OPTIMAL FREEZING CONDITIONS FOR CEREBRAL METABOLITES IN RATS

Abstract— Optimal freezing conditions for metabolites were evaluated in 250-450 g rats. As a standard procedure, the brains were frozen in such a way that the blood pressure and arterial oxygenation were upheld during the freezing. The progression of the freezing front was determined by means of implanted thermocouples, and the interruption of the circulation by means of injections of carbon particles into the blood stream. The freezing gave rise to a rapid interruption of the circulation in the superficial cortical layer first reached by the freezing front well before the temperature reached 0°C. In deeper regions the progression of the freezing front was slower and interruption of the circulation occurred simultaneously with the freezing of the tissue. Measurements of labile cerebral metabolites, including phosphocreatine, ATP, ADP, AMP and lactate, failed to show signs of autolysis in the part of cortex which became unperfused at temperatures above zero. Since the energy state was identical in superficial cortical areas and in areas that did not freeze until after 40–90 s, it is concluded that the freezing technique gives optimal conditions for metabolites also in deep cerebral structures. Decapitation of unanaesthetized animals gave rise to large autolytic changes in the cerebral cortex. In unanaesthetized animals that were immersed in liquid nitrogen the changes were less marked and mainly affected the concentrations of phosphocreatine, ADP and lactate. When paralysed animals that were anaesthetized with N₂O were immersed in liquid nitrogen the only significant change from the control was a decrease in phosphocreatine content. The virtual absence of autolytic changes in this group of animals was not related to the anaesthesia since more pronounced changes were observed in phenobarbitone-anaesthetized rats immersed in the coolant. These differences could be explained by the fact that spontaneously breathing animals immersed in liquid nitrogen developed arterial hypoxia much faster than paralysed animals. It is concluded that an optimal metabolite pattern can only be obtained in anaesthetized animals, frozen with a method that was described by Kerr almost 40 years ago (Kerr , 1935). If unanaesthetized animals must be used, greater attention should be paid to the oxygenation of the blood during the freezing than to such factors as speed of freezing or depth of anaesthesia.     

CEREBRAL ENERGY STATE IN INSULIN-INDUCED HYPOGLYCEMIA, RELATED TO BLOOD GLUCOSE AND TO EEG

—Concentrations of phosphocreatine, creatine, ATP, ADP and AMP were measured in the cerebral cortex of rats during insulin-induced hypoglycemia. Blood glucose concentrations were related to clinical symptoms in unanaesthetized animals and to the EEG pattern in paralysed and lightly anaesthetized animals. There was an excellent correlation between blood glucose concentration and EEG pattern. In animals showing a pronounced slowing of the EEG or convulsive polyspike activity for up to 20 min, there were no changes in any of the phosphates. However, after prolonged convulsive activity some animals showed clear signs of energy failure, and in all animals with an isoelectric EEG there was a major derangement of the energy state. Since the majority of those animals did not show signs of cerebral hypoxia or ischemia it is concluded that hypoglycemic coma is accompanied by substrate deficiency of a degree sufficient to induce energy depletion of brain tissue.     

Cerebral Metabolic State During the Ethanol Withdrawal Reaction in the Rat

Abstract: A severe ethanol withdrawal reaction was induced in rats by means of repeated intragastric intubation during a 4-day period. At the peak of the withdrawal reaction cerebral cortical tissue was frozen in situ for analysis of glycogen, glucose, phosphocreatine, creatine, ATP, ADP, AMP, lactate, pyruvate, GAB A, β-hydroxybutyrate, acetoacetate, cAMP and cGMP. Blood glucose concentration was also measured. The level of brain glycogen was decreased during ethanol withdrawal. Brain glucose concentration was increased, probably secondary to the increase in blood glucose concentration. The calculated NADH/NAD⁺ ratio was slightly increased during the withdrawal and brain ATP concentration and adenine nucleotide pool size were decreased. The adenylate energy charge remained unchanged. The overall changes in the metabolites were in agreement with the previously shown metabolic activation during ethanol withdrawal. The brain concentrations of ketone bodies (β-hydroxybutyrate and acetoacetate) during withdrawal did not deviate from controls, indicating that no abnormal ketone metabolism had developed as a consequence of the long-lasting ethanol intoxication. No changes were observed in the concentrations of GABA, cAMP, or cGMP in the rat cerebral cortex during ethanol withdrawal.     

