[Potentiometric monitoring of the redox state of brain structures of freely-moving rats in sleep-wake cycles]. / Monitoring okislitel'no-vosstanovitel'nogo sostoianiia struktur golovnogo mozga svobodno-podvizhnoi krysy v tsiklakh bodrstvovanie-son putem potentsiometricheskoi registratsii.

Variations of brain tissue redox state potential (E) of freely-moving white rats (300-350 g) in cycles of wakefulness (W), slow-wave sleep (SWS), and paradoxical sleep (PS) were measured by platinum electrodes symmetrically implanted into the frontal and occipital cortices and hippocampus. In addition, EMG of neck muscles and general motor activity of animals were recorded. The common reference electrode was implanted in the nasal bone. It was shown that in some brain sites (called active), episodes of W and PS were accompanied by a rise of E, and during transitions from W and PS to SWS, E dropped. The value of E varied in the range of 100 mV. It is suggested that transitions from W and PS to SWS are accompanied by shifts in the balance between the main energy sources. Oxidative phosphorylation prevails in W and PS, whereas aerobic glycolysis is the main source of energy during SWS. We think that this suggestion is supported both by a decrease in E in SWS and its oscillations typical of glucolytic processes [Aon et al., 1992]. Recent literature data [Bitter et al., 1996] suggest that astroglia is the main compartment for aerobic glycolysis.

[Dynamics of local shifts in oscillations and energy metabolism of the rabbit cerebral cortex during formation of a conditioned defensive reflex]. / Dinamika lokal'nykh sdvigov i ostsilliatsii v énergeticheskom metabolizme kory golovnogo mozga krolika v protsesse formirovaniia uslovnogo oboronitel'nogo refleksa.

Brain energy metabolism in different functional states or activities of humans and animals is characterized by dynamic changes in the degree of coupling between glycolysis and tissue respiration in different cell compartments (Fox et al., 1988; Fox, 1989; Pellerin et Magistretti, 1994; Prichard et al., 1991; Schur et al., 1999). These processes determine variations in the brain redox state (Siesjo, 1978) that can be potentiometrically recorded with implanted platinum electrodes as the brain tissue redox state potential E (Puppi et Fely, 1983). This potential was recorded in rat brain cortex with four pairs of platinum electrodes implanted into different symmetrical cortical region (one electrode of a pair being located in the cortical layers, another being located epidurally). In the course of defensive conditioning (after 5-15 combination of a bulb light and a weak electrodermal stimulation of a ear), E oscillations (6-10 per minute) appeared. In this period, stimuli combinations produced the generalized E shifts. Later on (with accumulation of stimuli combinations), the episodes of E increase were replaced by the episodes of E decrease. To the 200-400th combinations, E oscillations disappeared, and E shifts became local and stable. The findings suggest that conditioning shifts the balance between the main energy-producing systems in the brain tissue: at the initial stages of conditioning brain functions are predominantly supported by the energy obtained from tissue respiration, while during the realization of defensive conditioning glycolysis is the main source of energy.