Ongoing compound field potentials from octopus brain are labile and vertebrate-like

Abstract

Ongoing electrical activity was recorded from the brain of the virtually intact, semirestrained, unanesthetized octopus by semimicroelectrodes thrust through the cartilage into the optic, vertical or basal lobe. With flexible lead-in wires such electrodes were carried by and moved with the head without causing movement artifacts. Controls suggest that the activity reported comes from the brain; it is reversibly flattened by doses of urethane that do not embarrass respiration. Muscle potentials are only troublesome on occasion. Seen through a wideband filter, neuronal spikes are usually small or below noise level under these conditions; slow waves (1–70 Hz) dominate, with a maximum < 25 Hz, usually < 10 Hz and no consistent sharp peaks. The fall in power above ca. 25 Hz is usually slower than in the typical vertebrate EEG but the average power spectrum is much more like those of vertebrate brains than of cerebral ganglia of other invertebrates (insect, crustacean, gastropod). Variance among sample epochs is large, e.g. short spells may have relatively much more low frequency (< 25 Hz) or more ‘hashy’ high frequency (> 50 Hz) energy; there may be runs of spikes. Fluctuation in the composition of ongoing activity is graphically shown by writing out in parallel the outputs of several narrow band (one octave) filters; this shows irregular low frequency waxing and waning of the amplitude in each band. The envelopes were computed and their peak power is around 1 Hz or lower; the waxing and waning in the several bands is sometimes strongly correlated, especially when the envelope amplitude is large and slow. Optic lobe activity tends usually to be faster, with more small spikey hash than in the vertical lobe. The described electrical activity of the brain is strikingly episodic; it is recorded during seconds or minutes separated by long intervals of nearly electrical silence (10–40 dB lower power; the difference larger at frequencies > 20 Hz). Active and quite periods are usually not correlated with differences in visible behavior. Under my conditions the animal is usually not moving except for quiet ventilation and occasional local writhing of an arm. Potentials evoked by single flashes of light (0.2–1/sec) are conspicuous in the optic but not in the vertical lobe. They form a sequence of large, slow waves; the first peak may be at about 40 msec, others up to at least 400 msec. In a few attempts no evoked potentials were found for weak electric fields (100 μV/cm; 100 msec) such as electroreceptive fish respond to strongly. It is concluded that the compound field potential of the brain is not primarily the sum of spikes but of synaptic and other forms of graded potentials — as in vertebrate higher centers more than invertebrates.