Sphenopalatine ganglion stimulation increases regional cerebral blood flow independent of glucose utilization in the cat

Regional cerebral blood flow was determined using the tracer [14C]iodoantipyrine and regional brain dissection, and regional cerebral glucose utilization determined using the 2-deoxyglucose method, in the alpha-chloralose-anesthetized cat to evaluate the effect of electrical stimulation of the sphenopalatine (pterygopalatine) ganglion. Unilateral stimulation for either a short period (7-10 min) or a longer period (45 min) resulted in increases in blood flow in the ipsilateral cerebral cortex of up to 45% (parietal cortex) with, in addition, increased flow in the white matter of the corpus callosum (42%). The flow changes for both brief and prolonged stimulation were not significantly different. Flow was not altered in either the brainstem or basal ganglia (caudate nucleus). In contrast to these changes in cerebral blood flow no changes in cerebral glucose utilization were seen in any of the brain areas studied and in particular there were no changes in the areas in which blood flow increased. These data provide clear evidence that the innervation of the cerebral vasculature from the main parasympathetic ganglion can alter cerebral blood flow independent of cerebral metabolism.

Circadian variations in local cerebral glucose utilization in freely moving rats

Sokoloff's [14C]2-deoxyglucose method has been applied to investigate circadian variations in local cerebral glucose utilization (LCGU). Freely moving rats were tested during two phases of the circadian light/dark cycle. In the rats tested during darkness, elevations in LCGU, when compared with animals tested during the light period, were observed in the primary and secondary visual cortex, the primary auditory cortex, the lateral geniculate nucleus, the amygdala, the entorhinal cortex, the hippocampus, the substantia nigra and the cerebellum. A reduction in LCGU was observed in the suprachiasmatic nucleus.

High metabolic activity in the dorsal vagal complex of Brattleboro rats

Receptor densities for angiotensin II and atriopeptin are particularly high in the dorsal vagal complex (DVC) of the caudal medulla oblongata. Measurements of glucose metabolism in individual components of the DVC, compared with those in Long-Evans rats, revealed that the area postrema was activated selectively both in water-sated and water-deprived Brattleboro rats, which have high circulating levels of angiotensin II. Other parts of the DVC, including subnuclei of the nucleus of the solitary tract and the dorsal motor nucleus of the vagus nerve, as well as brainstem structures within efferent trajectories of the DVC, had elevated rates of glucose metabolism in Brattleboro rats deprived of water overnight and in Sprague-Dawley rats dehydrated for 120 h. The findings are consistent with neural activation by angiotensin II, as either a hormone or neurotransmitter, within subregions of the dorsal medulla oblongata having high densities of putative receptors and immunoreactive perikarya and fibers containing both angiotensin II and atriopeptin.

Isolation of mutant renal (LLC-PK1) epithelia defective in basolateral, Na(+)-independent glucose transport

To obtain mutant renal epithelia defective in the uptake of 2-deoxyglucose (Na(+)-independent glucose transport), LLC-PK1 renal epithelial cells were subjected to a combination of DNA alkylation, tritium-suicide with 2-[3H]deoxyglucose, and replica plating. One of the mutant sublines obtained, LLC-PK1M-7A, possesses only 40% of the 2-deoxyglucose uptake rate of the parent line, LLC-PK1M, and this defect is stable over at least 30 population doublings. Initial rate of 3-O-methylglucose transport into these mutant cells is only 20% of the parental rate, and efflux of 3-O-methylglucose from the mutant cells is correspondingly low. Glucose metabolism in the mutant cells does not appear to be altered, nor is free glucose accumulated in the cells against a concentration gradient. The uptake rate of L-leucine is the same in both mutant and parent, whereas the (Na(+)-dependent) uptake of alpha-methyl-D-glucoside and methylaminoisobutyric acid is greater in the mutant than the parent. The population doubling times of LLC-PK1M and LLC-PK1M-7A cultures are similar. LLC-PK1M-7A cell morphology is similar to LLC-PK1M when cultures are subconfluent, but on reaching confluence, LLC-PK1M-7A appear larger than LLC-PK1M cells. Their measured cell volume is then 150% of the volume of the parent cells. Future studies of the LLC-PK1M-7A mutant, and acquisition of additional mutant sublines, should elucidate the roles of transepithelial glucose transport in proximal tubular cell physiology.

