Brain Metabolism and Intracellular pH During Ischaemia: Effects of Systemic Glucose and Bicarbonate Administration Studied by 31P and 1H Nuclear Magnetic Resonance Spectroscopy In Vivo in the Lamb

Brain metabolism and intracellular pH were studied during and after episodes of incomplete cerebral ischaemia in lambs under sodium pentobarbitone anaesthesia. 31P and 1H magnetic resonance spectroscopy was used to monitor brain pHi and brain concentrations of inorganic phosphate (Pi), phosphocreatine (PCr), beta-nucleoside triphosphate (beta NTP), and lactate. Simultaneous measurements were made of arterio-cerebral venous concentration differences (AVDs) for oxygen, glucose, and lactate. Cerebral ischaemia was induced by a combination of bilateral carotid clamping and hypotension, and the acute effects of systemic administration of glucose and sodium bicarbonate were examined. The molar ratio of glucose to oxygen uptake by the brain (6G/O2) increased above unity during cerebral ischaemia. Statistically significant AVDs for lactate were not observed. Cerebral ischaemia was associated with a reduction in brain pHi PCr/Pi ratio, and an increase in brain lactate. No effect of arterial plasma glucose on brain lactate concentration or brain pHi was evident during cerebral ischaemia or in the postischaemic period. Administration of sodium bicarbonate systemically in the postischaemic period was associated with a rise in arterial and brain tissue PCO2. A fall in brain pHi occurred which was attributable in part to coincidental brain lactate accumulation. The increase in brain lactate measured by 1H nuclear magnetic resonance in vivo during ischaemia was insufficient to account for the change in buffer base calculated to have occurred from previous estimates of brain buffering capacity.     

Brain Metabolism and Intracellular pH During Ischaemia and Hypoxia: An In Vivo 31P and 1H Nuclear Magnetic Resonance Study in the Lamb

Brain metabolism and intracellular pH were studied during and after episodes of ischaemia and hypoxia-ischaemia in lambs anaesthetised with sodium pentobarbitone. 31P and 1H magnetic resonance spectroscopy methods were used to monitor brain pHi and brain concentrations of Pi, phosphocreatine (PCr), beta--nucleoside triphosphate (beta NTP), and lactate. Simultaneous measurements were made of cerebral blood flow and cerebral oxygen and glucose consumption. Cerebral ischaemia sufficient to reduce oxygen delivery to 75% of control values was associated with a fall in brain pHi and increase in brain Pi. Progressively severe hypoxia-ischaemia was associated with a progressive fall in brain pHi, PCr, and beta NTP and increase in brain Pi. In two animals the increase in brain lactate during hypoxia-ischaemia measured by 1H nuclear magnetic resonance (NMR) could be quantitatively accounted for by the increased net uptake of glucose by the brain in relation to oxygen, but was insufficient to account for the concomitant acidosis according to previous estimates of brain buffering capacity. In four animals brain pHi, PCr, Pi, and beta NTP had returned to normal 1 h after the hypoxic-ischaemic episode. In one animal brain pHi had reverted to normal at a time when 1H NMR indicated persistent elevation of brain lactate.     

Effect of Hypoglycemic Encephalopathy upon Amino Acids, High-Energy Phosphates, and pHi in the Rat Brain In Vivo: Detection by Sequential 1H and 31P NMR Spectroscopy

Metabolic alterations in amino acids, high-energy phosphates, and intracellular pH during and after insulin hypoglycemia in the rat brain was studied in vivo by 1H and 31P nuclear magnetic resonance (NMR) spectroscopy. Sequential accumulations of 1H and 31P spectra were obtained from a double-tuned surface coil positioned over the exposed skull of a rat while the electroencephalogram was recorded continuously. The transition to EEG silence was accompanied by rapid declines in phosphocreatine, nucleoside triphosphate, and an increase in inorganic orthophosphate in 31P spectra. In 1H spectra acquired during the same time interval, the resonances of glutamate and glutamine decreased in intensity while a progressive increase in aspartate was observed. Following glucose administration, glutamate and aspartate returned to control levels (recovery half-time, 8 min); recovery of glutamine was incomplete. An increase in lactate was detected in the 1H spectrum during recovery but it was not associated with any change in the intracellular pH as assessed in the corresponding 31P spectrum. Phosphocreatine returned to control levels following glucose administration, in contrast to nucleoside triphosphate and inorganic orthophosphate which recovered to only 80% and 200% of their control levels, respectively. These results show that the changes in cerebral amino acids and high-energy phosphates detected by alternating the collection of 1H and 31P spectra allow for a detailed assessment of the metabolic response of the hypoglycemic brain in vivo.     

