Longitudinal effect of deactivating stimulation sites based on low-rate thresholds on speech recognition in cochlear implant users

Abstract

Objective: The objective of the current study was to examine the longitudinal effect of deactivating stimulation sites estimated to produce broad neural excitation on speech recognition.

Design: Spatial patterns of neural excitation were estimated based on a previously established psychophysical measure, that is, detection threshold for low-rate pulse trains. Stimulation sites with relatively poor thresholds were deactivated in an experimental map. The acute effect was evaluated, in quiet and in noise, immediately after the experimental map was created (baseline), after the subjects practiced with the experimental map for two months (treatment), and after the subjects’ daily map was switched back again to the clinical map for another two months (withdrawal).

Study sample: Eight Cochlear Nucleus device users participated in the study.

Results: For both listening in noise and in quiet, the greatest effect of deactivation was observed after the subjects were given time to adapt to the new frequency allocations. The effect was comparable for listening in fluctuating and steady-state noises. All subjects benefited from deactivation for listening in noise, but subjects with greater variability in thresholds were more likely to benefit from deactivation for listening in quiet.

Conclusion: The benefit of electrode deactivation for speech recognition can increase with practice.

Keywords:

• Low-rate thresholds
• speech perception
• longitudinal effects
• electrode deactivation

Acknowledgments

We would like to thank our dedicated cochlear implant participants.

Disclosure statement

No potential conflict of interest was reported by the author.

Additional information

Funding

This work was supported by NIH NIDCD [R03DC014771-01A1].