Sequential metabolic changes in rat brain following middle cerebral artery occlusion: a 2-deoxyglucose study

The distribution and time course of altered cerebral metabolism following permanent focal ischemia was studied in rat using the 2-deoxyglucose (2DG) technique. Increased 2DG uptake preceded decreased 2DG uptake and infarction in the caudate putamen and cortex. Decreased 2DG uptake without infarction was observed for 72 h in thalamus and for 24 h in hippocampus (areas remote from the ischemic zones). This study supports the concept of cell excitation as a pathophysiologic process in permanent focal ischemia. The time course of increased metabolism may demarcate the time window of opportunity for the previously demonstrated attenuation of stroke size with inhibition of cell excitation by pharmacologic blockade of excitatory amino acid neurotransmission.

Effects of MK-801 upon local cerebral glucose utilisation in conscious rats and in rats anaesthetised with halothane

The effects of MK-801 (0.5 mg/kg i.v.), a non-competitive N-methyl-D-aspartate (NMDA) antagonist, upon local cerebral glucose utilisation were examined in conscious, lightly restrained rats and in rats anaesthetised with halothane in nitrous oxide by means of the quantitative autoradiographic [14C]-2-deoxyglucose technique. In the conscious rats, MK-801 produced a heterogenous pattern of altered cerebral glucose utilisation with significant increases being observed in 12 of the 28 regions of gray matter examined and significant decreases in 6 of the 28 regions. Pronounced increases in glucose use were observed after MK-801 in the olfactory areas and in a number of brain areas in the limbic system (e.g., hippocampus molecular layer, dentate gyrus, subicular complex, posterior cingulate cortex, and mammillary body). In the cerebral cortices, large reductions in glucose use were observed after administration of MK-801, whereas in the extrapyramidal and sensory-motor areas, glucose use remained unchanged after MK-801 administration in conscious rats. In the halothane-anaesthetised rats, the pattern of altered glucose use after MK-801 differed qualitatively and quantitatively from that observed in conscious rats. In anaesthetised rats, significant reductions in glucose use were noted after MK-801 in 10 of the 28 regions examined, with no area displaying significantly increased glucose use after administration of the drug. In halothane-anaesthetised rats, MK-801 failed to change the rates of glucose use in the olfactory areas, the hippocampus molecular layer, and the dentate gyrus.(ABSTRACT TRUNCATED AT 250 WORDS)

Glycolysis-induced discordance between glucose metabolic rates measured with radiolabeled fluorodeoxyglucose and glucose

We have developed an autoradiographic method for estimating the oxidative and glycolytic components of local CMRglc (LCMRglc), using sequentially administered [18F]fluorodeoxyglucose (FDG) and [14C]-6-glucose (GLC). FDG-6-phosphate accumulation is proportional to the rate of glucose phosphorylation, which occurs before the divergence of glycolytic (GMg) and oxidative (GMo) glucose metabolism and is therefore related to total cerebral glucose metabolism GMt: GMg + GMo = GMt. With oxidative metabolism, the 14C label of GLC is temporarily retained in Krebs cycle-related substrate pools. We hypothesize that with glycolytic metabolism, however, a significant fraction of the 14C label is lost from the brain via lactate production and efflux from the brain. Thus, cerebral GLC metabolite concentration may be more closely related to GMo than to GMt. If true, the glycolytic metabolic rate will be related to the difference between FDG- and GLC-derived LCMRglc. Thus far, we have studied normal awake rats, rats with limbic activation induced by kainic acid (KA), and rats visually stimulated with 16-Hz flashes. In KA-treated rats, significant discordance between FDG and GLC accumulation, which we attribute to glycolysis, occurred only in activated limbic structures. In visually stimulated rats, significant discordance occurred only in the optic tectum.

