A study of galactose intolerance in human and rat liver in vivo by 31P magnetic resonance spectroscopy.

An oral load of 20 mg/kg galactose produces significant changes in the 31P magnetic resonance spectrum of the liver of a galactosemic patient. The peak at 5.2 ppm (which includes inorganic phosphate and galactose-1-phosphate) increased on two occasions to about twice its original size 60 min after galactose administration. An oral load of 10 mg/kg galactose given to a second patient produced no discernible changes at 30 min. We have also used an animal model of galactose intolerance, in which galactose metabolism in rats was blocked by the acute administration of ethanol. Studies in vivo and in vitro showed that the increase in the peak at 5.2 ppm was largely due to galactose-1-phosphate. We have shown in this preliminary study that small amounts of galactose can produce significant elevation of hepatic galactose-1-phosphate, which can be detected by 31P magnetic resonance spectroscopy.

Study of liver metabolism in glucose-6-phosphatase deficiency (glycogen storage disease type 1A) by P-31 magnetic resonance spectroscopy.

Liver metabolism of two patients (aged 15 and 23 yr) was studied by P-31 magnetic resonance spectroscopy at 1.9 tesla. The P-31 spectra of liver showed the resonances of phosphomonoesters (including sugar phosphates), inorganic phosphate (Pi), phosphodiesters (e.g. glycerophosphorylcholine, glycerophosporylethanolamine), and ATP. These resonances were quantified by expressing their peak areas in mM (assuming that ATP concentrations in normal liver is 2.5 mM) or as a ratio relative to the area of the phosphodiester resonance. After an overnight fast liver phosphomonoesters in patients were 2.6 and 1.6 AU, respectively (controls 1.1 +/- 0.5, mean +/- 2 SD, n = 17). At the same time liver Pi was decreased in patients to 1.3 and 1.0, respectively (controls 1.8 +/- 0.8). Based on chemical shift measurements the increase in phosphomonoesters could be attributed to accumulation of sugar phosphates (mainly glycolytic intermediates). After 1 g/kg oral glucose, hepatic sugar phosphates decreased in patients by 64 and 40%, respectively, and reached normal levels (on the absolute intensity scale); whereas liver Pi increased by 130 and 40%, respectively. Liver Pi levels remained elevated in both patients 30 min after ingestion of glucose. Liver sugar phosphates and Pi did not change in control subjects (n = 4) after glucose. In contrast to some previous reports, we have found accumulation of glycolytic intermediates in the liver of glucose-6-phosphatase-deficient patients during fasting. In these patients high levels may enhance the activity of residual glucose-6-phosphatase thus increasing hepatic glucose production and reducing the degree of hypoglycemia during fasting.(ABSTRACT TRUNCATED AT 250 WORDS)

Study of hereditary fructose intolerance by use of 31P magnetic resonance spectroscopy.

The effect of fructose on liver metabolism in patients with hereditary fructose intolerance (HFI) and in heterozygotes for HFI was studied by 31P magnetic resonance spectroscopy (31P-MRS). In patients with HFI (n = 5) ingestion of small amounts of fructose was followed by an increase in sugar phosphates and decrease in inorganic phosphate (Pi) in the liver that could be detected by 31P-MRS. 31P-MRS could be used to diagnose fructose intolerance and to monitor the patients' compliance with a fructose-restricted diet. In heterozygotes (n = 8) 50 g fructose given orally led to accumulation of sugar phosphates and depletion of Pi in the liver. Fructose also induced a larger increase in plasma urate in heterozygotes than in control subjects. The effect of fructose on liver Pi and plasma urate was most pronounced in heterozygotes with gout (n = 3). Heterozygosity for HFI may predispose to hyperuricaemia.

Quantitative studies of human cardiac metabolism by 31P rotating-frame NMR.

We have developed 31P NMR spectroscopic methods to determine quantitatively relative levels of phosphorous-containing metabolites in the human myocardium. We have used localization techniques based on the rotating-frame imaging experiment and carried out with a double-surface coil probe. Information is obtained from selected slices by rotating-frame depth selection and from a complete one-dimensional spectroscopic image using phase-modulated rotating-frame imaging. The methods collect biochemical information from metabolites in human heart, and we use the fact that the phosphocreatine/ATP molar ratio in skeletal muscle at rest is higher than that in working heart to demonstrate that localization has been achieved for each investigation. The phosphocreatine/ATP molar ratio in normal human heart has been measured as 1.55 +/- 0.20 (mean +/- SD) (3.5-sec interpulse delay) in six subjects using depth selection and as 1.53 +/- 0.25 (mean +/- SD) in four subjects using spectroscopic imaging. Measurement of this ratio is expected to give a useful and reproducible index of myocardial energetics in normal and pathological states.

The study of human organs by phosphorus-31 topical magnetic resonance spectroscopy.