Effects of acute and chronic hyperglycemia on the neurochemical profiles in the rat brain with streptozotocin-induced diabetes detected using in vivo ¹H MR spectroscopy at 9.4 T

Chronic hyperglycemia could lead to cerebral metabolic alterations and CNS injury. However, findings of metabolic alterations in poorly managed diabetes in humans and animal models are rather inconsistent. We have characterized the cerebral metabolic consequences of untreated hyperglycemia from the onset to the chronic stage in a streptozotocin-induced rat model of diabetes. In vivo 1H magnetic resonance spectroscopy was used to measure over 20 neurochemicals longitudinally. Upon the onset of hyperglycemia (acute state), increases in brain glucose levels were accompanied by increases in osmolytes and ketone bodies, all of which remained consistently high through the chronic state of over 10 weeks of hyperglycemia. Only after over 4 weeks of hyperglycemia, the levels of other neurochemicals including N-acetylaspartate and glutathione were significantly reduced and these alterations persisted into the chronic stage. However, glucose transport was not altered in chronic hyperglycemia of over 10 weeks. When glucose levels were acutely restored to euglycemia, some neurochemical changes were irreversible, indicating the impact of prolonged uncontrolled hyperglycemia on the CNS. Furthermore, progressive changes in neurochemical levels from control to acute and chronic conditions demonstrated the utility of 1H magnetic resonance spectroscopy as a non-invasive tool in monitoring the disease progression in diabetes.     

Cerebral Acid Buffering Capacity at Different Ages Measured In Vivo by 31P and 1H Nuclear Magnetic Resonance Spectroscopy

Cerebral acidosis occurring during ischemia has been proposed as one determinant of tissue damage. Newborn animals appear to be less susceptible to ischemic tissue damage than adults. One possible component of ischemic tolerance could derive from maturational differences in the extent of acid production and buffering in newborns compared to adults. The purpose of this study was to measure the dependency of acid production on the blood plasma glucose concentrations and acid buffering capacity of piglets at different stages of development. Complete ischemia was induced in 29 piglets ranging in postconceptual age from 111 to 156 days (normal term conception, 115 days). Brain buffering capacity during the first 30 min of ischemia was quantified in vivo, via 31P and 1H nuclear magnetic resonance (NMR) spectroscopy, by measuring the change in intracellular brain pH for a given change in the concentration of compounds that contribute to the production of hydrogen ions. Animals from all four age groups showed a similar linear correlation between preischemia blood glucose concentration and intracellular pH after 30 min of ischemia. For each animal the slope of the plot of intracellular pH versus cerebral buffer base deficit was used to calculate the buffer capacity. Using data obtained over the entire 30 min of ischemia, there was no difference in the mean buffer capacity of the different age groups, nor was there a significant correlation between buffer capacity and age. However, there was a significant increase in buffer capacity for the intracellular pH range 6.6-6.0, compared to 7.0-6.6, for all age groups. No significant differences in buffer capacity for these two pH ranges were observed between any of the age groups. Acid buffering capacity was also measured by performing pH titrations on brain tissue homogenized in the presence of inhibitors of glycolysis and creatine kinase. Plots of homogenate pH versus buffer base deficit showed a nonlinear trend similar to that seen in vivo, indicating an increase in buffer capacity as intracellular pH decreases. A comparison of newborn and 1-month-old brain tissue frozen under control conditions or after 45 min of ischemia revealed no differences that could be attributed to age and a slight decrease in buffer capacity of ischemic brain compared to control brain tissue homogenates. There was no difference between the brain buffering capacity measured in vivo using 31P and 1H NMR and that measured in vitro using brain homogenates.     