Role of guanine nucleotide regulatory proteins in insulin stimulation of glucose transport in rat adipocytes. Influence of bacterial toxins

The potential role of guanine nucleotide regulatory proteins (G-proteins) in acute insulin regulation of glucose transport was investigated by using bacterial toxins which are known to modify these proteins. Cholera-toxin treatment of isolated rat adipocytes had no effect on either 2-deoxyglucose transport or insulin binding. Pertussis-toxin treatment resulted in an inhibition of both insulin binding and glucose transport. Insulin binding was decreased in pertussis-toxin-treated cells by up to 40%, owing to a lowering of the affinity of the receptor for hormone, with no change in hormone internalization. The dose-response curve for insulin stimulation of glucose transport was strongly shifted to the right by pertussis-toxin treatment [EC50 (half-maximally effective insulin concn.) = 0.31 +/- 0.04 ng/ml in control cells; 2.29 +/- 1.0 in treated cells), whereas cholera toxin had only a small effect (EC50 = 0.47 +/- 0.02 ng/ml). Correcting for the change in hormone binding, pertussis toxin was found to decrease the coupling efficiency of occupied receptors (50% of maximal insulin effect with 928 molecules bound/cell in control and 3418 in treated cells). Pertussis-toxin inhibition of insulin sensitivity was slow in onset, requiring 2-3 h for completion. Under conditions where pertussis-toxin inhibition of insulin sensitivity was maximal, a 41,000 Da protein similar to the alpha subunit of Gi (the inhibitory G-protein) was found to be fully ribosylated. These results are consistent with the concept that pertussis-toxin-sensitive G-protein(s) can modify the insulin-receptor/glucose-transport coupling system.

Evidence for common alterations in cerebral glucose metabolism in major affective disorders and schizophrenia

Regional glucose metabolic rates were measured in affectively disordered patients during the performance of auditory discrimination. Those regions previously observed as abnormal in schizophrenia were examined to see if similar alterations might be associated with affective disorder. The abnormalities observed in the mid-prefrontal cortex, an area that appears to be an important biologic determinant of the sustained attention required of subjects in this task, are similar to those previously observed in schizophrenia. Moreover, the abnormalities do not appear to relate directly to symptomatology or the subject's performance. The authors discuss the possibility that this abnormality may reflect dysfunction in the integrating component of the attention network critical for the maintenance of goal-directed behavior and thus represent a psychosis vulnerability factor in some patients.

The acquisition of increased insulin-responsive hexose transport in 3T3-L1 adipocytes correlates with expression of a novel transporter gene

The expression of two genes encoding facilitated glucose transporter proteins was studied during the differentiation of the 3T3-L1 fibroblastic cell line into adipocytes. The mRNA encoding the widely expressed HepG2/brain glucose transporter (GTI) is detectable in fibroblasts and its abundance remains unchanged during differentiation. On the other hand, the mRNA encoding a glucose transporter protein (GTIII) localized exclusively to muscle and adipose tissue is undetectable in fibroblasts but present in adipocytes. GTIII mRNA is first expressed three days after differentiation of 3T3-L1 cells has begun. Similarly, it is not until 3 days following the initiation of differentiation that GTIII protein can be detected, as assayed either by Western immunoblot or indirect immunofluorescence. The latter technique localizes GTIII predominantly to the perinuclear region of the adipocyte. The appearance of GTIII in developing fat cells correlates temporally with the acquisition of an increased stimulation of hexose uptake by maximal concentrations of insulin. These data support the concept that the marked increase in hexose transport in adipocytes in response to insulin is dependent on the expression in these cells of a specific, hormone-regulatable transport protein.

Mechanism of insulin resistance induced by sustained levels of cytosolic free calcium in rat adipocytes

We have recently provided evidence that elevated levels of cytosolic free Ca2+ ([Ca2+]i) decreased insulin-stimulated glucose uptake in isolated rat adipocytes. To investigate the mechanism of Ca2+ action, we examined the effects of elevated levels of [Ca2+]i on insulin binding, autophosphorylation, and tyrosine kinase activity (TKA) of insulin receptors as well as basal and insulin-stimulated cellular distribution of glucose transporters. The latter was assessed by cytochalasin-B binding to plasma membrane and cytosolic fractions. Elevated concentrations of [Ca2+]i were maintained by incubating adipocytes with a depolarizing concentration of K+ (40 mM). Basal nonstimulated glucose uptake was not altered by increased levels of [Ca2+]i. Adipocytes with higher [Ca2+]i (220 +/- 15 nM) showed 30% reduction in insulin-stimulated 2-deoxyglucose uptake compared with control cells ([Ca2+]i, 140 +/- 18 nM). Moreover, adipocytes with higher levels of [Ca2+]i demonstrated an approximately 10% reduction in autophosphorylation and TKA of insulin receptors without a change in insulin binding. Both basal and insulin-stimulated distributions of glucose transporters were unaffected by sustained levels of [Ca2+]i. The effects of elevated [Ca2+]i were not mimicked by protein kinase-C activation. These observations suggest that 1) elevated or sustained levels of [Ca2+]i impair insulin-stimulated glucose uptake; and 2) Ca2+-induced impairment appears to reside at the postbinding steps of insulin action and probably interferes with the TKA of insulin receptors and the intrinsic activity of glucose transporters.

