Quantitative measurement of blood flow and oxygen consumption in the rat brain

Brain metabolism modulates neuronal excitability in a mouse model of pyruvate dehydrogenase deficiency

Glucose is the ultimate substrate for most brain activities that use carbon, including synthesis of the neurotransmitters glutamate and γ-aminobutyric acid via mitochondrial tricarboxylic acid (TCA) cycle. Brain metabolism and neuronal excitability are thus interdependent. However, the principles that govern their relationship are not always intuitive because heritable defects of brain glucose metabolism are associated with the paradoxical coexistence, in the same individual, of episodic neuronal hyperexcitation (seizures) with reduced basal cerebral electrical activity. One such prototypic disorder is pyruvate dehydrogenase (PDH) deficiency (PDHD). PDH is central to metabolism because it steers most of the glucose-derived flux into the TCA cycle. To better understand the pathophysiology of PDHD, we generated mice with brain-specific reduced PDH activity that paralleled salient human disease features, including cerebral hypotrophy, decreased amplitude electroencephalogram (EEG), and epilepsy. The mice exhibited reductions in cerebral TCA cycle flux, glutamate content, spontaneous, and electrically evoked in vivo cortical field potentials and gamma EEG oscillation amplitude. Episodic decreases in gamma oscillations preceded most epileptiform discharges, facilitating their prediction. Fast-spiking neuron excitability was decreased in brain slices, contributing to in vivo action potential burst prolongation after whisker pad stimulation. These features were partially reversed after systemic administration of acetate, which augmented cerebral TCA cycle flux, glutamate-dependent synaptic transmission, inhibition and gamma oscillations, and reduced epileptiform discharge duration. Thus, our results suggest that dysfunctional excitability in PDHD is consequent to reduced oxidative flux, which leads to decreased neuronal activation and impaired inhibition, and can be mitigated by an alternative metabolic substrate.

Transcript Analysis of Zebrafish GLUT3 Genes, slc2a3a and slc2a3b, Define Overlapping as Well as Distinct Expression Domains in the Zebrafish (Danio rerio) Central Nervous System

The transport of glucose across the cell plasma membrane is vital to most mammalian cells. The glucose transporter (GLUT; also called SLC2A) family of transmembrane solute carriers is responsible for this function in vivo. GLUT proteins encompass 14 different isoforms in humans with different cell type-specific expression patterns and activities. Central to glucose utilization and delivery in the brain is the neuronally expressed GLUT3. Recent research has shown an involvement of GLUT3 genetic variation or altered expression in several different brain disorders, including Huntington's and Alzheimer's diseases. Furthermore, GLUT3 was identified as a potential risk gene for multiple psychiatric disorders. To study the role of GLUT3 in brain function and disease a more detailed knowledge of its expression in model organisms is needed. Zebrafish (Danio rerio) has in recent years gained popularity as a model organism for brain research and is now well-established for modeling psychiatric disorders. Here, we have analyzed the sequence of GLUT3 orthologs and identified two paralogous genes in the zebrafish, slc2a3a and slc2a3b. Interestingly, the Glut3b protein sequence contains a unique stretch of amino acids, which may be important for functional regulation. The slc2a3a transcript is detectable in the central nervous system including distinct cellular populations in telencephalon, diencephalon, mesencephalon and rhombencephalon at embryonic and larval stages. Conversely, the slc2a3b transcript shows a rather diffuse expression pattern at different embryonic stages and brain regions. Expression of slc2a3a is maintained in the adult brain and is found in the telencephalon, diencephalon, mesencephalon, cerebellum and medulla oblongata. The slc2a3b transcripts are present in overlapping as well as distinct regions compared to slc2a3a. Double in situ hybridizations were used to demonstrate that slc2a3a is expressed by some GABAergic neurons at embryonic stages. This detailed description of zebrafish slc2a3a and slc2a3b expression at developmental and adult stages paves the way for further investigations of normal GLUT3 function and its role in brain disorders.

Methamphetamine causes sustained depression in cerebral blood flow

The use prevalence of the highly addictive psychostimulant methamphetamine (MA) has been steadily increasing over the past decade. MA abuse has been associated with both transient and permanent alterations in cerebral blood flow (CBF), hemorrhage, cerebrovascular accidents and death. To understand MA-induced changes in CBF, we exposed C56BL/6 mice to an acute bolus of MA (5mg/kg MA, delivered IP). This elicited a biphasic CBF response, characterized by an initial transient increase (~ 5 minutes) followed by a prolonged decrease (~ 30 minutes) of approximately 25% relative to baseline CBF--as measured by laser Doppler flowmetry over the somatosensory cortex. To assess if this was due to catecholamine derived vasoconstriction, phentolamine, an α-adrenergic antagonist was administered prior to MA treatment. This reduced the initial increase in CBF but failed to prevent the subsequent, sustained decrease in CBF. Consistent with prior reports, MA caused a transient increase in mean arterial blood pressure, body temperature and respiratory rate. Elevated respiratory rate resulted in hypocapnia. When respiratory rate was controlled by artificially ventilating mice, blood PaCO(2) levels after MA exposure remained unchanged from physiologic levels, and the MA-induced decrease in CBF was abolished. In vivo two-photon imaging of cerebral blood vessels revealed sustained MA-induced vasoconstriction of pial arterioles, consistent with laser Doppler flowmetry data. These findings show that even a single, acute exposure to MA can result in profound changes in CBF, with potentially deleterious consequences for brain function.

Measuring the effects of indomethacin on changes in cerebral oxidative metabolism and cerebral blood flow during sensorimotor activation

The work presented here uses combined blood oxygenation level-dependent (BOLD) and arterial spin tagging (AST) approaches to study the effect of indomethacin on cerebral blood flow (CBF) and oxygen consumption (CMRO(2)) increases during motor activation. While indomethacin reduced the CBF increase during activation, it did not significantly affect the CMRO(2) increase during activation. The ratio of the activation-induced CBF increase in the presence and absence of indomethacin was 0.54 +/- 0.08 (+/-SEM, n = 8, P < 0.001), while the ratio of the CMRO(2) increase in the presence and absence of the drug was 1.02 +/- 0.08 (+/-SEM, N = 8, ns). Potential difficulties in estimating CMRO(2) changes from combined BOLD/AST data are discussed.

