Oscillatory discharges in the auditory midbrain of the big brown bat contribute to coding of echo delay

Subsequent to his breakthrough discovery of delay-tuned neurons in the bat’s auditory midbrain and cortex, Albert Feng proposed that neural computations for echo delay involve intrinsic oscillatory discharges generated in the inferior colliculus (IC). To explore further the presence of these neural...

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Bibliographic Details
Published in:Journal of Comparative Physiology 2023, Vol.209 (1), p.173-187
Main Authors: Simmons, James A., Simmons, Andrea Megela
Format: Article
Language:English
Subjects:
Acoustic Stimulation
Animal Physiology
Animals
Auditory Cortex - physiology
Auditory Perception - physiology
Bats
Biomedical and Life Sciences
Carollia perspicillata
Chiroptera - physiology
Delay
Discharge
Echoes
Echolocation - physiology
Eptesicus fuscus
Inferior Colliculi - physiology
Inferior colliculus
Latency
Life Sciences
Mesencephalon
Neural coding
Neurosciences
Original Paper
Oscillations
Unit activity
Zoology
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Summary:Subsequent to his breakthrough discovery of delay-tuned neurons in the bat’s auditory midbrain and cortex, Albert Feng proposed that neural computations for echo delay involve intrinsic oscillatory discharges generated in the inferior colliculus (IC). To explore further the presence of these neural oscillations, we recorded multiple unit activity with a novel annular low impedance electrode from the IC of anesthetized big brown bats and Seba’s short-tailed fruit bats. In both species, responses to tones, noise bursts, and FM sweeps contain long latency components, extending up to 60 ms post-stimulus onset, organized in periodic, oscillatory-like patterns at frequencies of 360–740 Hz. Latencies of this oscillatory activity resemble the wide distributions of single neuron response latencies in the IC. In big brown bats, oscillations lasting up to 30 ms after pulse onset emerge in response to single FM pulse–echo pairs, at particular pulse–echo delays. Oscillatory responses to pulses and evoked responses to echoes overlap extensively at short echo delays (5–7 ms), creating interference-like patterns. At longer echo delays, responses are separately evident to both pulses and echoes, with less overlap. These results extend Feng’s reports of IC oscillations, and point to different processing mechanisms underlying perception of short vs long echo delays.
ISSN:0340-7594
1432-1351
DOI:10.1007/s00359-022-01590-x