Brain metabolic and ionic responses to systemic hypoxia in the newborn dog in vivo.

Newborns are less sensitive than adults to hypoxic/ischemic injury. However, research into the mechanism of the newborn's relative resistance to reduced brain oxygen levels is relatively scarce, and the time-scale for the disappearance of resistance is not known. The multiprobe assembly (MPA) has enabled us to examine the resistance of puppies at various ages to hypoxia via continuous, simultaneous, on-line measurement of various ionic, metabolic and electrical parameters from the cerebral cortex. The parameters measured included electrocorticogram (ECoG), direct current (DC) steady state potential, extracellular potassium (Ke+) and calcium ion concentrations and intra-mitochondrial Nicotine amide adenine dinucleotide NADH redox levels. These parameters were measured under various degrees of hypoxia (fraction of inspiration oxygen was between 0-10%) in 6-h-old to 24-week-old puppies (n = 44). Sensitivity to hypoxia increased with age, being expressed in the leakage of potassium ions out of the cells (0.3 +/- 0.07 mM in the younger puppies and 3.0 +/- 1.3 mM in the older puppies) following an increase in intra-mitochondrial NADH redox levels. Potassium ion (Ke+) leakage was apparently due to depleted energy stores resulting from an impairment in the balance between oxygen supply and demand. Although the overall effect was similar, the kinetics of these changes were much faster in the older puppies. The time to initial increase of extracellular K+ was 2.5 +/- 0.1 min in the younger puppies and 0.9 +/- 0.1 min in the older puppies. The time to maximum increase of NADH was 3.2 +/- 0.2 min in the younger puppies and 1.4 +/- 0.1 min in the older puppies. Our results indicate that the older puppies utilize the existing oxygen faster than the younger puppies. It is concluded that the increased resistance of newborn puppies to hypoxia is due to intrinsic properties of the brain itself, like the ability of the membrane to maintain ionic homeostasis.

Thiopental induced cerebral protection during ischemia in gerbils.

Temporary interruption or reduction of cerebral blood flow during cerebrovascular surgery may rapidly result in ischemia or cerebral infarction. Thiopental has been shown to have cerebroprotective effects. However, the cerebroprotective dose of thiopental causes burst suppression of the EEG, thus this parameter cannot be used continuously for the detection of metabolic changes in the brain during thiopental anaesthesia. This study was performed in order to examine whether the multiparametric assembly (MPA), which measures energy metabolism CBF and mitochondrial (NADH) as well as extracellular ion concentrations (K+), can shed light on the mechanism of the cerebroprotective effects of thiopental. The MPA was placed on the brain of Mongolian gerbils and burst suppression of the ECoG was induced by thiopental. Cerebral ischemia was induced by occlusion of carotid arteries after burst suppression. Burst suppression of the ECoG was accompanied by a significant decrease in cerebral blood flow. In animals that received thiopental prior to ischemia, NADH increased to a lesser degree and extracellular potassium ion concentration increased to a lesser degree than in the control animals, indicating that thiopental affords protection of the brain under ischemic conditions due to improved energy metabolism. This study also demonstrates that the MPA can monitor changes occurring in the cerebral cortex even after the ECoG can no longer be used. Those findings have a significant value in the development of a new clinical monitoring device.

Responses of rat brain to induced spreading depression following exposure to carbon monoxide.

Until recently carbon monoxide (CO) was known only for its noxious effects. Exposure to CO results in an autoregulatory increase in cerebral blood flow (CBF). Little information is available on brain energy metabolism under low CO concentrations and on the effect of CO on the stimulated brain. In this study cortical spreading depression (SD) was induced in order to cause transient brain depolarization and increased energy demand. The multisite assembly (MSA), which contains four bundles of optical fibers for monitoring the intramitochondrial NADH redox state and tissue reflectance as well as four DC electrodes enabling measurement from four consecutive points on the cerebral cortex, was used to measure energy metabolism and the propagation of SD waves during exposure to CO. CBF in the contralateral hemisphere was measured using the laser Doppler technique. Three experimental groups of animals were examined: SD was induced during exposure to 1000 ppm CO, immediately after exposure to CO and 90 min after cessation of exposure to CO. Three control groups were also examined, in which the animals underwent the same procedures but were not exposed to CO. In all animals exposure to CO was followed by a significant increase in CBF. The greatest effect was found when SD was induced immediately after cessation of exposure to CO. SD wave frequency decreased when induced immediately after exposure to CO, whereas it increased when SD was induced 90 min after exposure. The amplitude of the NADH oxidation waves and their integral were smaller during SD induced immediately after exposure to CO. The DC potential did not change, suggesting that CO did not affect the SD initiation mechanism but rather resulted in energy depletion during recovery from SD. This study demonstrates that even at a concentration of 1000 ppm CO interferes with the metabolic activity of the brain during repolarization of the SD-induced negativity.

Effects of carbon monoxide on the brain may be mediated by nitric oxide.

Carbon monoxide (CO) is known to be a toxic molecule due to the high affinity of hemoglobin for it. However, it has recently been shown that low doses of CO may play a physiological role. The aim of the present study was to examine processes occurring in the brain during exposure to 1,000 parts per million CO that result in an increase in cerebral blood flow (CBF) but are not accompanied by changes in oxidation metabolism. This study was carried out in awake rats with the multiprobe assembly developed in this laboratory for the simultaneous continuous measurement of CBF, intramitochondrial NADH redox levels, direct current potential, and extracellular concentrations of K+, Ca2+, and H+ as well as the electrocorticogram. Exposure to 1,000 parts per million CO in air resulted in an increased CBF without any concomitant changes in any of the other metabolic or ionic parameters measured. This indicates that tissue hypoxia was not the trigger for this vasodilation. Injection of N omega-nitro-L-arginine (L-NNA), a nitric oxide synthase inhibitor, before exposure to CO effectively blocked the increase in CBF that was observed when the animal was exposed to CO without prior injection of L-NNA. Furthermore, electrocorticographic depression was observed after the combined treatment of L-NNA and CO. In conclusion, exposure to relatively low doses of CO apparently does not have a deleterious effect on oxidative metabolism because the increase in CBF after this exposure is sufficient to prevent changes in oxidative metabolism, as indicated by the fact that NADH levels remained constant. This protective autoregulatory effect may be mediated by nitric oxide.