Summary
Up to five microelectrodes inserted through short hypodermic needles in the cranial cartilage of Sepia officinalis recorded potentials while the cuttlefish moved freely in a small enclosure. Compound field potentials and unit spikes were seen during ongoing, spontaneous activity and after sensory stimulation.
Ongoing activity resembles that reported for octopus, with maximum power usually below 20 Hz. Amplitude varies greatly but has not been seen to shut off or turn on abruptly and globally as in octopus.
Evoked potentials, focally large after flashes of light consist of several waves; the first is largest, positive and peaks at ca. 35 ms (called P35), followed by ca. P75, P95, N110 and smaller waves or oscillations lasting more than 0.5 s. The Upper Following Frequency (highest flashing rate the potentials can follow 1:1), without averaging, is >15 flashes/s (20–22 °C); at 20/s the 1∶1 following lasts for 1 or 2 s. The Lower Fusion Frequency of averaged responses is < 30/s. Gentle tapping of the tank wall evokes local, brief, fast potentials. No responses have been found to loud air-borne clicks and tone bursts with principal energy at 300 Hz or to electric fields in the bath at 50–100 μV/cm.
In a few loci relatively large slow Omitted Stimulus Potentials have been seen following the end of a train of flashes at more than 5/s; these are by definition event related potentials and a special, central form of OFF response.
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Abbreviations
- EP :
-
evoked potential
- ISI :
-
interstimulus interval
- OSP :
-
omitted stimulus potential
- VEP :
-
visual evoked potential
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Bullock, T.H., Budelmann, B.U. Sensory evoked potentials in unanesthetized unrestrained cuttlefish: a new preparation for brain physiology in cephalopods. J Comp Physiol A 168, 141–150 (1991). https://doi.org/10.1007/BF00217112
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DOI: https://doi.org/10.1007/BF00217112