Regional cerebral glucose metabolism differs in adult and rigid juvenile forms of Huntington disease

A 7-year-old girl with the juvenile form of Huntington disease is described. She had personality changes, speech and gait disturbances, diffuse rigidity, dementia, and a well-documented family history of Huntington disease. Electroencephalography revealed bilateral epileptic foci; however, she had no seizures. Positron emission tomography using [18F]-2-fluoro-2-deoxy-D-glucose with an improved method for quantification of glucose metabolism in anatomically defined regions of interest demonstrated marked hypometabolism in the caudate nuclei and putamen, as is observed in adults with the disease. Glucose metabolism was also reduced in the posterior nuclei of the thalamus. Adults with Huntington disease have consistently demonstrated normal or increased rates of thalamic glucose metabolism. The findings suggest that brain metabolic alterations of Huntington disease in children differ from those in adults which is consistent with the postmortem pathologic differences previously recognized.

Simultaneous in vivo monitoring of cerebral deoxyglucose and deoxyglucose-6-phosphate by 13C[1H] nuclear magnetic resonances spectroscopy

The capacity of brain to dephosphorylate glucose-6-phosphate has been established, but the magnitude and significance of this capacity in vivo are debated, particularly in regard to dephosphorylation of the glucose analog 2-deoxyglucose. We now report results of external measurement in the brains of conscious rats with simultaneous resolution and quantification of both 2-deoxyglucose and its phosphorylated product by nuclear magnetic resonance (NMR) techniques that used 2-[6-13]deoxyglucose together with proton-decoupled 13C surface-coil spectroscopy. As NMR techniques require large doses of 2-deoxyglucose, a dose comparison was first made using decay curves of total label after tracer doses of 2-[14C]deoxyglucose without versus with unlabeled deoxyglucose at 500 mg/kg (the NMR dose). Similar cerebral half-lives for the two doses were found, and no behavioral evidence for toxicity of the NMR dose was seen. In vivo NMR monitoring of conscious rats showed that the analog reached maximal cerebral concentration within 10 min of the intravenous bolus and decayed with a half-life of 29 +/- 7 min (n = 4; mean +/- SEM), whereas 2-deoxyglucose-6-phosphate reached peak concentration between 30 and 40 min and decayed with a half-life of 2.1 +/- 0.3 h, equivalent to a fractional loss of 0.8%/min. Thirty-one percent (+/- 5%) of the total analog pool (which showed a half-life of 1.4 h) consisted of 2-deoxyglucose at 45 min after the bolus. The results support an active but limited role for dephosphorylation by normal brain in glucose analog (and potentially glucose) metabolism in the unstimulated conscious rat and a wide concentration range for the metabolic operations involved.

Early effects of intra-arterial chemotherapy in patients with brain tumours studied with PET: preliminary results

In ten patients with malignant gliomas the regional cerebral metabolic rate for glucose (rCMRGlc) was studied with positron emission tomography (PET) using 2-18F-deoxyglucose (18FDG) before and within 1 to 7 days after intra-arterial chemotherapy with the nitrosourea derivative ACNU (iaACNU). Three patients were studied before and after two iaACNU courses and one patients before and after three iaACNU courses. The early effects of iaACNU on tumour rCMRGlc were highly variable and appeared to be more pronounced after the first course of iaACNU than in later iaACNU courses, i.e. more pronounced in untreated patients. Although there was no clear correlation between the change of rCMRGlc following the first course of iaACNU and the clinical outcome in this small group of patients, the patient with the most pronounced decrease of tumour metabolism (-16.5%) after the first course of iaACNU exhibited full tumour remission for 12 months, while the patient with the most pronounced increase of tumour metabolism (+65%) after the first course of iaACNU developed rapid tumour progression. The first results indicate that early effects of intra-arterial chemotherapy may be observed with 18FDG PET, especially following the first course of iACNU. Further studies are needed to evaluate the predictive value of such studies for therapy response.

