Na-G-penicillin penetration into rat cerebral cortex and formation of an epileptic focus.

Fluorescein isothiocyanate-labelled Na-G-penicillin was applied to the intact dura of 11 rats and the cortical layers were determined to which this epileptogenic substance must penetrate for electrophysiologically demonstrable focal activity to be induced. In 10 animals labelled penicillin was demonstrated in cortical layers I--III and in one animal in layers I and II. This concurs with the results obtained in 12 other animals in which activity was recorded from three depths of the cerebral cortex with semimicroelectrodes.     

Ionic changes induced by excitatory amino acids in the rat cerebral cortex

The ionic mechanisms underlying the action of excitatory amino acids were investigated in the rat motor cortex. Ion-selective microelectrodes were attached to micropipettes such that their tips were very close and local changes in extracellular concentration of sodium, calcium, and potassium ions elicited through ionophoretic applications of glutamate (Glu) and of its agonists N-methyl-D-aspartate (NMDA), quisqualate (Quis), and kainate (Ka) were measured. These agents produced moderate increases in [K+]o (up to 13 mM) but, in contrast, substantial tetrodotoxin-insensitive decreases in [Na+]o (maximally of 60 mM). NMDA-induced sodium responses could be blocked by manganese, while the Quis- and Ka-induced responses were not. Quis and Ka produced increases in [Ca2+]o or biphasic responses while NMDA, even with small doses, induced each time drastic decreases in [Ca2+]o (maximally of 1.15 mM), which could be attenuated or blocked by manganese but not by organic calcium channel blockers. NMDA responses could be abolished by reduced doses of 2-amino-phosphonovalerate. The largest Glu- and NMDA-induced calcium responses were observed in the superficial cortical layers, but such maxima disappeared after selective degeneration of pyramidal tract neurons. All amino acids produced sizeable reductions in the extracellular space volume. The following can be concluded. (i) All the excitatory amino acids tested induce an increased permeability to sodium and potassium ions. (ii) In addition, the NMDA-operated channels have specifically a large permeability for calcium, although calcium ions contribute only by less than 10% to the NMDA-induced inward currents.(ABSTRACT TRUNCATED AT 250 WORDS)     

Temperature effect on subclasses of muscarinic receptors in rat colon, heart and cerebral cortex

The high-affinity muscarinic antagonist /3H/-Quinuclidinyl benzilate (/3H/-QNB) has been used to label muscarinic receptors in a crude membrane fraction of rat cerebral cortex, colon and heart. The inhibition of /3H/-QNB binding by Atropine, Oxotremorine and Pirenzepine was investigated at three temperatures: 37 degrees C, 22 degrees C and 10 degrees C. The IC50 values and the proportion of high (Rt1) and low (Rt2) affinity binding sites were determined for the three compounds. When the temperature were lowered from 37 degrees C to 10 degrees C, in the agonist and antagonist dissociation constants decreased in all tissues. Changes in temperature did not modify Rt1 or Rt2 values for Oxotremorine and Pirenzepine. The results show marked temperature-dependent modifications of IC50 values for muscarinic receptors of high- and low-affinity sites in rat cerebral cortex, colon or heart.     

Spread of directly evoked responses in the cat''s cerebral cortex

A study has been made of the electrical responses to direct stimulation of the exposed cerebral cortex of cats that had been immobilized with neuromuscular blocking drugs, and whose muscle and skin wounds had been locally anesthetized. The characteristics and spread of the first and second surface-negative responses are described. It was found that the first surface-negative response to weak stimuli decays linearly to zero at 3 to 6 mm. from the point of stimulation. Intermediate stimuli cause farther and non-linear spread: responses are re-initiated, or reinforced, at 6 to 10 mm.; and supramaximal stimulation produces reinforcement both at 5 and at 10 mm. The conduction velocity of these responses is uniform for linear spread (0.7 to 2.0 m./sec.), but reinforced responses occur 1 to 3 msec. earlier than would be expected for simple conduction. The phenomenon of re-initiation, or reinforcement, depends upon the excitatory state of the brain; circulation and previous stimulation are important factors. Connections outside the gyrus matter only in so far as they provide other sources of general excitation. It is concluded that two types of transmission: slow and fast, can lead to generation of similar surface-negative responses. The suggestion is made that the slowly conducted surface-negative potentials are due to direct or to synaptic excitation of pyramidal cells; while the responses with shortened latency are initiated synaptically on other pyramidal cells after fast conduction at about 10 m./sec. in tangential fibres.     

Anticonvulsants and trifluoperazine inhibit the evoked release of GABA from cerebral cortex of rat at different sites

The action of anticonvulsant drugs, phenytoin, diazepam, clonazepam and phenobarbitone, was tested on the release of [¹⁴C]-GABA from tissue slices of rat cerebral cortex. All drugs caused a significant dose-dependent depression of the 33mM-K⁺-evoked release of [¹⁴C]-GABA but had little effect on the resting release of [¹⁴C]-GABA, except at high concentrations. The IC₅₀ values for inhibition of K⁺-evoked release of [¹⁴C]-GABA were 4.7 × 10^?5, 7 × 10^?5, 28 × 10^?5 and 7.9 × 10^?4M for diazepam, clonazepam, phenytoin and phenobarbitone respectively. Trifluoperazine also caused a similar and complete inhibition of [¹⁴C]-GABA release with an IC₅₀ of 1 × 10^?5M. The effect of diazepam and trifluoperazine were additive. The inhibition by trifluoperazine could be overcome by addition of exogenous calmodulin, whereas that of diazepam, phenytoin or phenobarbitone was not overcome. It is proposed that the anticonvulsants tested inhibit calcium-dependent transmitter release at a site distal to the formation of a calcium-calmodulin complex, which is presumably activated by this complex. Trifluoperazine, on the other hand, acts by reducing the availability of calmodulin.     