The Kety-Schmidt technique for repeated measurements of global cerebral blood flow and metabolism in the conscious rat

Cerebral activation will increase cerebral blood flow (CBF) and cerebral glucose uptake (CMRglc) more than it increases cerebral uptake of oxygen (CMR(O2)). To study this phenomenon, we present an application of the Kety-Schmidt technique that enables repetitive simultaneous determination of CBF, CMR(O2), CMRglc and CMRlac on awake, non-stressed animals. After constant intravenous infusion with 133Xenon, tracer infusion is terminated, and systemic arterial blood and cerebral venous blood are continuously withdrawn for 9 min. In this paper, we evaluate if the assumptions applied with the Kety-Schmidt technique are fulfilled with our application of the method. When measured twice in the same animal, the intra-individual variation for CBF, CMR(O2), and CMRglc were 10% (SD: 25%), 8% (SD: 25%), and 9% (SD: 28%), respectively. In the awake rat the values obtained for CBF, CMR(O2) and CMRglc were 106 mL [100 g](-1) min(-1), 374 micromole [100 g](-1) min(-1) and 66 micromole [100 g](-1) min(-1), respectively. The glucose taken up by the brain during wakefulness was fully accounted for by oxidation and cerebral lactate efflux. Anaesthesia with pentobarbital induced a uniform reduction of cerebral blood flow and metabolism by approximately 40%. During halothane anaesthesia CBF and CMRglc increased by approximately 50%, while CMR(O2) was unchanged.

Functional, metabolic, and circulatory changes associated with seizure activity in the postischemic brain

The present study was undertaken to explore how transient ischemia in rats alters cerebral metabolic capacity and how postischemic metabolism and blood flow are coupled during intense activation. After 6 h of recovery following transient forebrain ischemia 15 min in duration, bicuculline seizures were induced, and brains were frozen in situ after 0.5 or 5 min of seizure discharge. At these times, levels of labile tissue metabolites were measured, whereas the cerebral metabolic rate for oxygen (CMRO2) and cerebral blood flow (CBF) were measured after 5 min of seizure activity. After 6 h of recovery, and before seizures, animals had a 40-50% reduction in CMRO2 and CBF. However, because CMRO2 rose three-fold and CBF fivefold during seizures, CMRO2 and CBF during seizures were similar in control and postischemic rats. Changes in labile metabolites due to the preceding ischemia encompassed an increased phosphocreatine/creatine ratio, as well as raised glucose and glycogen concentrations. Seizures gave rise to minimal metabolic perturbation, essentially comprising reduced glucose and glycogen contents and raised lactate concentrations. It is concluded that although transient ischemia leads to metabolic depression and a fall in CBF, the metabolic capacity of the tissue is retained, and drug-induced seizures lead to a coupled rise in metabolic rate and blood flow.

Cerebral blood flow and metabolic rate in the conscious, freely moving rat: the effects of hypercapnia, and acute ethanol administration

We propose a simple method that can be used to measure cerebral blood flow (CBF), cerebral oxygen consumption (CMRO2), and cerebral glucose consumption (CMRglu) in the conscious, freely moving rat. The method is based on the classical Kety-Schmidt approach, and uses a chronic cannula in the confluens sinuum. We tested the method by investigating the response of CBF, CMRO2, and CMRglu to hypercapnia and used the approach to investigate the effects of acute alcohol administration. Severe hypercapnia (PaCO2 approximately 80 mmHg) increased the CBF by a factor of 3.5, decreased the CMRO2 by 30%, and had no significant effect on the CMRglu. Under normocapnic conditions moderate blood alcohol levels (100-200 mg%) caused no significant effects on CBF, CMRO2, or CMRglu, but high blood alcohol levels (250-400 mg%) decreased all three parameters by approximately 25%. Under hypercapnic conditions high blood alcohol levels had no effect on CBF, CMRO2, and CMRglu.

Measurement of cerebral blood flow in rat brain by 19F-NMR detection of trifluoromethane washout

The washout of trifluoromethane (CHF3) from rat cerebral cortex was monitored by 19F NMR. After 15 min of inhalation of 67% CHF3/33% O2 the fluorine signal detected was in a steady state. The CHF3 was switched off rapidly at the endotracheal tube and the washout detected with 12-s time resolution. Two models were used to extract flow information, a simple exponential fit and a model which accounts for arterial CHF3 recirculation. In both cases, a two-compartment model fit the data significantly better than a one-compartment model. In both models, the faster time component varied with increasing pCO2, but no significant change in the slow component was detected. At control values of pCO2, there was a small difference in washout rate constants derived from the two models. At high pCO2, when tissue washout was comparable to arterial washout of CHF3, the model which accounted for arterial recirculation gave higher flows. Using this two-compartment model with correction for recirculation, a control flow (pCO2 = 35 mm Hg) of 0.73 +/- 0.04 ml/min/g was measured. Increasing plasma pCO2 increased the apparent flow six- to sevenfold with a 4.4% increase in flow per millimeter of Hg change in CO2. These results are qualitatively in agreement with results found by others using the washout of 133Xe. However, this method yields values for flow that are lower than those obtained using 133Xe washout, probably because of diffusion limitations of CHF3.

Sciatic nerve blood flow response to carbon dioxide

Sciatic nerve blood flow (NBF) during hypercarbia was examined in unanesthetized decerebrate rats by means of laser Doppler flowmetry (LDF). During inspiration of gas mixtures containing no CO2, followed by either 5, 10 or 20% CO2, arterial pCO2 increased by 13, 18 and 68 mm Hg, respectively. Blood pressure (BP) and the LDF signal, which were measured continuously, increased for 30-40 s following the start of inhalation of CO2 and then decreased. Three min after the start of inhalation of 5 or 10% CO2, BP had returned to the baseline and the LDF signal was increased by 14 and 15%, respectively, compared with preinhalation values. In rats inspiring 20% CO2, systemic BP remained elevated 12% above the baseline and NBF was increased by 18%. The results indicate that dilatation of the vasa nervorum during hypercarbia is less than that at cerebral blood vessels. The nerve vasculature dilates maximally in response to 5% CO2, with a rise in NBF of about 1.1% per mm Hg increase in paCO2.