Cerebral carbohydrate metabolism during acute hypoxia and recovery

Abstract— The levels of ATP, ADP, AMP and phosphocreatine, of four amino acids, and of 11 intermediates of carbohydrate metabolism in mouse brain were determined after: (1) various degrees of hypoxia; (2) hypoxia combined with anaesthesia; and (3) recovery from severe hypoxia. Glycogen decreased and lactate rose markedly in hypoxia, but levels of ATP and phosphocreatine were normal or near normal even when convulsions and respiratory collapse appeared imminent. During 30 s of complete ischaemia (decapitation) the decline in cerebral ATP and phosphocreatine and the increase in AMP was less in mice previously rendered hypoxic than in control mice. From the changes we calculated that the metabolic rate had decreased by 15 per cent or more during 30 min of hypoxia. Hypoxia was also associated with decreases of cerebral 6-phosphogluconate and aspartate, and increases in alanine, γ-aminobutyrate, α-ketoglutarate, malate, pyruvate, and the lactate :pyruvate ratio. Following recovery in air (10 min), increases were observed in glucose (200 per cent), glucose-6-phosphate, phosphocreatine and citrate, and there was a fall in fructose-1, 6-diphosphale. Similar measurements were made in samples from cerebral cortex, cerebellum, midbrain and medulla. Severe hypoxia produced significant increases in lactate and decreases in glycogen in all areas; γ-aminobutyrate levels increased in cerebral cortex and brain stem, but not in cerebellum. No significant changes occurred in ATP and only in cerebral cortex was there a significant fall in phosphocreatine. Phosphocreatine, ATP and glycogen were determined by quantitative histochemical methods in four areas of medulla oblongata, including the physiological respiratory centre of the ventromedial portion. After hypoxia, ATP was unchanged throughout and the changes (decreases) in phosphocreatine and glycogen were principally confined to dorsal medulla, notably the lateral zone. Thus there is no evidence that respiratory failure is caused by a ‘power’ failure in the respiratory centre. It is suggested that in extremis a protective mechanism may cause neurons to cease firing before high-energy phosphate stores have been exhausted.     

Cerebral energy metabolism during experimental status epilepticus.

—The concentration of ATP, ADP, AMP, phosphocreatine and of 5 intermediates of carbohydrate metabolism were determined in rodent brain after single and repeated seizures induced by either electroshock (ES), flurothyl or pentylenetetrazol (PTZ). In paralysed-ventilated rats, one ES produced a 4–5 fold increase in cortical glycolytic flux (estimated from changes in glucose and lactate), and associated increases in pyruvate and in the lactate/pyruvate ratio. Total high energy phosphates declined during the seizure; a decrease was also calculated in cortical tissue pH and in the cytoplasmic [NAD⁺]/[NADH] ratio. Similar changes in brain were observed in ventilated mice after ES, but in paralysed animals, no decrease in high energy phosphates occurred during the first seizure. More vigorous and prolonged chemically-induced seizures in both rats and mice elicited a decrease in the cerebral energy reserves with a rise in lactate and in the lactate/pyruvate ratio. At all times during the seizures the cerebral venous blood had a higher oxygen tension than that of control animals (rats) or was visibly reddened (mice), implying that oxygen availability to brain exceeded metabolic demands. It is proposed that the development of‘non-hypoxic’cerebral lactacidosis during seizures is part of the overall metabolic response of the brain to an abrupt increase in energy consumption. The response constitutes a homeostatic influence which promotes cerebral vasodilatation, thereby increasing blood flow and the delivery of substrates. With repeated seizures, delivered 2 min apart, glycogen declined progressively, but concentrations of the adenine nucleotides appeared to plateau, suggesting that a new energy balance had been established. However, after 20–25 seizures, the attacks became self-generating and there was a further reduction in the tissue high energy phosphate stores, a fall in brain glucose and in the brain/blood glucose ratio. It is concluded that the brain possesses a limited capacity to adjust its metabolism to meet the increased energy requirements of single or repeated seizures, but that this mechanism ultimately fails during status epilepticus unless the abnormal electrical discharges, themselves, are brought under control.     