Biochemical and Neurotoxicological Effects of L-2-Chloropropionic Acid on Rodent Brain

L-2-Chloropropionic acid (L-CPA) is selectively toxic to cerebellar granule cells; necrosis is first observed in rats 36 h after L-CPA administration (750 mg/kg p.o.) and becomes marked by 48 h. L-CPA has also been shown to activate the mitochondrial pyruvate dehydrogenase (PDH) complex in fasted adult rats, resulting in reduced blood glucose and lactate levels. This study aimed to investigate the biochemical and neurotoxicological effects of L-CPA on the brain. Extracts, prepared from guinea-pig cerebellar and cerebral cortex slices incubated in the presence of L-CPA, were analysed using 1H magnetic resonance spectroscopy, 31P magnetic resonance spectroscopy, and amino acid analysis. Glucose metabolism was studied by monitoring the metabolism of [1-(13)C]glucose using gas chromatography/mass spectrometry. Increased glucose metabolism and decreases in the pool sizes of lactate and alanine were observed in both tissues, demonstrating activation of the PDH complex. Extracts were also prepared from the forebrain and cerebellum of animals that had been treated in vivo with L-CPA and analysed as described for the in vitro studies. Similar evidence for PDH activation was demonstrated at 2 and 24 h after dosing in both tissues. At 48 h after dosing, when signs of toxicity are observed, an increase in the lactate concentration and a decrease in N-acetylaspartate in the cerebellum but not in the forebrain confirmed the selective neurotoxic action of L-CPA. These results suggest that activation of the PDH complex does not directly lead to the delayed selective neurotoxicity of L-CPA.     

Age-Related Differences in the Effect of Dichloroacetate on Postischemic Lactate and Acid Clearance Measured In Vivo Using Magnetic Resonance Spectroscopy and Microdialysis

Abstract: Numerous studies using adult animal models suggest that dichloroacetate (DCA) may have neuroprotective properties by virtue of its ability to increase rates of metabolism and, therefore, clearance of brain lactic acidosis, which may accumulate during cerebral ischemia. We tested the hypothesis that postischemic DCA administration affects lactate and acid clearance to different extents in immature versus mature brain. ³¹P and ¹H magnetic resonance spectroscopy were used to measure intracellular acid and lactate clearance rates in vivo in newborn and 1-month-old swine after a 14-min episode of transient near-complete global ischemia. Simultaneous monitoring of extracellular lactate efflux and clearance was measured in the same animals by in vivo microdialysis. Plasma glucose concentrations were elevated in order to study animals with severe cerebral lactic acidosis. Maximal levels of brain lactosis (16–20 µmol/g) and acidosis (pH_{intracellular} 5.8–6.0) were reached during the first 10 min of recovery and were the same in age groups and in subgroups either acting as controls or treated with DCA (200 mg/kg) given from the last minute of ischemia to 5–7 min after ischemia. For newborns, DCA administration improved the postischemic clearance rate of cerebral acidosis and cerebral phosphocreatine, with similar trends for the clearance of lactosis and increased rates of recovery of nucleotide triphosphates, compared with controls. In contrast, DCA administration in 1-month-olds resulted in a modest trend for improvement of cerebral lactate clearance, but did not affect acid clearance or the recovery rate of phosphocreatine or nucleotide triphosphates. Extracellular brain lactate concentrations had similar relative increases and rates of decline for subgroups of either age treated with DCA versus controls. The results of this study indicate that postischemic DCA administration helps to resolve cerebral acidosis to a greater degree in immature than more mature brain, suggesting that DCA may have cerebroprotective properties for neonatal hypoxic-ischemic encephalopathy.     

