Abstract
Mormryid electric fish (Gnathonemus petersii) respond to novel stimuli with an increase in the rate of the electric organ discharge (EOD). These novelty responses were used to measure the fish's ability to detect small changes in the amplitude and latency of an electrosensory stimulus. Responses were evoked in curarized fish in which the EOD was blocked but in which the EOD motor command continued to be emitted. An artificial EOD was provided to the fish at latencies of 2.4 to 14.4 ms following the EOD motor command.
Novelty responses were evoked in response to transient changes in artificial EOD amplitude as small as 1% of baseline amplitude, and in latency as small as 0.1 ms. Changes in latency were effective only at baseline delays of less than 12.4 ms.
The sensitivity to small changes in latency supports the hypothesis that latency is used as a code for stimulus intensity in the active electrolocation system of mormyrid fish. The results also indicate that a corollary discharge signal associated with the EOD motor command is used to measure latency.
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Abbreviations
- EOD :
-
electric organ discharge
- ELL :
-
electrosensory lateral line lobe
- epsp :
-
excitatory post synaptic potential
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Hall, C., Bell, C. & Zelick, R. Behavioral evidence of a latency code for stimulus intensity in mormyrid electric fish. J Comp Physiol A 177, 29–39 (1995). https://doi.org/10.1007/BF00243396
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DOI: https://doi.org/10.1007/BF00243396