Cerebral oxygen consumption and blood flow in Fischer-344 rats of different ages

Regional cerebral oxygen consumption and blood flow were determined and compared in conscious male Fischer-344 rats at 3, 12, 24 and 33 months of age to correlate the reported regional neurochemical and morphological changes which occur in these parameters during development, maturation, aging and senescence. Cerebral blood flow was determined with 14[C]-labelled iodoantipyrine and regional cerebral arterial and venous oxygen saturation was measured microspectrophotometrically. Oxygen consumption was obtained by multiplying cerebral blood flow and oxygen extraction. Systolic and diastolic blood pressure and heart rate decreased significantly with age. Average cerebral blood flow, oxygen extraction and oxygen consumption/100 g did not differ significantly between the four age groups examined. Oxygen consumption averaged 2.9 +/- 0.1 ml O2/min/100 g (mean +/- S.E.M.) in the 3-month-old group and 3.6 +/- 0.1 ml O2/min/100 g in the 33-month-old group. Differences in flow among the examined brain regions, which were present in the mature, 12-month-old brain, were not present in the developing, aging or senescent rat brain. Compensatory alterations in the efficiency or organization of neurochemical activity which occur during development, aging and senescence may modify the inter-regional differences in cerebral blood flow and oxygen consumption noted during maturation. There was no correlation found between the neurochemical and morphological changes which have been reported during maturation, aging or senescence and regional cerebral oxygen consumption.

Regional cerebral blood flow in acute experimental allergic encephalomyelitis

Regional cerebral blood flow was studied in Lewis rats with fulminant acute experimental allergic encephalomyelitis (EAE). [14C]iodoantipyrine was used as a tracer. By employing a short experimental time and an infusion schedule producing an increasing arterial tracer concentration, the spatial resolution of the method was fine enough to detect focal increases in blood flow in the small central nervous system lesions (lymphocytic accumulations). An increase of flow of 100% in the lesions and a decrease of 50% in the cerebral cortex of EAE animals was statistically significant. In all other regions studied (deep cerebral structures, cerebellum), blood flow in EAE animals did not differ from the control values. The flow increase corresponding to the lesions may be due to inflammatory hyperemia. The cortical decrease in flow may be secondary to sensory motor impairment.

Effects of xenon and krypton on regional cerebral blood flow in the rat

The effects of high inspired concentrations of xenon and krypton on regional CBF (rCBF) were assessed in the rat using [14C]iodoantipyrine and quantitative autoradiography. Inhalation of 80% xenon for 1 or 2 min and inhalation of 40% xenon for 2 min were found to have significant effects on rCBF, including average increases of 75-96% in cerebral neocortical regions. Inhalation of 40% xenon for 1 min and of 80% krypton for 2 min had no significant effect on rCBF in most brain regions studied. If xenon inhalation produces effects on rCBF in humans similar to those observed in the rat, such effects could be an important source of error in xenon computed tomography rCBF studies.

Measurement of cerebral blood flow in the rat with intravenous injection of [11C]butanol by external coincidence counting: a repeatable and noninvasive method in the brain

No method has been reported for measuring CBF, repeatedly and noninvasively, in the rat brain. A new method is described, which is noninvasive to the brain, skull, or cervical large vessels. Two pairs of coincidence detectors were positioned, one over the rat brain and the other at the loop of a catheter inserted into the femoral artery. The coincidence head curve and arterial curve were recorded after intravenous injection of 1-[11C]butanol in 15 rats. CBF was calculated by one-compartment curve fitting ( CBFo ) from 1-min data and with the recirculation corrected height/area method from 3-min data ( CBFh X 3 min) and 5-min data ( CBFh X 5 min). CBFo agreed well with CBFh X 5 min, although a slight overestimation was observed in CBFh X 3 min. The normal CBFo in the normocapnic group (n = 6, paCO2 36.7 +/- 2.3 mm Hg) was 1.76 +/- 0.49 ml/g min (mean +/- SD). A good correlation was observed between CBFo (y) and PaCO2 (x), and the regression line was y = 0. 0629x -0.715 (r = 0.88, p less than 0.0001). We concluded that this method gives the stable blood flow values noninvasively and with a minimum loss of blood (less than 0.28 ml per measurement). Applications of this method include activation studies, studies on the effect of drugs and treatments, and water and oxygen extraction fraction studies using different tracers in the same rat.

Cerebral metabolic and circulatory effects of 1,1,1-trichloroethane, a neurotoxic industrial solvent. 1. Effects on local cerebral glucose consumption and blood flow during acute exposure

The effects of inhaled 1,1,1-trichloroethane (3500, 6000, and 7800 ppm) on behavior, local cerebral blood flow, and local cerebral glucose consumption were studied in awake rats. The effect of the solvent inhalation on the EEG pattern and local cerebral blood flow was also studied in paralyzed animals under N2O analgesia. Exposure of awake animals to 6000 ppm 1,1,1-trichloroethane induced a decrease in motility and exploratory behavior. At 7800 ppm the rats were clearly ataxic. The local cerebral glucose consumption in 23 brain regions was studied by the [14C]deoxyglucose technique. A decrease was observed ranging from 14 to 55% of control values. The inferior colliculus and substantia nigra displayed the largest reductions. In exposed animals the local cerebral blood flow increased in 11 brain structures by 28-45%. In animals under N2O analgesia, 7400 ppm 1,1,1-trichloroethane induced a depression of the EEG activity. In these animals the local cerebral blood flow increased by 12-99%, with a large variability in blood flow between the different structures. It is concluded that exposure of rats to subanesthetic doses of 1,1,1-trichloroethane induces an increase in cerebral blood flow in spite of a concomitant decrease in glucose consumption and depression of cerebral function.

Local blood flow and glucose consumption in the rat brain during sustained bicuculline-induced seizures

The present study addresses the problem of whether brain structures which have been shown to develop neuronal cell damage in recurrent or prolonged epileptic seizures have higher metabolic rates and/or less pronounced increases in blood flow rates than others during sustained seizures. To that end, local cerebral blood flow (CBF) and glucose utilization (CMRgl) were measured autoradiographically in ventilated rats, in which seizures of 20, 60, or 120 min duration were induced by i.v. bicuculline. After 20 and 60 min of seizure activity, local CBF increased 2- to 4-fold in most of the 21 structures analysed. However, there was a marked heterogeneity with CBF values varying between 150% (caudoputamen) and 500% (globus pallidus) of control. After 120 min, CBF in several structures, notably cortical and limbic regions, fell in spite of unchanged blood pressure and continued seizure activity. Changes in local CMRgl were equally heterogenous, and correlated poorly with blood flow rates. Some structures (the cerebral cortices and 3 limbic areas) showed a sustained 2-4 fold increase in CMRgl. In these, metabolic rate and blood flow were initially matched but CBF subsequently fell to yield a pattern of relative hypoperfusion. Other structures showed no, or only moderate, increases in CMRgl. In spite of this, CBF increased markedly to yield a pattern of relative hyperemia. It is concluded that bicuculline-induced seizures represent a condition in which structures, observed to be prone to develop cell damage, show grossly enhanced metabolic rate and develop relative underperfusion. Furthermore, the results suggest that structures with a large increase of the metabolic rate during seizures, develop a striking mismatch between local metabolic rate and blood flow.