High-Resolution Proton Magnetic Resonance Spectroscopy of Rabbit Brain: Regional Metabolite Levels and Postmortem Changes

The changes in 16 cerebral metabolites produced by cardiac arrest and subsequent room temperature autolysis were studied using high-resolution proton nuclear magnetic resonance spectroscopy. Biopsies of rabbit cerebral cortex, cerebral white matter, and cerebellum were quantitatively analyzed for acetate, alanine, gamma-aminobutyric acid, creatine, glutamate, glycine, inositol, lactate, N-acetylaspartate, phosphocreatine, succinate, taurine, and threonine. Of these, N-acetylaspartate and the total creatine pool are the best candidates for use as concentration reference standards linking in vitro to in vivo 1H nuclear magnetic resonance measurements. Both changed little immediately after death, and they varied in a distinctive way among cortex, white matter, and cerebellum.     

Nitric oxide mediates hypoxia-induced cerebral vasodilation in humans.

Nitric oxide (NO) plays a pivotal role in the regulation of peripheral vascular tone. Its role in the regulation of cerebral vascular tone in humans remains to be elucidated. This study investigates the role of NO in hypoxia-induced cerebral vasodilatation in young healthy volunteers. The effect of the NO synthase inhibitor N(G)-monomethyl-L-arginine (L-NMMA) on the cerebral blood flow (CBF) was assessed during normoxia and during hypoxia (peripheral O(2) saturation 97 and 80%, respectively). Subjects were positioned in a magnetic resonance scanner, breathing normal air (normoxia) or a N(2)-O(2) mixture (hypoxia). The CBF was measured before and after administration of L-NMMA (3 mg/kg) by use of phase-contrast magnetic resonance imaging techniques. Administration of L-NMMA during normoxia did not affect CBF. Hypoxia increased CBF from 1,049 +/- 113 to 1,209 +/- 143 ml/min (P < 0.05). After L-NMMA administration, the augmented CBF returned to baseline (1,050 +/- 161 ml/min; P < 0.05). Similarly, cerebral vascular resistance declined during hypoxia and returned to baseline after administration of L-NMMA (P < 0.05 for both). Use of phase-contrast magnetic resonance imaging shows that hypoxia-induced cerebral vasodilatation in humans is mediated by NO.     

Effects of Acute Hyperammonemia on Cerebral Amino Acid Metabolism and pHi In Vivo, Measured by 1H and 31P Nuclear Magnetic Resonance

The effects of an acute intravenous infusion of ammonium acetate on rat cerebral glutamate and glutamine concentrations, energy metabolism, and intracellular pH were measured in vivo with 1H and 31P nuclear magnetic resonance (NMR). The level of blood ammonia maintained by the infusion protocol used in this study (approximately 500 microM, arterial blood) did not cause significant changes in arterial PCO2, PO2, or pH. Cerebral glutamate levels fell to at least 80% of the preinfusion value, whereas glutamine concentrations increased 170% relative to the preinfusion controls. The fall in brain glutamate concentrations followed a time course similar to that of the rise of brain glutamine. There were no detectable changes in the content of phosphocreatine (PCr) or nucleoside triphosphates (NTP), within the brain regions contributing to the sensitive volume of the surface coil, during the ammonia infusion. Intracellular pH, estimated from the chemical shift of the inorganic phosphate resonance relative to the resonance of PCr in the 31P spectrum, was also unchanged during the period of hyperammonemia. 1H spectra, specifically edited to allow quantitation of the brain lactate content, indicated that lactate rose steadily during the ammonia infusion. Detectable increases in brain lactate levels were observed approximately 10 min after the start of the ammonia infusion and by 50 min of infusion had more than doubled. Spectra acquired from rats that received a control infusion of sodium acetate were not different from the spectra acquired prior to the infusion of either ammonium or sodium acetate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Biological 1H NMR spectroscopy

Proton nuclear magnetic resonance spectroscopy (1H NMR) is a powerful analytical method used to identify and quantitate chemical compounds. In recent years, it has been used to study rates of metabolism in microbes, isolated perfused tissues, intact animals, and human beings. This review highlights some of the more recent biological applications of 1H NMR in the study of metabolic pathophysiology in animals and man. 1H NMR can rapidly analyze complex mixtures of metabolites found in body fluid and biopsy specimens. In vivo 1H NMR methods can measure intracellular pH, a wide variety of metabolites, tissue perfusion, and rates of metabolism of endogenous and exogenous compounds. Using 13C labeled compounds or magnetization transfer techniques metabolic fluxes may be measured in vivo during virtually all normal and abnormal physiological conditions.     