Spreading depression following experimental head injury in the rat

The direct current (DC) potential and electroencephalographic (EEG) changes were continuously monitored following fluid percussion head injury (brain contusion) in 10 conscious rats. Local cerebral glucose utilization (LCGU) was measured by the autoradiographic [14C]deoxyglucose method. Measurement of LCGU was started at the lowest point of the first or second DC potential negative shift when it occurred, and 2 hours after contusion if no DC potential changes were observed. The DC potential did not change in four rats (Group A), whereas DC potential negative shifts together with marked suppression of EEG activity occurred at 54 +/- 6.9 minutes after injury in six rats (Group B). In Group A, LCGU was decreased nonsignificantly in both the right and left cortices. In Group B, however, LCGU in the lesioned cortex rose to 160-190% of the level observed in the contralateral cortex (p less than 0.05). The autoradiographic pattern in Group B was identical to that seen in spreading depression. These findings can contribute to the effort to better understand the pathophysiology of head injury.

Antagonism by growth hormone of insulin-sensitive hexose transport in 3T3-F442A adipocytes

We have studied the effects of GH on basal and insulin-stimulated hexose transport by 3T3-F442A adipocytes in a hormonally defined serum-free medium. Adipocytes preincubated in defined medium exhibit a low level of hexose transport which is acutely (15 min) stimulated (greater than 5-fold) by insulin (EC50, 0.1-0.2 nM). GH has acute (15-45 min) insulin-mimetic (greater than 2-fold) and chronic (4-48 h) diabetogenic (50-80%) effects on basal and insulin-stimulated hexose transport. The insulin-mimetic effect of GH has a higher EC50 (2 nM) than its diabetogenic effect (EC50, 0.2 nM). Chronic GH exposure decreases the maximal responsiveness (50-80%) and the acute sensitivity (approximately 2-fold) of hexose transport to insulin. Insulin-stimulated transport is more (approximately 5-fold) sensitive to the diabetogenic effect of GH than is basal transport. Insulin binding and degradation were not altered by chronic exposure to GH. The diabetogenic effect of GH may occur at a postinsulin binding level.

Global reduction in cerebral blood flow and metabolism elicited from intrinsic neurons of fastigial nucleus

We sought to determine whether the global increase in regional cerebral blood flow (rCBF) produced by electrical stimulation of the rostral cerebellar fastigial nucleus (FN) is a consequence of excitation of intrinsic neurons of the FN or of axons of fibers passing through or projecting into it. Studies were conducted in rats anesthetized with chloralose, paralyzed and ventilated. rCBF was measured with [14C]iodoantipyrine as tracer and regional cerebral glucose utilization (rCGU) by [14C]2-deoxyglucose in homogenates of 11 brain regions. Neuronal perikarya in FN were excited chemically by local microinjection of the glutamate analogue kainic acid (KA) (5 nmol in 100 nl). KA elicited a transient and significant fall of arterial pressure and heart rate, the fastigial depressor response (FDR). Associated was a significant and symmetrical reduction in rCBF, to 44% of control in all regions except medulla. The response was site- and agent-specific and unrelated to the hypotension. KA also significantly and proportionally reduced, to 52% of control, rCGU in the same 10 areas of brain. In all regions the magnitudes of the reductions in rCBF and rCGU elicited by KA were linearly related. Intrinsic neurons of FN were chronically destroyed by local microinjection of the excitotoxin ibotenic acid (IBO) (10 micrograms/microliters in 0.4 microliter). Destruction of intrinsic FN neurons had no effect on resting rCBF nor on the global cerebrovascular vasodilation elicited by electrical stimulation of the FN. We conclude that: (a) excitation of intrinsic neurons of FN elicits a widespread reduction of cerebral metabolism and, secondarily, blood flow; (b) FN neurons do not exert a long-term tonic influence on brain blood flow nor metabolism; (c) the global increase in rCBF elicited by electrical stimulation of the FN is a consequence of excitation of axons projecting into or through the nucleus.