A venous outflow method for measurement of rapid changes of the cerebral blood flow and oxygen consumption in the rat

A technique for continuous measurement of cerebral venous outflow in the rat is described. The method involves cannulation of one retroglenoid vein close to its exit from the skull, and diversion of cerebral venous blood through a closed extracorporal circuit with a drop recording device, the blood being returned to the central venous circulation via a catheter in the external jugular vein. Occlusion of the contralateral retroglenoid vein increases measured flow and minimizes extracerebral contamination of the diverted cerebral venous blood. The venous outflow system is not further isolated from cerebral or potential extracerebral collaterals. Thus, the mass of tissue drained cannot be exactly defined anatomically. However, the experiments involving changes of PP, arterial CO2 tension, and induction of epileptic seizure activity, and simultaneous indirect measurements with radioactive tracer technique, indicate that significant extracerebral contamination does not occur and that in short term measurements the venous outflow represents cerebral blood flow (CBF) in a constant mass of (dorsal and central, mainly forebrain) cerebral tissue. Measurement of arterial blood pressure and pressure in the cisterna magna allows calculation of cerebral perfusion pressure (PP). By simultaneous measurement of arterial and cerebral venous oxygen content changes in cerebral oxygen consumption (CMRO2) can be calculated. The method has been applied to document several situations of transient CBF and CMRO2 changes.

Cerebral circulatory response to hypercapnia: effects of lesions of central dopaminergic and serotoninergic neuron systems

The present study explores the possibility that the central dopaminergic and serotoninergic neuron systems influence CBF under normocapnic and hypercapnic conditions. In the first part of the study the effect of unilateral 6-hydroxydopamine lesion of the nigrostriatal dopamine pathway on local cerebral blood flow (1-CBF) was measured autoradiographically with [14C]iodoantipyrine as the diffusible tracer. The lesion caused no major effect on CBF under normocapnic or hypercapnic conditions. However, the circulatory response to hypercapnia was slightly enhanced (about 10%) in the denervated caudate-putamen. It is suggested that under hypercapnic conditions the pronounced increase in blood flow in the caudate-putamen is normally modulated by a slight vasoconstriction caused by dopamine release from the nigrostriatal system. In the second part of the study the effect of intraventricular 5,7-dihydroxytryptamine on cerebral metabolic rate for oxygen (CMRO2) and CBF was evaluated using a 133xenon modification of the Kety-Schmidt inert gas technique. The lesion, which removed about 90% of cortical 5-hydroxytryptamine, had no effect on the circulatory response to hypercapnia, not did it alter CMRO2. Under normocapnic conditions, though, the lesion seemed to induced a minor increase in CMRO2, which indicates that the serotoninergic system exerts a depressant resting tone on metabolic rate in the brain.

Cerebral blood flow and oxygen consumption in normocapnia and hypercapnia: modulating influence of paravertebral sympathetic blockade at the low thoracic level

The objective of the present study was to explore whether the systemic consequences of sympathoadrenal activation influence the cerebral circulatory and metabolic effects of hypercapnia in the rat. To that end, a bilateral blockade of the sympathetic chain was performed at the low thoracic level by paravertebral injection of local anaesthetic. The injection was followed by a reduction in blood pressure and, in comparison to animals injected with local anaesthetic intramuscularly, those with paravertebral blockade showed lower blood and tissue concentrations of glucose and lactate. Overall ("cortical") CBF and CMRO2 were measured with a 133xenon modification of the Kety-Schmidt technique, and local CBF was estimated autoradiographically with 14C-iodoantipyrine as the diffusible tracer. Paravertebral blockade failed to modify the circulatory response to hypercapnia, nor did it prevent the increase in CMRO2d previously noted in this preparation. In animals maintained ventilated on 70% N2O, paravertebral blockade reduced overall CBF by 30% and local CBF by 30-40%, with a suggested but statistically nonsignificant reduction in CMRO2. In unparalysed, awake animals the blockade failed to affect local CBF. It is concluded, therefore, that blockade of the sympathetic chain causes a reduction of CBF only in the stressful conditions prevailing in paralysed and ventilated animals.

Simultaneous measurement of blood flow and glucose metabolism by autoradiographic techniques

A double tracer autoradiographic technique using 131I-iodo-antipyrine and 14C-deoxyglucose is presented for the simultaneous measurement of blood flow and cerebral glucose utilization in the same animal. 131I is a gamma emitting isotope with a half life of 8.06 days and can be detected with adequate resolution on standard autoradiographic films. Autoradiograms are made before and after decay of 131I; the time interval between the 2 exposures and the concentration of the 2 tracers is adjusted to avoid significant cross-contamination. In this way, 2 film exposures are obtained which can be processed quantitatively like single tracer autoradiograms. The validity of the method for the investigation of local coupling of flow and metabolism was tested under various physiological and pathophysiological conditions. Coupling was tight in barbiturate-anesthetized healthy animals, but not under halothane anesthesia where uncoupling occurred in various subcortical structures. Focal seizures induced by topical application of penicillin on the cortical surface led to a coupled increase of metabolism and flow in thalamic relay nuclei but not at the site of penicillin administration where increased glucose utilization was not accompanied by similar increase in blood flow. Both coupled and uncoupled increases in local glucose utilization were observed in spreading depression and in circumscribed areas of experimental brain tumors. The results obtained demonstrate that double tracer autoradiography allows allows the very precise local assessment of cerebral blood flow and glucose utilization, and, therefore, is particularly suited to the study of regional coupling processes under various experimental conditions.