CEREBRAL METABOLIC AND CIRCULATORY CHANGES INDUCED BY HYPOXIA IN STARVED RATS

In order to study cerebral metabolic and circulatory effects of hypoxia under conditions of restricted glucose supply, the arterial P_o2, was reduced to 25–30mm Hg in artificially ventilated and lightly anaesthetized rats that were starved for 24 or 48 h prior to experiments. Arterial glucose concentrations, that were initially around 6μmol g^-1, were significantly reduced after 15min of hypoxia, and decreased to 50^o of control after 30min. In animals studied after 30min of hypoxia (24 h of starvation), cerebral blood flow had increased 4-fold and there was a moderate (25%) rise in cerebral oxygen consumption. During the course of hypoxia, cerebral cortical concentrations of glucose fell to low values. In spite of this, concentrations of pyruvate and lactate rose with time, and the sum of citric acid cycle intermediates (citrate, α-ketoglutarate, fumarate. malate and oxaloacetate) increased. Changes in amino acids were dominated by a fall in aspartate and a rise in alanine concentration. There was a moderate reduction in phosphocreatine and a slight rise in ADP concentration, but concentrations at ATP and AMP were unchanged. The changes observed are similar to those previously obtained in fed animals. It is concluded that even if blood glucose concentrations fall to 3μmol g^-1, and cerebral energy flux is maintained, substrate supply is sufficient to cover the energy requirements of the tissue. Hypoxia was accompanied by increases in the lactate/pyruvate and β-hydroxybutyrate acetoacetate ratios of blood. In the tissue, NADH/NAD⁺ ratios derived from the lactate, malate and β-hydroxybutyrate dehydrogenase systems rose, while that derived from the glutamate dehydrogenase reaction fell. It is concluded that the latter system is not well suited for estimating mitochondrial redox changes in brain tissue.     

INFLUENCE OF ANAESTHETICS ON THE BALANCE BETWEEN PRODUCTION AND UTILIZATION OF ENERGY IN THE BRAIN

Abstract— The influence of general anaesthesia upon the metabolic state of the brain was evaluated from the tissue concentrations of ATP, ADP and AMP, and from the concentrations of glycolytic and citric acid cycle intermediates, in immobilized and artificially ventilated rats anaesthetized either with 70% N₂O, 1% halothane or 60 mg/kg of pentobarbitone. The results were compared to the results obtained on awake animals in fentanyl-analgesia. The adenylate energy charge was identical in all groups studied and there were no H⁺-independent changes in the phosphocreatine/creatine ratios. In pentobarbitone anaesthesia there was an accumulation of glucose 6-phosphate and a fall in fructose 1,6-diphosphate, indicating inhibition of phosphofructokinase. No significant changes in these metabolites were observed with halothane or nitrous oxide anaesthesia and the substrate patterns differed from that obtained with pentobarbitone.
The blood glucose concentrations were higher in the unanaesthetized, immobilized rats given fentanyl than in those anaesthetized. There was a direct relationship between the glucose concentrations in blood and in tissue. The glucose concentration ratios intracellular water to blood were higher in the anaesthetized than in the unanaesthetized animals, increasing with increasing depth of anaesthesia. The intracellular lactate concentrations were lowest in the groups given pentobarbitone and fentanyl citrate, and there was thus no direct relationship between lactate concentration and depth of anaesthesia.     