Odor-induced metabolic activity in the olfactory bulb of rats trained to detect propionic acid vapor

The pattern of glucose metabolism in the glomerular layer of the main olfactory bulb was studied in rats trained to sample brief odor stimuli. After injection with [14C]2-deoxyglucose (2-DG). 5 rats were tested for discrimination of propionic acid from air. Over the 45 min test period rats sampled the stimulus for 0.5-0.8s during each trial and their total exposure to the stimulus was 53-147 s. A discrete focus of increased glucose metabolism was found in the central dorsomedial sector of the glomerular layer in each animal. The position of this focus and the overall pattern of glomerular layer activity was essentially identical to that obtained in 4 control rats which were exposed passively to alternating 5 min periods of the odor and clean air for 45 min. The size of the primary focus was only slightly smaller in the trained rats, despite the large difference in total exposure time. The absence of olfactory adaptation during the behavioral tests and the similar pattern of 2-DG uptake in controls and trained animals indicate that adaptation does not play a significant role in the patterns of glucose metabolism induced in the glomeruli of the olfactory bulb by extended exposure to an odor.

Adaptation of the quantitative 2-[14C]deoxyglucose method for use in freely moving rats

A procedure for venous and arterial catheterization is described which allows the quantitative 2-[14C]deoxyglucose method to be applied to freely moving animals for behavioral and pharmacological studies. The catheterization method is rapid, minimally invasive, and requires no complicated equipment. Physiological conditions and rates of cerebral glucose utilization in freely moving rats and in restrained rats have been compared. The results demonstrate that local cerebral glucose utilization can readily be measured in freely moving animals engaged in behavioral experiments.

Computer-assisted three-dimensional reconstructions of [14C]-2-deoxy-D-glucose metabolism in cat lumbosacral spinal cord following cutaneous stimulation of the hindfoot

We report on computer-assisted three-dimensional reconstruction of spinal cord activity associated with stimulation of the plantar cushion (PC) as revealed by [14C]-2-deoxy-D-glucose (2-DG) serial autoradiographs. Moderate PC stimulation in cats elicits a reflex phasic plantar flexion of the toes. Four cats were chronically spinalized at about T6 under barbiturate anesthesia. Four to 11 days later, the cats were injected (i.v.) with 2-DG (100 microCi/kg) and the PC was electrically stimulated with needle electrodes at 2-5 times threshold for eliciting a reflex. Following stimulation, the spinal cord was processed for autoradiography. Subsequently, autoradiographs, representing approximately 8-18 mm from spinal segments L6-S1, were digitized for computer analysis and 3-D reconstruction. Several strategies of analysis were employed: 1) Three-dimensional volume images were color-coded to represent different levels of functional activity. 2) On the reconstructed volumes, "virtual" sections were made in the horizontal, sagittal, and transverse planes to view regions of 2-DG activity. 3) In addition, we were able to sample different regions within the grey and white matter semi-quantitatively (i.e., pixel intensity) from section to section to reveal differences between ipsi- and contralateral activity, as well as possible variation between sections. These analyses revealed 2-DG activity associated with moderate PC stimulation, not only in the ipsilateral dorsal horn as we had previously demonstrated, but also in both the ipsilateral and contralateral ventral horns, as well as in the intermediate grey matter. The use of novel computer analysis techniques--combined with an unanesthetized preparation--enabled us to demonstrate that the increased metabolic activity in the lumbosacral spinal cord associated with PC stimulation was much more extensive than had heretofore been observed.

Rabbit hindlimb glucose uptake assessed with positron-emitting fluorodeoxyglucose

The feasibility of estimating skeletal muscle glucose uptake in vivo was examined by using the glucose analogue 2-[18F]deoxy-2-fluoro-D-glucose (2-[18F]FDG) in the rabbit hindlimb. A pair of collimated coincidence gamma photon detectors was used to monitor the accumulation of tracer in the tissue after 2-[18F]FDG injection. Time-activity curves were generated on a second-by-second basis under control conditions, during increased contractile activity, or hyperinsulinemia. The arterial input of 2-[18F]FDG, plasma glucose, lactate, free fatty acids, and insulin were determined. A graphical (Patlak plot) procedure was used to determine the fractional rate of tracer phosphorylation and therefore trapping in the muscle. From the graphical analysis, the estimated rate of glucose phosphorylation (R) in the unperturbed state was calculated to be 0.037 mumol.min-1.ml-1 of tissue. During perturbation by electrical stimulation, an increase in the rate of tracer phosphorylation (K) was observed. No change in the rate of tracer phosphorylation was observed during hyperinsulinemia. The results support the use of 2-[18F]FDG and the graphical procedure for the noninvasive assessment of glucose uptake by skeletal muscle in vivo. The method described is sensitive to changes in the rate of tracer uptake with respect to time and physiological interventions.