Cerebral blood flow in rats during physiological and humoral stimuli

The technique for estimating cerebral blood flow (CBF) in anesthetized rats by injecting 133Xe into the internal carotid artery represents a potentially useful and inexpensive model for screening cerebral vascular responses to pathophysiological and pharmacological stimuli. We have examined associated neuropathology, the validity and the reproducibility of the method, and made comparisons of initial slope estimates of CBF with those obtained by stochastic analysis. Initial slope estimates (CBF = 1.62 +/- 0.04 ml min-1g-1, X +/- SE, N = 38) were linearly related to stochastic measurements (CBF = 1.42 +/- 0.09 ml min-1g-1, N = 6), and overestimated mean CBF by about 15%. A reactivity to CO2 of 0.05 ml min-1g-1 per mm Hg, and an auto-regulation range of 70 to 180 mm Hg were found. CBF responses to the intra-arterial infusion of aminergic drugs were determined before and after opening of the blood-brain barrier with hypertonic urea. Serotonin reduced CBF after, but not before, the administration of urea. Acetylcholine increased CBF when the barrier was intact, the effect being augmented when the barrier was disrupted; these responses were reduced by atropine. Histamine increased CBF only after barrier opening, and this response was attenuated by the H2-receptor antagonist, metiamide. These studies indicate that initial slope estimates of CBF derived in rats from intracarotid 133Xe injection, which represents an inexpensive and simplified approach for screening cerebral circulatory adjustments, may facilitate the characterization of stimuli affecting CBF.

The effect of indomethacin on cerebral blood flow and oxygen consumption in the rat at normal and increased carbon dioxide tensions

The effect of the fatty acid cyclo-oxygenase inhibitor indomethacin on cerebral blood flow (CBF) and the metabolic rate for oxygen (CMRO2) was studied in paralyzed and artificially ventilated rats. In normocapnic animals, the drug (10 mg.kg-1i.v.) reduced CBF to 50% of control without a measurable effect on CMRO2. During hypercapnia (PaCO2 70-80 mmHg) the increase in CBF was reduced by about 80% but CMRO2 remained unchanged. Autoradiographic evaluation of local CBF in 20 brain structures indicated that the reduction in CBF was relatively uniform throughout the brain. Dose response curves showed that an effect on CBF was evident already at an indomethacin dose of 1 mg.kg-1 and maximal effects were obtained with 3-5 mg.kg-1. Following i.v. injection of the drug reduction in CBF was observed already after 10 s and the full response occurred after 1-2 min. It is concluded that metabolites of arachidonic acid, possibly mainly prostacyclin, are powerful modulators of normal cerebrovascular tone, and help to mediate the CBF response to increased CO2 tensions. However, since indomethacin does not modify the circulatory response in other conditions with increased CBF these substances do not qualify as general coupling factors controlling CBF in physiological or pathological states.

Effects of indomethacin on cerebral blood flow and oxygen consumption in barbiturate-anesthetized Normocapnic and hypercapnic rats

Although results obtained in baboons and rats have demonstrated that the fatty acid cyclo-oxygenase inhibitor indomethacin reduces cerebral blood flow (CBF) under control conditions and markedly attenuates the CBF response to hypercapnia, nonconfirmatory results have been obtained in rabbits and cats. Since these latter studies were carried out under barbiturate anesthesia, we tested the effect of indomethacin (10 mg kg-1) on CBF and cerebral oxygen consumption in rats anesthetized with 150 mg kg-1 of phenobarbital. At normocapnia the barbiturate reduced CBF, measured with a 133Xe modification of the Kety-Schmidt technique, to about 50% of nitrous oxide control values as previously determined with a similar technique. At this CBF level, indomethacin induced a small, albeit highly significant decrease in CBF. We suggest that a reduction of this magnitude will escape detection with some CBF techniques in current use. Indomethacin induced a highly significant decrease in CBF during hypercapnia, demonstrating that the barbiturate does not eliminate the effect of indomethacin on CO2 responsiveness. The magnitude of the reduction in CO2 response was so large that is should be detected with most methods for measuring CBF. A comparison with previous data on animals under 70% N2O demonstrated that phenobarbital reduced the CO2 responsiveness. defined as the ratio deltaCBF/deltaPCO2, to 39% of that observed under nitrous oxide analgesia. With both types of anesthesia, indomethacin curtailed the CO2 responsiveness 4- to 5-fold.

Influence of nitrous oxide on local cerebral blood flow in awake, minimally restrained rats

In order to evaluate the effect of 70-80% N2O on local cerebral blood flow (1-CBF) in the rat brain, we developed a procedure for measuring CBF by an autoradiographic [14C]iodoantipyrine technique in awake, minimally restrained animals. Results on 1-CBF, as measured in 22 different structures, showed little variability between animals. In the majority of structures analyzed, 70-80% N2O failed to alter 1-CBF. These included all cerebral cortical and most subcortical structures. However, nitrous oxide reduced CBF in the inferior colliculus and the superior olive, in two of the limbic structures analyzed, and in the hypothalamus. In no structure, except the striatum (p less than 0.05), was a significant increase in 1-CBF obtained in N2O-breathing animals. However, the results suggest that CBF may have been increased in the auditory cortex. Immobilization was found to reduce 1-CBF in the cerebellum, inferior colliculus, superior olive, hippocampus, and septal nuclei. The results also suggest that the procedure somewhat increased CBF in frontal and parietal cortex. When the results obtained in awake, air-breathing animals were compared with those obtained in immobilized animals ventilated on N2O, there was no significant increase in any of the structures analyzed, although there were suggested increases in all cortical areas except the visual cortex. However, the data showed that ventilation with 70-80% N2O significantly decreased CBF in several structures (inferior colliculus, superior olive, hippocampus, amygdala, septal nuclei, and hypothalamus). In some of these, the effects of 70-80% N2O and of immobilization were obviously additive.

The increase in extracellular potassium concentration in the ischemic brain in relation to the preischemic functional activity and cerebral metabolic rate

The course of ischemic increase of extracellular potassium concentration ([K+]e) was studied in rat cerebral cortex with potassium selective microelectrodes and correlated to the preischemic functional and metabolic state. Complete cerebral ischemia was induced in artificially ventilated rats by cardiac arrest. Seven different functional states including conditions with cerebral hypermetabolism (seizures, amphetamine intoxication, hyperthermia) and hypometabolism (barbiturate anesthesia, hypothermia) were chosen in order to cover a wide range of cerebral metabolic rates (CMRO2 : 28.7--2.4 ml O2/(100 g)/min). The ischemic increase of [K+]e was delayed in conditions with low CMRO2 and accelerated in conditions with high CMRO2; the time interval to the terminal steep rise in extracellular potassium concentration varied within the extremes of 35 +/- 5 and 365 +/- 12 sec (means +/- S.E.M.), the control state (N2O-analgesia) being 116 +/- 5 sec. In groups with high CMRO2 electrocortical activity ceased within 15 sec and in groups with low CMRO2 within 22 sec. The rates of the ischemic [K+]e increase, measured as rate of change in the potassium electrode potential (mV/sec), remained high in conditions with high preischemic CMRO2 and low in conditions with low CMRO2, indicating a remaining influence of the preischemic metabolism on membrane ion permeability. These results support previous metabolic data indicating that the rate of consumption of high energy phosphates during ischemia mirrors the preischemic cerebral metabolic rate. Phenobarbital anesthesia did not change the initial rate of [K+]e increase but reduced the rate of [K+]e increase later during ischemia, suggesting a special effect of barbiturates on partly depolarized membranes.