EVALUATION OF IN SITU FREEZING OF CAT BRAIN BY NADH FLUORESCENCE

Abstract— Cat brain was frozen in situ with liquid nitrogen. In order to locate areas with ischemic artifact, frozen brain slices were surveyed for regions of increased NADH fluorescence. In addition, levels of ATP, phosphocreatine, lactate, and NADH were determined in various brain regions. High levels of ATP and phosphocreatine, and low levels of lactate and NADH were present in all brain regions except the depths of some cortical sulci. These regions of ischemic change were easily detected by virtue of increased NADH fluorescence in frozen brain slices. Deep brain structures such as basal ganglia and hippocampus showed neither high tissue fluorescence nor ischemic changes of the metabolites measured. Therefore, in situ freezing of cat brain adequately preserves metabolite levels in most regions.     

FREEZE-BLOWING: A NEW TECHNIQUE FOR THE STUDY OF BRAIN IN VIVO

Abstract— A new apparatus is described which removes and freezes brains of conscious rats more rapidly than was heretofore possible. The apparatus consists of two probes which are driven simultaneously into the cranial vault of the rat immobilized in a specially constructed restraining cage. When in position, air under pressure enters through one probe and blows the supratentorial portion of the brain tissue (situated between the olfactory bulbs and the superior colliculi) out the other probe and into a thin chamber previously cooled in liquid N₂. This method stops brain tissue metabolism more rapidly than the previously-described methods of microwave irradiation, decapitation into liquid N₂, or whole-animal immersion into liquid N₂, as evidenced by the measurement of labile metabolites and redox states. Thus, samples of freeze-blown brain had higher levels of a-oxoglutarate, creatine phosphate, pyruvate, glucose and glucose-6-phosphate and lower levels of lactate, malate and AMP than brain tissue obtained by the other methods. The free cytoplasmic [NAD⁺]/[NADH₂], [NADP⁺]/[NADPH₂] and [ATP]/[ADP] [HPO₄^2-] ratios were higher in freeze-blown samples. These data indicate that more extensive anoxic metabolism occurred when methods other than freeze-blowing were used. We conclude that the levels of metabolites measured in brain obtained with the freeze-blowing technique more closely resemble those which occur in vivo.     

INFLUENCE OF HYPOXIA ON CEREBRAL ENERGY STATE IN RATS WITH PORTA-CAVAL ANASTOMOSIS

Abstract— In order to evaluate whether porta-caval anastomosis, and the accompanying hyperammonemia, affect the balance between production and utilization of ATP in the brain, organic phosphates and carbohydrate substrates were measured in control and shunted rats exposed to hypoxia (arterial P_o2 about 30 mm Hg). In the shunted animals the cortical ammonia content was about 2.5 times that measured in the controls, and there was a marked accumulation of glutamine. The intracellular lactate concentration was identical in the control and the shunted groups, and the pattern of change in carbohydrate substrates was similar. There were no significant differences in ATP, ADP or AMP between the groups but the shunted group showed a significantly lower phosphocreatine content. However, the fall in phosphocreatine in the shunted group could be related to a decrease in the sum of phosphocreatine and creatine. It is concluded that the shunting procedure does not disturb the balance between energy production and energy utilization in the brain.     

A COMPARISON OF METHODS FOR STOPPING INTERMEDIARY METABOLISM OF DEVELOPING RAT BRAIN1

Abstract— Freeze-blowing (Veech et al. 1973), focussed microwave irradiation (Stavinoha et al. 1973) and immersion in liquid nitrogen were compared as methods for stopping metabolism in order to assay in vivo levels of intermediary metabolites in developing rat brain. Freeze-blowing was superior at all ages (5. 10, 15 and 20 days post-natal). The differences between this method and immersion in liquid nitrogen were quite small in the youngest rats and increased with age. reflecting the increased time needed to freeze larger brains. Brains frozen by immersion in liquid nitrogen showed evidence of increased anaerobic metabolism, with increased fructose 1.6-diphosphate. dihydroxyacetone phosphate and lactate and decreased glucose 6-phosphate and creatine phosphate concentrations. When brain metabolism was stopped by microwave irradiation there were many differences from freeze-blown brain. Increases in fructose 1.6-diphosphate. dihydroxyacetone phosphate, ADP and AMP, and decreased in ATP and creatine phosphate were especially striking. The differences between microwave irradiation and freeze-blowing were not attributable simply to anoxia. Rather, the changes produced by this method seem to reflect the different thermal characteristics of the various enzymes which must be denatured to stop metabolism of the substrates measured. Unlike freezing in liquid nitrogen, the efficacy of microwave irradiation was not a simple function of head size, in that better results were achieved with 15- and 20-day-old than 5- or 10-day-old rats. Many glycolytic and Krebs cycle intermediates, as well as glutamate and aspartate, progressively increased over the course of development. The reasons for these increases are uncertain but are probably-related to the concomitant rises in rates of glycolysis and oxidative phosphorylation in brain.     

