results indicate that monopolar (MP) stimulation with either electrode type produced widepread excitation across the ICC. Bipolar (BP) stimulation with banded pairs of electrodes oriented longitudinally produced activation that was somewhat less broad than MP stimulation, and tripolar (TP) stimulation produced activation that was more restricted than MP or BP stimulation. Bipolar stimulation with radially oriented pairs of VP ball electrodes produced the most restricted activation. The activity patterns evoked by radial VP balls were comparable to those produced by pure tones in normal-hearing animals. Variations in distance between radially oriented VP balls had little effect on activation spread, although increases in interelectrode spacing tended to reduce thresholds. Bipolar stimulation with longitudinally oriented VP electrodes produced broad activation that tended to broaden as the separation between electrodes increased.
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