Two components of the antidromic IPSPs in the pyramidal tract cells

Characteristics and origin of frontal paroxysmal responses induced by light stimulation in the Papio papio under allylglycine

In the Papio papio, curarized and rendered photosensitive by injection of a subconvulsant dose of DL-allylglycine, single flashes induce frontal paroxysmal evoked responses on condition that they be preceded by trains of intermittent light stimulation (ILS). The characteristics of these responses have been compared to those of non-paroxysmal responses induced in the same cortical area by isolated flashes (not preceded by trains of ILS). The paroxysmal responses resemble spikes and waves and consist of one or two positive spikes followed by a slow negative wave. The intracortical distribution of these responses has been studied in the motor cortex. The non-paroxysmal responses are probably not generated at this level. On the other hand, observations made during paroxysmal responses show the existence of two cortical responses; this demonstration follows from the existence of an inversion in some response components, linked to a negativity and a local cellular activation. A generator, situated in the pyramidal cell layer, is active during the positive surface spikes; the other generator, situated in the more superficial cortical layers, is active at the beginning of the slow negative surface wave. The cortical and subcortical afferents likely to bring these generators into play are discussed.

Spike-wave rhythms in cat cortex induced by parenteral penicillin. II. Cellular features

Epileptiform potentials, consisting of spontaneous, generalized bursts frequently assuming a 3/sec spike-wave form and tonic clonic electrographic seizures were produced in 32 lightly anesthetized cats by parenteral injections of penicillin. The activity of 83 identified pyramidal tract cells and 207 cortical non-pyramidal tract cells was correlated with the surface EEG. The majority of both cell types generated depolarizations and action potentials with the EEG spike. Hyperpolarizations, during which cells were inhibited, followed the depolarizations. The depolarizations responded to injected current as if they were generated by excitatory synapses; and hyperpolarizations to injected current and chloride ions as if generated by proximal inhibitory synapses. Attempts to identify a class of neurons firing during the surface-negative wave (presumed inhibitory interneurons) were unsuccessful. Forty-two units were recorded during tonic-clonic seizures. Intracellular records disclosed tonic oscillations of membrane potential, phased bursting with "depolarization shifts", abortive action potentials and post-ictal hyperpolarizations. Cell somata often depolarized to the point of inactivation, but axons continued to fire at high rates. These results emphasize the role of EPSP-IPSP sequences in the generation of spike-wave rhythms.

Synaptic processes in pericruciate cortical neurons evoked by pyramidal tract stimulation in cats

In cats anesthetized with chloralose and pentobarbital and immobilized with D-tubocurarine activity of 423 pericruciate cortical neurons was recorded (342 extra- and 81 intracellularly); 78 neurons had spontaneous activity. Stimulation of the pyramidal tract evoked antidromic action potentials in the pyramidal neurons with a latent period of 0.5-16.0 msec. Recurrent and lateral PSPs also developed both in pyramidal and in unidentified neurons in all layers of the cortex; IPSPs were recorded in 46.7% of neurons, EPSPs in 21.0%, mixed responses in 26.0%, and no visible changes were found in 6.3%. The latent period of the IPSPs was 1.5-14.0 msec, ther amplitude 1.3-17.0 mV, their rise time from 4 to 18 msec, and their duration 18-120 msec (sometimes up to 250-500 msec). In 30% of cases in which IPSPs appeared, their course was divided into two phases: fast (duration 10-20 msec) and slow. EPSPs developed after a latent period of 2.6-29.0 msec; their amplitude was 1.0-7.8 mV and their duration from 10.0 to 50.0 msec. In 51.2% of spontaneously active neurons the antidromic volley inhibited their activity in the course of 200-400 msec, in 19.5% it stimulated their activity, in 7.4% it had a mixed effect, and in 21.9% no visible change took place in their activity. The role and participation of axon collaterals of pyramidal neurons and of the interneuronal system in the formation of these processes are discussed.