Validity of cerebral blood flow measurements obtained with quantitative tracer techniques

A great number of results for the cerebral blood flow obtained in the animal with quantitative tracer techniques have been collected from the literature. They are exposed in order to compare both normal flow values in different laboratory species, and the characteristics, accuracy and sensitivity of each technique. A dramatic overall dispersion of flow values is observed, allowing neither the flow level particular to each species to be estimated, nor the average value provided by a given technique to be found. The physiological and technological causes of such a dispersion are discussed. Several techniques seem to have limitations which even alter the interpretation of their results, and especially the origin of the local or regional blood flow results. Other techniques may be criticized from the quantitative standpoint, but give more reliable results.

Regional cerebral blood flow in the rat during prolonged seizure activity

In order to evaluate the possible contribution of regional insufficiency in blood flow to the development of epileptic brain damage, we have measured changes in total and regional cerebral blood flow (tCBF and rCBF) during the course of prolonged sustained seizures. We have used both a particle distribution method (radioactively labelled microspheres) and a diffusible tracer method (iodo [14C]antipyrine). Seizures were induced with bicuculline (1.2 mg/kg, i.v.) in rats with neuromuscular paralysis, mechanically ventilated with 70% N2O/30% O2, rCBF was determined in 13 brain regions after 10, 30, 60 and 120 min of seizure activity. Microsphere and iodo[14C]antipyrine methods gave identical control values for tCBF (0.88 +/- 0.02 vs 0.86 +/- 0.07 ml/g brain/min) and closely similar rCBF values. The increases in tCBF after 10 and 30 min seizure activity were less as measured with microspheres than with iodo [14C]antipyrine (2.42 +/- 0.29 vs. 4.99 +/- 0.94 and 1.79 +/- 0.18 vs 3.05 +/- 0.30 mg/g brain/min, respectively). With microspheres, rCBF values showed considerable interhemisphere variability, but did not do so with iodo [14C]antipyrine. The regional pattern of flow changed during seizures. Changes in neocortical rCBF tended to match changes in tCBF. Consistent decreases in rCBF relative to tCBF were seen in the pons-medulla and cerebellum at all seizures times. Relative increases in rCBF were seen at all seizure times in the thalamus, and at 10 and 30 min in colliculi and midbrain. In the hippocampus, rCBF was unchanged (relative to tCBF) at 10 and 30 min, but was increased at 60 and 120 min of seizure activity. Thus, regions developing epileptic brain damage in this model of status epilepticus (hippocampus, thalamus, neocortex) show increases in rCBF greater than those in regions not showing brain damage (cerebellum, brain stem).

Regional cerebral blood flow in the rat as determined by particle distribution and by diffusible tracer

Measurements of total and regional cerebral blood flow in paralyzed rats maintained on 70% N2O/30% O2 obtained by a diffusible tracer technique, iodoantipyrine, and by a particle distribution method, microspheres, have been compared. Total CBF values were in good agreement, 0.86 +/- 0.07 ml/g/min (PaCO2 37.3 +/- 1.5, iodoantipyrine method) and 0.88 +/- 0.02 (PaCO2 36.2 +/- 0.8, microsphere method). Regional cerebral blood flows showed good agreement with the 2 methods, with highest flow in the colliculi, striatum and cerebral cortex and lowest flows in the hypothalamus, pons medulla and cerebellum. The iodoantipyrine method is technically easier to perform and had a higher precision.

Cerebral metabolic and circulatory changes in the rat during sustained seizures induced by DL-homocysteine

Sustained, generalized seizure activity was induced in anaesthetized (70% N2O), paralyzed and artifically ventilated rats by i.p. DL-homocysteine thiolactone in a dose of 11 mmol/kg. Epileptic discharges in the EEG were accompanied by marked perturbation of tissue metabolites. There was a fall in phosphocreatine concentration to 40% of control but only moderate changes in adenine nucleotides, a marked rise in lactate concentration, and a pronounced increase in the lactate/pyruvate ratio. Excessive amounts of dihydroxyacetone phosphate (and glyceraldehyde phosphate) accumulated, indicating that depletion of NAD+ occurred. There was marked accumulation of ammonia, glutamine and alanine, and reduction in glutamate and aspartate concentrations. Administration of a subconvulsive dose of homocysteine (7.5 mmol/kg) gave rise to changes in ammonia and amino acids, qualitatively similar to those occurring during seizures. It is concluded that although changes in the metabolites of the energy reserve were mainly caused by the induced seizures, those affecting amino acid concentrations were significantly influenced by accumulation of ammonia, secondary to metabolism of injected homocysteine. Cerebral blood flow (CBF) and oxygen utilization (CMRO2) were measured during sustained seizures. CMRO2 rose to 150% of control, with a corresponding increase in CBF.

Influence of chlormethiazole on cerebral blood flow and oxygen consumption in the rat, and its effect on the recovery of cortical energy metabolism after pronounced, incomplete ischaemia

The influence of an anaesthetic dose of chlormethiazole (Hemineurin) on blood flow (CBF) and oxygen consumption (CMRO2) in the rat brain was investigated. In spontaneously breathing animals a dose of 160 mg . kg-1 of chlormethiazole, infused i.v., induced a state close to surgical anaesthesia. In paralyzed animals, the same dose decreased CBF and CMRO2 to about 60% of control, an effect similar to that observed after an anaesthetic dose of phenobarbitone. Neither a protective nor a detrimental effect of chlormethiazole could be demonstrated when the drug was given during reversible and pronounced, incomplete ischaemia, as evaluated from the postischaemic tissue concentrations of labile phosphates (PCr, ATP, ADP, AMP) and of lactate and pyruvate. It is concluded that protection in this situation (as earlier shown with phenobarbitone) must, at least partly, be related to other mechanisms than a depression of metabolism.

