Hearing Mechanisms and Noise Metrics Related to Auditory Masking in Bottlenose Dolphins (Tursiops truncatus)

• Published in: Advances in experimental medicine and biology Vol. 875; p. 109
• Main Authors: Branstetter, Brian K, Bakhtiari, Kimberly L, Trickey, Jennifer S, Finneran, James J
• Format: Journal Article
• Language: English
• Published: United States 01.01.2016
• Subjects: Animals; Auditory Perception - physiology; Bottle-Nosed Dolphin - physiology; Hearing - physiology; Models, Theoretical; Noise; Perceptual Masking - physiology; Sound Spectrography; Comodulation; Detection; Signal
• ISSN: 0065-2598
• DOI: 10.1007/978-1-4939-2981-8_13

Odontocete cetaceans are acoustic specialists that depend on sound to hunt, forage, navigate, detect predators, and communicate. Auditory masking from natural and anthropogenic sound sources may adversely affect these fitness-related capabilities. The ability to detect a tone in a broad range of natural, anthropogenic, and synthesized noise was tested with bottlenose dolphins using a psychophysical, band-widening procedure. Diverging masking patterns were found for noise bandwidths greater than the width of an auditory filter. Despite different noise types having equal-pressure spectral-density levels (95 dB re 1 μPa(2)/Hz), masked detection threshold differences were as large as 22 dB. Consecutive experiments indicated that noise types with increased levels of amplitude modulation resulted in comodulation masking release due to within-channel and across-channel auditory mechanisms. The degree to which noise types were comodulated (comodulation index) was assessed by calculating the magnitude-squared coherence between the temporal envelope from an auditory filter centered on the signal and temporal envelopes from flanking filters. Statistical models indicate that masked thresholds in a variety of noise types, at a variety of levels, can be explained with metrics related to the comodulation index in addition to the pressure spectral-density level of noise. This study suggests that predicting auditory masking from ocean noise sources depends on both spectral and temporal properties of the noise.