The potential clinical use of topical magnetic resonance spectroscopy (volume selection by static magnetic field gradients) was tested in 50 studies in volunteers. Topical magnetic resonance spectroscopy (MRS) was shown to be a straightforward method for localising 31P spectra of brain and liver. However, the spherical shape and fixed position of the selected volume posed serious limitations to the study of heart and transplanted kidney by topical MRS. Phosphorus-31 spectra of approximately 30 cm-3 of brain or liver could be obtained in 8 min. Ratios of metabolite concentrations could be determined with a coefficient of variation ranging from 10% to 30%. The ratios of phosphocreatine/ATP and inorganic phosphate/ATP in brain were 1.8 and 0.3, respectively. The ratio of inorganic phosphate/ATP in liver was 0.9. Intracellular pH was 7.03 in brain and 7.24 in liver. The T1 relaxation times of phosphocreatine, inorganic phosphate and gamma-ATP in brain were 4.8 s, 2.5 s and 1.0 s, respectively.

Biochemical investigation of human tumours in vivo with phosphorus-31 magnetic resonance spectroscopy.

The bioenergetic state of 15 human tumours was examined with phosphorus-31 magnetic resonance spectroscopy. A striking diversity in metabolic patterns was observed, and significant differences from normal tissue were seen in all cases. A common feature was an elevation of intracellular pH, which may be related to an increase in Na+/H+ exchange during cell activation. It is unlikely that the patterns observed directly correlate with malignancy, but characterisation of the energetic state of a given tumour in a given physiological environment may help in the design and evaluation of interventions for that specific case.

Assessment of human liver metabolism by phosphorus-31 magnetic resonance spectroscopy.

Phosphorus 31 magnetic resonance (MR) spectroscopy was used for the study of liver metabolism in vivo in seven healthy subjects. Subjects were examined in a 1.6 T whole-body magnet using surface coils for data acquisition. The region of the liver from which MR signals were collected was selected by magnetic-field profiling. The concentration ratios of adenosine triphosphate (ATP), inorganic phosphate (Pi) and sugar phosphates contained in liver cells could be reproducibly assessed. Cytosolic pH and the free magnesium concentration were determined to be 7.18 and 300 microM, respectively. During intravenous fructose tolerance tests the hepatic concentrations of sugar phosphates, ATP and Pi altered markedly. During the first 5 min following bolus injection of 250 mg fructose/kg body weight the concentration of sugar phosphates increased sevenfold whereas Pi and ATP decreased by three- to fourfold. Metabolism of sugar phosphates was complete within 20 min and could be followed by 31P MR with a time resolution of 5 min. Thus, 31P MR spectroscopy yields insight into liver metabolism which has not been accessible so far using conventional non-invasive methods. In conjunction with intravenous fructose loading, 31P MR spectroscopy may provide a means for the functional assessment of the liver.

Effect of norepinephrine on ketogenesis, fatty acid oxidation, and esterification in isolated rat hepatocytes.

Recent studies in man demonstrated a marked ketogenic effect of increased plasma norepinephrine concentrations as observed in diabetic ketoacidosis. Since this effect may have been due either to increased substrate supply for ketogenesis (lipolysis) or to direct hepatic activation of ketogenesis, the latter mechanism was examined in isolated rat hepatocytes. Incubation of hepatocytes with norepinephrine (10(-7) to 10(-4) M) resulted in a dose-dependent increase in conversion of the long-chain fatty acid [1-14C]palmitate into ketone bodies and CO2. Norepinephrine decreased [1-14C]palmitate conversion into triglycerides without affecting fatty acid uptake. Norepinephrine enhanced ketogenesis from [1-14C]palmitate in a physiologic range of fatty acid concentrations (0.5-2.5 mM), but failed to affect fatty acid esterification to phospholipids or mono- and diglycerides. In contrast to long-chain fatty acids, oxidation of the medium-chain fatty acid [1-14C]octanoate to ketone bodies was not enhanced by norepinephrine, whereas CO2 production increased. The effect of norepinephrine on [1-14C]fatty acid oxidation was blocked by the alpha 1 receptor blocker prazosin. The results demonstrate that norepinephrine diverts long-chain fatty acids into the pathways of oxidation and ketogenesis away from esterification, suggesting enhanced carnitine-dependent mitochondrial fatty acid uptake. The studies using octanoate indicated that norepinephrine also enhanced fatty acid oxidation by increasing the flux of acetyl-CoA through the Krebs cycle. The data suggest that stress-associated sympathetic activation and norepinephrine discharge, as observed in diabetic ketoacidosis, result in direct activation of ketogenesis in the liver.

Different actions of deferoxamine and iron on Ga-67 abscess detection in rats.

The contrast-enhancing properties of iron (Fe) and deferoxamine (DFO) in abscess imaging with Ga-67 citrate were compared in rats bearing turpentine-induced abscesses. Iron administration shifted Ga-67 from plasma into tissues such as muscle and fat. As a result, the abscess-to-plasma ratio increased whereas the abscess-to-muscle ratio decreased. DFO enhanced the abscess-to-muscle and abscess-to-plasma ratios by increasing urinary Ga-67 excretion. In contrast to Fe, DFO removed abscess-bound Ga-67, thus representing a disadvantage of DFO compared with Fe. As a result, the abscess-to-plasma ratio was more effectively enhanced by Fe than by DFO. We conclude that abscess imaging with Ga-67 citrate may be improved by administration of Fe for detection of abscesses masked by blood activity, or DFO for detection of abscesses surrounded by muscle tissue.