Fast sensory–motor reactions in echolocating bats to sudden changes during the final buzz and prey intercept

Echolocation is an active sense enabling bats and toothed whales to orient in darkness through echo returns from their ultrasonic signals. Immediately before prey capture, both bats and whales emit a buzz with such high emission rates (≥180 Hz) and overall duration so short that its functional signi...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences
Main Authors: Geberl, Conny, Brinkløv, Signe, Wiegrebe, Lutz, Surlykke, Annemarie
Format: Article in Journal/Newspaper
Language:English
Published: 2015
Subjects:
Bat
Buzz
Decision
Echolocation
Sensory motor
Decision Making
Chiroptera/physiology
Predatory Behavior/physiology
Vocalization
Animal
Acoustics
Flight
Feedback
Physiological
Animals
Video Recording
Animal Communication
toothed whales
Online Access:https://portal.findresearcher.sdu.dk/da/publications/c73e28a1-2ef0-42e9-b321-3a76565e8d9b
https://doi.org/10.1073/pnas.1424457112
https://findresearcher.sdu.dk/ws/files/129871255/Fast_sensory_motor_reactions_in_echolocating_bats_to_sudden_changes_during_the_final_buzz_and_prey_intercept.pdf
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Summary:Echolocation is an active sense enabling bats and toothed whales to orient in darkness through echo returns from their ultrasonic signals. Immediately before prey capture, both bats and whales emit a buzz with such high emission rates (≥180 Hz) and overall duration so short that its functional significance remains an enigma. To investigate sensory-motor control during the buzz of the insectivorous bat Myotis daubentonii, we removed prey, suspended in air or on water, before expected capture. The bats responded by shortening their echolocation buzz gradually; the earlier prey was removed down to approximately 100 ms (30 cm) before expected capture, after which the full buzz sequence was emitted both in air and over water. Bats trawling over water also performed the full capture behavior, but in-air capture motions were aborted, even at very late prey removals (<20 ms = 6 cm before expected contact). Thus, neither the buzz nor capture movements are stereotypical, but dynamically adapted based on sensory feedback. The results indicate that echolocation is controlled mainly by acoustic feedback, whereas capture movements are adjusted according to both acoustic and somatosensory feedback, suggesting separate (but coordinated) central motor control of the two behaviors based on multimodal input. Bat echolocation, especially the terminal buzz, provides a unique window to extremely fast decision processes in response to sensory feedback and modulation through attention in a naturally behaving animal.

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