弥散加权成像及1H磁共振波谱在新生儿缺氧缺血性脑病中的诊断价值

目的:探讨弥散加权成像、1H磁共振波谱诊断新生儿缺氧缺血性脑病的应用价值。方法:以本院收治的缺氧缺血性脑病新生儿37例为研究组,另选择健康新生儿40例作为对照组,两组新生儿均接受弥散加权成像及1H磁共振波谱检查,观察研究组新生儿普通MRI与弥散加权成像检查结果,对比研究组和对照组新生儿的脑代谢化合物相对浓度。结果:与普通MRI检出率相比,研究组患儿的弥散加权成像信号明显升高,差异存在统计学意义(P0.05)。研究组NAA/Cr比值低于对照组,Cho/Cr、MI/Cr、Glu-Gln/Cr、Lac/Cr比值高于对照组,差异存在统计学意义(P0.05)。结论:临床上诊断新生儿缺氧缺血性脑病时,弥散加权成像与1H磁共振波谱的联合应用可提升诊断准确率,通过对代谢物浓度的分析有利于评价缺氧缺血导致脑组织损害的严重程度。     

Effect of fasting and acute ethanol administration on the energy state of in vivo liver as measured by 31P-NMR spectroscopy

The effects of 48 h fasting, administration of ethanol or 2,4-dinitrophenol, on the phosphorus-containing metabolites in liver in vivo have been determined utilizing 31P nuclear magnetic resonance spectroscopy. These measurements were combined with determinations of metabolite concentrations in livers which were freeze-clamped immediately after the NMR measurements were completed. Administration of sub-lethal amounts of dinitrophenol dramatically decreased ATP and increased Pi concentrations in liver in vivo as indicated by a 2.7-fold increase in the NMR-derived [Pi]/[ATP] ratio. Ethanol administration to fed animals increased the NMR-derived [Pi]/[ATP] ratio 27%; in contrast, the same amount of ethanol administered to fasted animals decreased the NMR-derived [Pi]/[ATP] ratio 30%. The NMR visible Pi and ADP represent about 50% and 15% of the total Pi and ADP, respectively. The phosphorylation potentials calculated from the NMR visible Pi and ADP were an order of magnitude higher than those obtained from metabolite concentrations in freeze-clamped tissue. There was no apparent correlation between the phosphorylation potentials derived from either the NMR spectral analyses or from metabolite concentrations and the hepatic [NAD+]/[NADH] ratio. The chemical shift of Pi indicated that ethanol administration elicited a decrease in pH of 0.1 unit in liver in vivo. Hepatic free [Mg2+] was increased 21% in fasted animals, but was unaffected by ethanol administration.     

Analysis of CHO-K1 cell growth in a fixed bed bioreactor using magnetic resonance spectroscopy and imaging

Non-invasive magnetic resonance imaging and spectroscopy techniques have been used to monitor the growth and distribution of Chinese hamster ovary K1 cells growing in a fixed bed bioreactor composed of macroporous carriers. Diffusion-weighted 1H magnetic resonance spectroscopy was used to monitor the volume fraction of the bioreactor occupied by the cells and diffusion-weighted 1H magnetic resonance imaging was used to map cell distribution. The imaging measurements demonstrated that cell growth in the bioreactor was heterogeneous, with the highest cell densities being found at the surface of the carriers. The increase in the volume fraction occupied by the cells during cell growth showed a close correlation with bioreactor ATP content measured using 31P magnetic resonance spectroscopy. These magnetic resonance measurements, in conjunction with measurements of bioreactor glucose consumption, allowed estimation of the specific glucose consumption rate. This declined during the culture, in parallel with medium glucose concentration. This revised version was published online in July 2006 with corrections to the Cover Date.     