Local versus regional cerebral blood flow in the rat at high (hypoxia) and low (phenobarbital anesthesia) flow rates

Local cerebral blood flow (CBF) was measured in rats, using an autoradiographic technique with 14C-iodoantipyrine as diffusible tracer, in situations with low, normal and high flow rates (phenobarbital anesthesia, analgesia with 75% N2O, and hypoxia, respectively). A comparison of the results with previous data obtained in conscious rats (Sakurada et al. 1978) demonstrates that 75% N2O moderately reduces local CBF in some, but not all, cortical and subcortical areas, that phenobarbital anesthesia reduces local CBF to between 30 and 65% of (conscious) control, and that pronounced hypoxia (arterial P02 about 25 mmHg) increases local CBF 3- to 4-fold. A comparison of the values obtained for cortical structures with those previously measured with a technique based on the Fick principle shows that the autoradiographic technique gives similar values at low and normal flow rates but that it moderately underestimates CBF at high flow rates, probably due to diffusion limitation.

Effects of bicuculline-induced seizures on cerebral metabolism and circulation of rats rendered hypoglycemic by starvation

To evaluate the effects of substrate deficiency on cerebral function, metabolism, and blood flow during seizures, rats were injected intravenously with bicuculline (1.2 mg.kg-1) following a 24-hour period of starvation. During the course of seizures, blood glucose concentrations fell, and when they were reduced to below about 3 mumol.gm-1, cerebral function, metabolism, and blood flow altered. Changes in function involved the transition of an electroencephalographic pattern of bursts and suppression into one of frequent or sparse single spikes. Oxygen consumption, which initially increased at least twofold, fell toward normal or subnormal values in the single-spike period. Cortical blood flow was markedly reduced, and there was an attenuated response to carbon dioxide administration. Simultaneously, a small but clear fall was detected in the cerebral phosphorylation potential, and concentrations of glycolytic metabolites (including lactate) and citric acid cycle intermediates were reduced. Changes in amino acids and ammonia were somewhat similar to those observed in insulin-induced hypoglycemia, but since the amino acid pool did not fall, the experiments failed to give evidence that amino acids serve as oxidative substrates. The perturbation of cerebral energy state (and of levels of carbohydrate substrates and amino acids) was reversed by glucose administration; but since neither this procedure nor additional bicuculline injections could cause resumption of continuous seizure activity, the results suggest that cellular substrate depletion may have given rise to a sustained disturbance of synaptic transmission.

Additive effects of hypothermia and phenobarbitol upon cerebral oxygen consumption in the rat

The quantitative effects of a combination of hypothermia and phenobarbital on cerebral oxygen uptake (CMRo2) was studied in rats, curarized and artificially ventilated with 70% nitrous oxide in oxygen. Cerebral blood flow (CBF) was measured with a modification of the KETY & SCHMIDT (1948) technique, using 133xenon as a tracer. Arteriovenous difference in oxygen content over the brain was measured and CMRo2 was calculated. Four groups were studied. Group 1 was a control group. The three experimental groups were injected with phenobarbital intraperitoneally: Group 2 with 50 mg/kg body weight; Group 3 with 150 mg/kg; and Group 4 with 50 mg/kg of phenobarbital, and, in addition, body temperature was lowered to 32 degrees C in this group. CMRo2 in groups 2, 3 and 4 was reduced by 22, 37 and 43%, respectively, compared to Group 1. The changes in CBF were of the same magnitude. In a previous study we have found that CMRo2 decreases by 5% per 1 degree C decrease in body temperature. The value for CMRo2 in Group 4 is close to the value obtained if the effect of 50 mg/kg body weight of phenobarbital on CMRo2 is added to the effect of a temperature reduction of 5 degrees C. It is concluded that the effects of barbiturates and hypothermia on CMRo2 are additive.

Influence of "lytic cocktail" on blood flow and oxygen consumption in the rat brain

The influence of a sedative dose of "lytic cocktail" (chlorpromazine, promethazine and pethidine) on cerebral blood flow (CBF) and oxygen consumjtion (CMRO2) was tested in artificially ventilated rats, maintained on either 70% N2 or 70% N2O. When given alone, the lytic cocktail had no significant effect on CBF or CMRO2. However, in the presence of nitrous oxide there was a 25% reduction in blood flow and oxygen consumption.

Influence of intravenously administered catecholamines on cerebral oxygen consumption and blood flow in the rat

In order to study effects of catecholamines on cerebral oxygen consumption (CMRo2) and blood flow (CBF), rats maintained on 75% N2O and 25% O2 were infused i.v. with noradrenaline (2, 5, or 8 microgram.kg-1.min-1) or adrenaline (2 or 8 microgram.kg-1.min-1) for 10 min before CBF and CMRo2 were measured. In about 50% of animals infused with 2--8 microgram.kg-1.min-1 of noradrenaline, CMRo2 (and CBF) rose. However, there was no dose-dependent response, and CMRo2 did not exceed 150% of control. The effects of noradrenaline in a dose of 5 microgram.kg-1.min-1 on CMRo2 and CBF were blocked by propranolol (2.5 mg.kg-1). In animals infused with adrenaline (8 microgram.kg-1.min-1) CMRo2 was doubled and, in many, CBF rose 4- to 6-fold. It is concluded that, when given in sufficient amounts, catecholamines have pronounced effects on cerebral metabolism and blood flow, the effects of adrenaline on CMRo2 and CBF resembling those observed in status epilepticus.

Coupling of cerebral metabolism and blood flow in epileptic seizures, hypoxia and hypoglycaemia

This study examines the possibility that changes of cerebral extracellular pH (PH e) or adenosine concentration may provide coupling mechanisms of a general nautre, adjusting cerebral blood flow (CBF) to metabolic demands. Although there is considerable indirect evidence that CBF varies inversely with pHe, results obtained during the last few years indicate that large increases in flow may occur in the absence of a fall in pHe. Thus, induction of hypoxia or epileptic seizures leads to maximal increase in CBF before pHe falls or even when there is initial alkalosis due to concomitant hypocapnia. Furthermore, CBF increases in hypoglycaemia and after administration of amphetamine, two conditions unassociated with tissue acidosis. The possibility that adenosine may be a coupling factor was examined in hypoxia and during epileptic seizures in rats. In both conditions a four- to fivefold increase in CBF occurs in spite of the fact that tissue adenosine concentrations remain at or below 1 mumolkg-u. It is concluded that adenosine accumulates first when there is a perturbation of cerebral energy state with a rise in AMP concentration. It seems unlikely that adenosine, formed by breakdown of AMP, acts as a general coupling factor.