EFFECT OF HYPOTHERMIA UPON ORGANIC PHOSPHATES, GLYCOLYTIC METABOLITES, CITRIC ACID CYCLE INTERMEDIATES AND ASSOCIATED AMINO ACIDS IN RAT CEREBRAL CORTEX

—The influence of hypothermia upon the metabolism of the brain was studied by reducing body temperature in N₂O-anaesthetized rats to 32, 27 or 22°C, with subsequent measurements of organic phosphates, glycolytic metabolites, citric acid cycle intermediates and associated amino acids. Hypothermia was maintained for either 1 or 2 h and the effect of anaesthesia was evaluated by maintaining unanaesthetized animals at 22°C. Hypothermia had no influence on the cerebral cortical concentrations of ATP, ADP or AMP and there was only a small increase in phosphocreatine. Since the tissue concentrations of glucose and glycogen were reduced, it is concluded that the well known resistance of the hypothermie brain to ischaemia is unrelated to increased energy stores. Hypothermia was accompanied by decreases in the tissue concentrations of fructose-1,6-diphosphate, dihydroxyacetone phosphate, 3-phosphoglycerate, pyruvate, lactate, α-ketoglutarate, succinate and malate, but not of glucose-6-phosphate or citrate. These results indicate that metabolic flux is retarded mainly at the phosphofructokinase and isocitrate dehydrogenase steps. The largest relative reduction was seen in α-ketoglutarate, which was possibly secondary to accumulation of ammonia. There was no change in GABA, but a decrease in glutamate and increases in aspartate and alanine. These, changes are compatible with shifts in the aspartate and alanine aminotransferase reactions, possibly induced by the fall in α-ketoglutarate.     

THE EFFECT OF HYPERTHERMIA UPON OXYGEN CONSUMPTION AND UPON ORGANIC PHOSPHATES, GLYCOLYTIC METABOLITES, CITRIC ACID CYCLE INTERMEDIATES AND ASSOCIATED AMINO ACIDS IN RAT CEREBRAL CORTEX

The influence of hyperthermia on cerebral blood flow, cerebral metabolic rate for oxygen and cerebral metabolite levels was studied by increasing body temperature from 37° to 40°C and 42°C in rats under nitrous oxide anaesthesia maintained at constant arterial CO₂ tension. The metabolic rate for oxygen increased by 5-6% per degree centigrade. At 42°C the increase in cerebral blood Row was comparable to that in the metabolic rate. The increased temperatures were not accompanied by changes in organic phosphates (phosphocreatine, ATP, ADP or AMP) or in lactate/pyruvate ratio. There was an increase in the tissue to blood glucose concentration ratio. At steady state, there was an increase in glucose-6-phosphate but no other changes in glycolytic metabolites or citric acid cycle intermediates, and the only change in amino acids studied (glutamate, glutamine, aspartate, alanine and GABA) was an increase in glutamate concentration.     

METABOLISM OF BRAIN DURING SLEEP AND WAKEFULNESS

Abstract— The levels in brain of lactate, pyruvate, creatine phosphate, ATP, ADP and AMP were examined in sleeping and waking adult rats. The animals were monitored electrophysiologically and the biochemical measurements were made after approx. 25 min of sleep or wakefulness. The previous treatment of the animals had a marked effect on the levels of brain metabolites during sleep. In animals not acclimatized to the observation chamber, brain levels of lactate and pyruvate rose during sleep above those in the waking state: creatine phosphate and ATP were depressed somewhat. When the animals were acclimatized by being placed in the observation chamber for at least 2 h on four or more consecutive days prior to the experiment, sleep was accompanied by a depression of brain levels of lactate and pyruvate and slight elevations of brain levels of creatine phosphate and ATP. No significant differences in the EEG recordings were noted between the sleeping rats of the acclimatized and non-acclimatized groups. These observations on the effect of acclimatization on brain metabolism during sleep may have clinical relevance in man.     