Ultrastructure of the cerebral cortex in the rat after the effect of electromagnetic impulse

In mature rats an area on the head has been subjected to a single radiation for 1.5 sec with microwaves in the continuous regimen of generation, frequency 2.4 GHz level of the specific absorbed power 5 W/g, that is accompanied with appearance of convulsions. Under anesthesia specimens of the superficial layer of the cerebral superlateral part are taken and subjected to electron microscopical investigation. Immediately after radiation and in 2 h certain disorders in microcirculation and reactive changes of mitochondria in perikaryons, axons, dendrites, synapses of the neurons and in gliocytes are revealed. The mitochondrial changes are designated as "edematous". In 2 and 6 h in karyoplasm of some neurons membranous structures appear; they are interpreted as a result of heat denaturation of the nuclear proteins. In synapses, together with lesions of mitochondria, synaptic complexes undergo destruction and osmiophilic substance is accumulated in the subsynaptic zone along the whole length of the contact. In one day, essential destructive changes are revealed as severe lesions of some neurons, vacuolization and destruction of mitochondria, localized in all the structures. Pathogenesis of the neurological disturbances is based on disturbances of interneuronal interactions, connected with an immediate heat effect of the electromagnetic radiation on the structures responsible for the synaptic transmission and with a rapidly developing tissue hypoxia as a consequence of microcirculatory disturbance and a sharp inhibition of energetic metabolism.     

Aging and benzodiazepine binding in the rat cerebral cortex

The specific binding of ³H-diazepam in the cerebral cortex was investigated in membrane preparations from 6 and 30 month old Fischer-344 rats. No age-related differences in the association, equilibrium, or dissociation binding characteristics were observed. The increased sensitivity of the elderly to the central sedative effects of the benzodiazepines does not, therefore, appear to involve changes in binding to the receptor site located in the cortex.     

Effect of diazepam on electrical activity and Na,K-ATP-ase level in a penicillin-induced epileptic focus in the rat cerebral cortex

Application of penicillin solution to the motor cortex in rats evoked the appearance of interictal discharges and epileptic seizures. After administration of diazepam in a dose of 2 mg/kg, Na,K-ATPase activity in the unpurified synaptosomes fraction of the cortex in the zone of the focus was increased by practically 100% compared with the level of activity of the enzyme in the focus without diazepam. Interictal discharges and epileptic seizures underwent different changes following intramuscular injection of diazepam. The frequency and variability of amplitude of the interictal discharges increased after administration of diazepam, whereas epileptic seizures were depressed. This effect was potentiated with an increase in the dose of diazepam. It is suggested that the opposite action of diazepam on epileptic seizures and interictal discharges may be evidence that the mechanisms lying at the basis of the development of these phenomena are different.Institute of General Pathology and Pathological Physiology, Academy of Medical Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 12, No. 4, pp. 349–357, July–August, 1980.     

Electron microscopic evidence for the existence of an intercellular substance in rat cerebral cortex

Summary The intercellular spaces of rat cerebral cortex are filled with a dense material, demonstrable by electron microscopy. This intercellular substance is in part preserved by chemical fixation with formaldehyde and osmium tetroxide but is solubilized and largely lost during subsequent dehydration with ethyl alcohol. Dehydration with acetone or Durcupan favors the preservation of the intercellular substance, which is preserved also by freezing and drying. Whether the intercellular substance demonstrated here is part of the outer leaflets of apposing plasma membranes (glycocalyx) or truly an intercellular substance similar to connective tissue ground substance is not known. The probability of the latter is discussed with regard to proposed physiological mechanisms.This work was supported by USPHS Research Grants NB 05175 and AM 06998.     

Acetylcholinesterase in neurons of the rat cerebral cortex.

AChE-containing neurons have been demonstrated by electron-microscopical histochemistry in the neocortex of the rat. These cells are mainly located in layer VI. AChE activity is seen in the cisternae of the RER, in subsurface cisternae and in the dendritic membranes.     

The effect of omega-3 fatty acids on Ca-ATPase in rat cerebral cortex

Neuronal Ca-ATPase has the essential function of keeping intracellular Ca levels in the micromolar range. This is a prerequisite for normal neurotransmission. This study was designed to determine whether Ca-ATPase is a target for docosahexaenoic acid (DHA) and eicosapentaenoic acid (EPA) action: results show that both these fatty acids are inhibitors of Ca-ATPase activity in synaptosomal membranes isolated from rat cerebral cortex (-65+/-5% at [DHA]=20 microg/ml, -59+/-7% at [EPA]=20 microg/ml). The inhibition caused by EPA, but not that of DHA, could be reversed completely by the addition of calphostin, a protein kinase C blocker. In contrast, DHA could stimulate Ca-ATPase activity (+132+/-5% at [DHA]=30 microg/ml) only in calmodulin-depleted membranes. In addition, Na,K-ATPase (which drives the Na-Ca exchanger) was inhibited by both DHA and EPA, both at 30 microg/ml (-15+/-0.7% and -42+/-1%, respectively). These results suggest a mechanism that explains the dampening effect of omega-3 fatty acids on neuronal activity.