Circulatory and metabolic effects in the brain induced by amphetamine sulphate

Cerebral circulatory and metabolic effects of amphetamine sulphate (0.25-25 mg.kg-1 i.v. or 5-10 mg.kg-1 i.p.) were studied in anesthetized, paralyzed and artifically ventilated rats. Cerebral blood flow (CBF) was measured with a modification of the Kety and Schmidt (1948) technique, and oxygen consumption (CMRO2) was calculated from CBF and arteriovenous differences in oxygen content. Regional CBF was evaluated from the uptake of 14C-ethanol. Cortical metabolites were analysed following freezing of tissue in situ. Amphetamine administration gave rise to a marked increase in CBF that was doubled following 0.25 mg.kg-1 and increased 4-fold following 15 mg.kg-1. However, such excessive increases in flow were confined to frontoparietal cortical regions, while other cortical or subcortical areas showed more moderate hyperemia. The increase in CBF was unrelated to changes in arterial PCO2, blood pressure, or tissue lactate content. CMRO2 increased by 30% to 95% depending on dose and rat strain used. At all doses employed, amphetamine gave rise to glycogenolysis in cerebral cortex but, in animals studied within the first 30 min after 5 mg.kg-1, or less, the only other changes were increases in glucose-6-phosphate and alpha-ketoglutarate concentrations. When the dose was increased to 15 mg.kg-1, there were moderate increased in lactate concentration and lactate/pyruvate ratio. Sixty min after 5 mg.kg-1 there were increases in tissue concentrations of pyruvate, citric acid cycle intermediates and alanine, as well.

Cerebral blood flow autoregulation in the rat

Cerebral blood flow autoregulation (CBFA) to changes in perfusion pressure has not been previously reported in the rat. A modification of the Kety and Schmidt technique employing 133Xenon was used to measure cerebral blood flow (CBF) in paralyzed adult Sprague Dawley rats passively ventilated with 70% nitrous oxide and 30% oxygen. At a mean arterial blood pressure (MABP) of 121 +/- 19 mm Hg, and a mean arterial PCO2 of 36.2 +/- 2.9 mm Hg, mean CBF was 103 +/- 22 ml/min/100 gm of brain. CBF responses to hypercarbia were 4.9 ml/min/100 gm per mm Hg change in arterial PCO2. CBF was measured during steady state levels of hypo- and hypertension induced by phlebotomy, or by intravenous metaraminol, over the MABP range of 48-205 mm Hg. From a MABP of 80 to 160 mm Hg. CBF remained nearly constant, indicating the presence of CBFA. However, when MABP exceeded 160 mm Hg, CBF became pressure dependent, indicating a "breakthrough" of autoregulation in acute severe hypertension.

Reduction of cerebral blood flow and oxygen consumption with a combination of barbiturate anaesthesia and induced hypothermia in the rat

The influence of phenobarbitone anaesthesia on cerebral blood flow (CBF) and cerebral metabolic rate for oxygen (CMRo2) during hypothermia (23 degrees C & 27 degrees C) was studied in the rat, using a modification of the Kety & Schmidt (1948) technique and arterio-venous differences for oxygen. Phenobarbitone (150 mg/kg) was found to decrease CMRo2 by 40-60% during hypothermia, when compared to N2O anaesthesia. At a body temperature of 23 degrees C, and during phenobarbitone anaesthesia, CMRo2 was reduced to about 15% of normal control value (about 10.3 ml.100g-1). CBF was reduced to about 50% of the phenobarbitone control value but was similar to the value obtained with N2O anaesthesia at 22 degrees C. It is concluded that the combination of phenobarbitone anaesthesia and hypothermia results in a more pronounced reduction in cerebral metablic rate for oxygen than can be achieved by administration of barbiturates to normothermic animals, or by reducing body temperature by 15 degrees C during superficial anaesthesia.

Regional brain blood flow in the conscious gerbil

Regional brain blood flow was determined in 23 awake, unparalyzed gerbils with a simplified indicator-fractionation technique. The use of intravenous 14C-butanol, an indicator that is freely diffusible into the brain, eliminated the need for repetitive sampling of arterial and cerebral venous blood and reduced the period of indicator circulation of 10 seconds. Gerbils spontaneously breathing room air (PaCO2 = 32 +/- 1 (SE) mm Hg) had blood flows in whole cerebrum, cerebellum, and brainstem of 102 +/- 4, 93 +/- 5, and 114 +/- 6 ml/100 gm/min respectively. Cerebral blood flow increased linearly with elevations in PaCO2 (r=0.969) and averaged 3.14 +/- 0.17 ml/100gm/min per mm Hg increase in PaCO2. Interpolated cerebral blood flow at a PaCO2 of 40 mm Hg was 127 +/- 2 ml/100 gm/min. This technique is easy and convenient to use, involves no intracranial surgery, requires steady state conditions for only 10 seconds, and minimizes blood loss in small animals. In more discrete brain regions a less volatile indicator is needed.

Postischemic cerebral blood flow and oxygen utilization rate in rats anesthetized with nitrous oxide or phenobarbital

The present experiments were undertaken to measure postischemic regional cerebral blood flow (rCBF) and oxygen utilization rate (CMRo2) in rats anesthetized with either 70% N2O or phenobarbital (150 mg x kg-1). In previous studies we have found that extensive restitution of cerbral energy metabolites occurs after 30 min of complete cerebral ischemia irrespective of the type of anesthesia used. Following 30 min of pronounced, incomplete ischemia, however, a comparable restitution of cerebral energy state was obtained in deeply anesthetized (phenobarbital 150 mg x kg-1) but not in superfically anesthetized (70% N2O) rats. The objectives of the present investigation were (1) to study whether postischemic cerebral blood flow was higher in barbiturate-anesthetized animals during the initial recirculation period, and (2) to investigate if the protective effects of phenobarbital previously observed could be attributed to a decrease in CMRo2. In both groups of animals a considerable variability in postischemic rCBF was observed between different animals. However, no signs of gross inhomogeneity in blood flow were found and no consistent differences in flow values between the two groups of animals were observed. Since the measured postischemic CMRo2 were identical in both groups of animals and since cerebral venous oxygen contents were above normal the results leave little support to the assumption that, in the present model of transient, incomplete cerebral ischemia, failure of recovery of cerebral metabolism (N2O group) is primarily due to impaired recirculation, nor do they indicate that the protective effects of barbiturates is due to their ability to reduce rate of cerebral energy utilization.