CEREBRAL METABOLIC CHANGES IN PROFOUND, INSULIN-INDUCED HYPOGLYCEMIA, AND IN THE RECOVERY PERIOD FOLLOWING GLUCOSE ADMINISTRATION

Severe hypoglycemia was induced by insulin in lightly anaesthetized (70°_o N₂O) and artificially ventilated rats. Brain tissue was frozen in situ after spontaneous EEG potentials had disappeared for 5. 10. 15 or 30 min and cerebral cortex concentrations of labile organic phosphates, glycolytic metabolites, ammonia and amino acids were determined. In other experiments, recovery was induced by glucose injection at the end of the period of EEG silence. All animals with an isoelectric EEG showed extensive deterioration of the cerebral energy state. and gross perturbation of amino acid concentrations. The latter included a 4-fold rise in aspartate concentration and reductions in glutamate and glutamine concentrations to 20 and 5^o_o of control levels respectively. There was an associated rise in ammonia concentration to about 3μmol-g^-1. Administration of glucose brought about extensive recovery of cerebral energy metabolism. For example, after an isoelectric period of 30 min tissue concentrations of phosphocreatine returned to or above normal, the accumulation of ADP and AMP was reversed, there was extensive resynthesis of glycogen and glutamine and full normalisation of tissue concentrations of pyruvate. α-ketoglutarate. GABA and ammonia. However, even after 3 h of recovery there was a reduction in the ATP concentration and thereby in adenine nucleotide pool, moderate elevations of lactate content and the lactate pyruvate ratio, and less than complete restoration of the amino acid pool. It is concluded that some cells may have been irreversibly damaged by the hypoglycemia.     

Ammonia Intoxication: Effects on Cerebral Cortex and Spinal Cord

The effect of an acute systemic ammonia intoxication on the metabolic states of the cerebral cortex and the spinal cord of the same animal was studied in the cat. The intravenous infusion of ammonium acetate (2 and 4 mmol/kg body weight/30 min) increased the gross levels of tissue NH4+, glutamine, glutamine/glutamate ratio, lactate, and the lactate/pyruvate ratio in the cerebral cortex and the spinal cord. Pyruvate increased, but significantly only in the spinal cord; aspartate decreased, but significantly only in the cerebral cortex. The infusion of ammonium acetate did not significantly change the levels of phosphocreatine, ATP, ADP, AMP, total adenine nucleotides, adenylate energy charge, glucose, glutamate, alpha-ketoglutarate, and malate in either tissue. The changes of NH4+, glutamine, and lactate levels as well as glutamine/glutamate and lactate/pyruvate ratios in the spinal cord correlated significantly with the corresponding changes of these metabolites in the cerebral cortex. Thus, cerebral cortex and spinal cord show certain specific and comparable metabolic changes in response to a systemic ammonia intoxication. The effect of ammonia intoxication on the increases of glutamine and lactate levels is discussed.     