Noninvasive quantitative in vivo mapping and metabolism of boronophenylalanine (BPA) by nuclear magnetic resonance (NMR) spectroscopy and imaging

10B-enriched L-p-boronophenylalanine (BPA) is one of the compounds used in boron neutron capture therapy (BNCT). In this study, several variations of nuclear magnetic resonance spectroscopy (MRS) and spectroscopic imaging (MRSI) were applied to investigate the uptake, clearance and metabolism of the BPA-fructose complex (BPA-F) in normal mouse kidneys, rat oligodendroglioma xenografts, and rat blood. Localized 1H MRS was capable of following the uptake and clearance of BPA-F in mouse kidneys with temporal resolution of a few minutes, while 1H MRSI was used to image the BPA distribution in the kidney with a spatial resolution of 9 mm3. The results also revealed significant dissociation of the BPA-F complex to free BPA. This finding was corroborated by 1H and 11B NMR spectroscopy of rat blood samples as well as of tumor samples excised from mice after i.v. injection of BPA-F. This investigation demonstrates the feasibility of using 1H MRS and MRSI to follow the distribution of BPA in vivo, using NMR techniques specifically designed to optimize BPA detection. The implementation of such procedures could significantly improve the clinical efficacy of BNCT.     

Relation of impaired energy metabolism to apoptosis and necrosis following transient cerebral hypoxia-ischaemia

This study investigated whether both mild and severe hypoxia-ischaemia (HI) caused significant numbers of cells to die by apoptosis in the developing brain in vivo. Newborn piglets were subjected to transient global HI and the fraction of all cells in the cingulate gyrus that were apoptotic or necrotic counted 48 h after resuscitation. The mean (S.D.) proportion of apoptotic cells was 11.9% (6.7%) (sham operated controls 4.1% (2.7%)), while 11.4% (8.4%) were necrotic (controls 0.7% (1.3%)) (P<0.05). Apoptotic and necrotic cell counts were both linearly related to the severity of impaired cerebral energy metabolism measured by magnetic resonance spectroscopy (P<0.05), as shown by: (1) the decline in the ratio of nucleotide triphosphates to the exchangeable phosphate pool during HI; (2) the fall in the ratio of phosphocreatine to inorganic phosphate 8 - 48 h after HI; and (3) an increased ratio of lactate to total creatine at both these times. Thus both apoptosis and necrosis occurred in the cingulate gyrus after both severe and mild HI in vivo in proportion to the severity of the insult.     

Brain levels and turnover rates of presumptive neurotransmitters as influenced by administration and withdrawal of ethanol in mice

—Effects of acute or chronic administration of ethanol and its withdrawl on the steady-state levels and turnover rates of certain neurotransmitters have been investigated in mice. The influence of long-term administration of ethanol on the activities of enzymes involved in the metabolism of these transmitters has also been studied. Acute administration of ethanol or acetaldehyde or chronic administration of ethanol resulted in a decrease in the cerebral contents of acetylcholine, acetylCoA and CoA. Brain levels of 5-hydroxytryptamine, norepinephrine and choline remained unchanged after acute administration of ethanol. However, chronic administration of ethanol resulted in a decrease in the norepinephrine content without significantly affecting 5-hydroxytryptamine or choline contents. Cerebral levels of γ-aminobutyric acid increased with both acute or chronic administration of ethanol. The total incorporation of [³H]choline into acetylcholine in brain was depressed upon acute administration of ethanol. After withdrawal of ethanol for one day cerebral levels of norepinephrine returned to normal; however, γ-aminobutyric acid and acetylcholine returned to normal levels at 2 and 4 days after ethanol withdrawal, respectively. Pretreatment of mice with pyrazole, an inhibitor of alcohol dehydrogenase, prevented the ethanol-induced decrease in cerebral acetylcholine levels. The activities of cerebral choline acetyltransferase and glutamic decarboxylase were decreased after 2 weeks of chronic ethanol administration. However, the activities of acetyl cholinesterase and GABA-transaminase remained unaffected after 2 weeks of ethanol treatment     