Stimulation of glucose transport by insulin and norepinephrine in isolated rat brown adipocytes

The effects of insulin and norepinephrine on glucose transport, glucose uptake, and cell respiration were investigated in isolated rat brown adipocytes. Glucose transport and uptake were determined using [U-14C]-D-glucose and 2-deoxy-[1,2-3H]-D-glucose, respectively. Brown adipocyte respiration was measured polarographically. Dose-response experiments revealed that insulin stimulated D-glucose transport and 2-deoxyglucose uptake between 10(-11) and 10(-7) M with a maximal four- to sixfold stimulation. In the absence of insulin, norepinephrine concentrations ranging from 10(-7) to 10(-7) M also enhanced glucose transport and uptake with a maximal two- to fourfold stimulation. Experiments with alpha- and beta-adrenergic agonists and antagonists showed that the effect of norepinephrine was predominantly mediated via beta-adrenergic pathways. Dibutyryl cyclic AMP and 3-isobutyl-1-methylxanthine also increased glucose transport, suggesting that the effects of norepinephrine are cyclic AMP dependent. Moreover, norepinephrine (10(-8) M) enhanced insulin sensitivity for glucose transport [half-maximum velocity constant (1/2 V max)] but failed to potentiate insulin responsiveness (Vmax). On the other hand, insulin (10(-9) M) had no effect on basal respiration but rapidly inhibited the calorigenic effect of norepinephrine (10(-7) M) by greater than 50%. These results demonstrate that 1) in the absence of insulin, physiological concentrations of norepinephrine stimulate glucose transport via beta-adrenergic pathways, 2) the neurohormone synergistically potentiates brown adipocyte submaximal insulin responses for glucose transport, and 3) insulin counteracts the effects of norepinephrine on brown adipocyte thermogenesis despite the fact that both hormones enhance glucose uptake.

Cerebrospinal fluid ionic regulation, cerebral blood flow, and glucose use during chronic metabolic alkalosis

Chronic metabolic alkalosis was induced in rats by combining a low K+ diet with a 0.2 M NaHCO3 solution as drinking fluid for either 15 or 27 days. Local cerebral blood flow and local cerebral glucose utilization were measured in 31 different structures of the brain in conscious animals by means of the iodo-[14C]antipyrine and 2-[14C]deoxy-D-glucose method. The treatment induced moderate [15 days, base excess (BE) 16 mM] to severe (27 days, BE 25 mM) hypochloremic metabolic alkalosis and K+ depletion. During moderate metabolic alkalosis no change in cerebral glucose utilization and blood flow was detectable in most brain structures when compared with controls. Cerebrospinal fluid (CSF) K+ and H+ concentrations were significantly decreased. During severe hypochloremic alkalosis, cerebral blood flow was decreased by 19% and cerebral glucose utilization by 24% when compared with the control values. The decrease in cerebral blood flow during severe metabolic alkalosis is attributed mainly to the decreased cerebral metabolism and to a lesser extent to a further decrease of the CSF H+ concentration. CSF K+ concentration was not further decreased. The results show an unaltered cerebral blood flow and glucose utilization together with a decrease in CSF H+ and K+ concentrations at moderate metabolic alkalosis and a decrease in cerebral blood flow and glucose utilization together with a further decreased CSF H+ concentration at severe metabolic alkalosis.

Relationship between local brain glucose metabolism and maze patrolling in adult and aged rats

Rats in the tunnel maze are not rewarded or punished. The active information gathering of the rats in this apparatus is supposed to be guided by learning and memory processes. As assessed by the 2-deoxyglucose method the age-related behavioral changes in rats in this maze are partly reflected in functional-metabolic changes in cortical and hippocampal structures.