Relating Cerebral Ischemia and Hypoxia to Insult Intensity

The contributions of five variables believed to influence the brain's metabolism of O2 during hypoxia [duration, PaO2, delta CMRO2 (the difference between normal and experimental oxygen uptake), O2 availability (blood O2 content.CBF), and O2 deficit (delta CMRO2.duration)] were assessed by stepwise and multiple linear regression. Levels of brain tissue carbohydrates (lactate, glucose, and glycogen) and energy metabolites [ATP, AMP, and creatine phosphate (CrP)] were significantly influenced by O2 deficit during hypoxia, as was final CMRO2. After 60 min of reoxygenation, levels of tissue lactate, glucose, ATP, and AMP were related statistically to the O2 deficit during hypoxia; however, CMRO2 changes were always associated more significantly with O2 availability during hypoxia. Creatine (Cr) and CrP levels in the brain following reoxygenation were correlated more to delta CMRO2 during hypoxia. Changes in some brain carbohydrate (lactate and glucose), energy metabolite (ATP and AMP) levels, and [H+]i induced by complete ischemia were also influenced by O2 deficit. After 60 min of postischemic reoxygenation, brain carbohydrate (lactate, glucose, and glycogen) and energy metabolite (ATP, AMP, CrP, and Cr) correlated with O2 deficit during ischemia. We conclude that "O2 deficit" is an excellent gauge of insult intensity which is related to observed changes in nearly two-thirds of the brain metabolites we studied during and following hypoxia and ischemia.     

BRAIN ENERGETICS IN OXYGEN-INDUCED CONVULSIONS

Mice were exposed to 6 ATA of 100% oxygen. The effect of high oxygen pressure (OHP), disulphiram and both disulphiram and oxygen as a function of the length of oxygen exposure on cerebral cortical ATP, phosphocreatine, lactate, pyruvate and glucose was determined. Neither OHP nor disulphiram altered ATP prior to the onset of convulsions. The combination of OHP and disulphiram appeared to elevate cerebral ATP, particularly during the early exposure period. OHP had no effect on phosphocreatine, however, disulphiram, both alone and in combination with OHP increased cerebral cortical phosphocreatine. ATP and phosphocreatine were unchanged in mice sacrificed either at the onset or 9 s after the onset of oxygen convulsions. Lactate and pyruvate increased as the length of time the mice were exposed to OHP increased although neither lactate nor pyruvate levels differed significantly from control levels at either the onset or 9 s after the onset of convulsions. Disulphiram by itself lowered cerebral lactate, and prevented the increase in lactate and pyruvate in mice exposed to OHP. OHP and disulphiram increased cerebral glucose with the combination of both OHP and disulphiram appearing to have an additive effect. Glucose also remained elevated at the onset or 9 s after the onset of oxygen convulsions.     

MECHANISMS ACTIVATING GLYCOLYSIS IN THE BRAIN IN ARTERIAL HYPOXIA

Abstract— In order to study regulatory steps responsible for the activation of anaerobic glycolysis in the brain during hypoxia, cerebral concentrations of carbohydrate substrates and organic phosphates were measured in rats after reduction of the arterial P_O2 to 23-25 mm Hg for 2, 5 and 15 min. The results demonstrated a progressive accumulation of lactate as well as of pyruvate and malate in the absence of changes in ATP, A DP, AMP, citrate and ammonia. The pattern of substrate changes obtained indicate that hypoxia is accompanied by activation of pyruvate kinase and of hexokinase, but not of phosphofructokinase. There was a progressive fall in intracellular pH and a moderate increase in the calculated cytoplasmic NADH/NAD⁺ ratio. The changes in pyruvate and in the NADH/NAD⁺ ratio may be responsible for the observed increase in the malate concentration.     

Simple techniques for freeze clamping and for cutting and milling of frozen tissue at low temperature for the purpose of two- or three-dimensional metabolic studies in vivo

A technique is described for freeze-clamping of parenchymal tissue (e.g., liver) which causes the tissue to be rigidly fixed to an aluminium cup in the frozen state with a well-defined, reproducible orientation of the tissue as well as a minimum of morphological distortion of the major part of the sample. Furthermore, three instruments for low-temperature cutting or milling of the frozen sample for the purpose of two- or three-dimensional metabolic studies are described. The cutting and milling instruments work according to the principle of ordinary workshop machines for steel work. The frozen sample fixed in the aluminium cup may be mounted in the milling instrument and cut at the temperature of liquid nitrogen with high precision; e.g., one instrument may be adjusted to mill off tissue layers of a thickness of only 20 μm. Thermocouple readings from the frozen sample suggest that the milling process does not cause significant heating of the sample. This is further supported by the fact that the amount of labile metabolites, ATP, ADP, AMP, lactate, and pyruvate, is unaffected by the milling process.