Dose-dependent metabolic response of mammary carcinoma to photodynamic therapy

The metabolic response of mammary carcinoma in the C3H mouse to photodynamic therapy (PDT) was measured using in vivo 31P nuclear magnetic resonance (31P-NMR) spectroscopy and pH microelectrodes. Twenty-four hours after administration of Photofrin II (12.5 mg/kg), the tumor was subjected to photoactivation using an argon dye laser. Optical treatment doses were 200, 400, and 600 J/cm2 and corresponded to the following tumor control doses: TCD10/30, TCD50/30, and TCD90/30, respectively. In vivo 31P-NMR spectra and pH micro-electrode measurements were obtained prior to treatment and at 4, 24, 48, and 72 h and 1 week post-treatment. The data revealed a significant (P less than 0.0002) alkalosis as indicated by the pH measured by NMR compared to pH measured by microelectrodes at all treatment levels and time points. Spectral differences between treatment groups were apparent as early as 4 h after treatment. The ratio of beta-nucleoside triphosphate to inorganic phosphate at 4 h after treatment was significantly (P less than 0.01) smaller for 600 J/cm2 treatment than for 200 J/cm2 treatment. At curative (600 J/cm2) levels, from 48 h on, no phosphate resonances were detected in the spectra. The pH measured by NMR transiently decreased from pretreatment levels after 200 and 400 J/cm2 treatment (P less than 0.002, P less than 0.009, respectively), while no change in pH from pretreatment values was found after 600 J/cm2 treatment. The data suggest that the early metabolic response of mammary carcinoma to PDT, as indicated by 31P-NMR spectroscopy, is dose dependent, and may be a sensitive indicator of biological outcome to treatment.     

In vivo oxygen-17 nuclear magnetic resonance for the estimation of cerebral blood flow and oxygen consumption

To explore the feasibility of in vivo 17O NMR for the estimation of cerebral blood flow and oxygen consumption, in vivo 17O NMR spectroscopy and imaging were employed in animal models. In the spectroscopy, the changes in the 17O NMR signal intensity after the injection of H2(17)O and the inhalation of 17O2 gas were obtained every 4 seconds with sufficient signal-to-noise ratios for the quantification of cerebral blood flow and oxygen consumption. In the imaging, although the time and spatial resolutions were insufficient for the quantification of H2(17)O, 17O NMR images of rabbit brain could be obtained, indicating that it is possible to map cerebral blood flow and oxygen consumption by 17O NMR imaging.     

Ethanol decreases entry of vincristine into brain of rat: modification by acetylcholine or histamine

Male Sprague-Dawley rats were anesthetized with pentobarbital sodium and a jugular vein and femoral artery cannulated. Ethanol (3%; 13.3 ml/kg) was injected intraperitoneally 5 min before the administration of 10 microCi [3H]vincristine sulfate intravenously. One minute later, saline, acetylcholine, (1 or 2 micrograms/kg) or histamine (1.25, 2.5 or 5 micrograms/kg) was given intravenously. At 15 min the thoracic cavity was opened, a cardiac sample of blood obtained, and saline infused into the left ventricle to remove blood from the brain. Samples of the cerebral cortex, midbrain, cerebellum, and plasma were subjected to liquid scintillation counting. The concentration of ethanol at 20 min after its administration was 20.3 mg/dl. This was associated with a significant decrease in radioactivity in the cerebral cortex and midbrain and a nonsignificant decrease in the cerebellum. Administration of 2 micrograms/kg of acetylcholine in the presence of ethanol decreased the blood pressure and increased the movement of radioactivity into the cerebral cortex and cerebellum while causing a significant decrease in the midbrain. Histamine (2.5 micrograms/kg) significantly increased the movement into the cerebellum and 5 micrograms/kg decreased the movement into the midbrain. The permeability of the blood-brain barrier to [3H]vincristine was decreased by ethanol and this could be modified regionally by vasoactive doses of acetylcholine and histamine. Possible therapeutic advantage might result if vincristine were given in the presence of ethanol which should diminish the potential neurotoxicity.