Efficient stem cell labeling for MRI studies.

Iron oxide particles are especially suited for cell tracking experiments due to their extraordinarily molar relaxivity as compared with other paramagnetic nuclei. We have compared different iron oxide particles (Sinerem, Endorem and magnetic microspheres) for their suitability to label embryonic stem cells (D3 cell line). In addition to detectability thresholds, particular attention has been paid to the evaluation of long-term stability of the labelling procedure (up to 4 weeks) as well as to toxic and other adverse effects on cell viability. Comparative studies were performed using neural progenitor cells (C17.2) and dendritic cells. The present study indicates strong dependence of the label efficiency and stability on the iron oxide particles and cell lines in use.

Simultaneous in vivo monitoring of hepatic glucose and glucose-6-phosphate by (13)C-NMR spectroscopy.

Hepatic glucose-6-phosphate (G6P) was monitored non-invasively in rat liver by in vivo (13)C NMR spectroscopy after infusion of [1-(13)C] glucose. The phosphorylation of glucose to G6P yields small but characteristic displacements for all of its (13)C-NMR resonances relative to those of glucose. It is demonstrated that in vivo (13)C-NMR spectroscopy at 7 Tesla provides the spectral sensitivity and resolution to detect hepatic G6P present at sub-millimolar concentration as partially resolved low-field shoulders of the glucose C1 resonances at 96.86 ppm (C1beta) and 93. 02 ppm (C1alpha). Upon (13)C-labeling, the intracellular conversion of [1-(13)C] glucose to [1-(13)C] G6P could be monitored, which allowed the hepatic glucose-G6P substrate cycle to be assessed in situ. The close correlation found for the (13)C labeling patterns of glucose and G6P supports the concept of an active substrate cycle whose rate exceeds that of net hepatic glucose metabolism. High-resolution (13)C-NMR spectroscopy and biochemical analyses of tissue biopsies collected at the end of the experiments confirmed qualitatively the findings obtained in vivo.

Nonlinear decrease over time in N-acetyl aspartate levels in the absence of neuronal loss and increases in glutamine and glucose in transgenic Huntington's disease mice.

Mice transgenic for exon I of mutant huntingtin, with 141 CAG repeats, exhibit a profound symptomatology characterized by weight loss, motor disorders, and early death. We performed longitudinal analysis of metabolite levels in these mice using NMR spectroscopy in vivo and in vitro. These mice exhibited a large (53%), nonlinear drop in in vivo N-acetyl aspartate (NAA) levels over time, commencing at approximately 6 weeks of age, coincident with onset of symptoms. These drops in NAA levels occurred in the absence of neuronal death as measured by postmortem Nissl staining and neuronal counting but in the presence of nuclear inclusion bodies. In addition to decreased NAA, these mice showed a large elevation of glucose in the brain (600%) consistent with a diabetic profile and elevations in blood glucose levels both before and after glucose loading. In vitro NMR analysis revealed significant increases in glutamine (100%), taurine (95%) cholines (200%), and scyllo-inositol (333%) and decreases in glutamate (24%) and succinate (47%). These results lead to two conclusions. NAA is reflective of the health of neurons and thus is a noninvasive marker, with a temporal progression similar to nuclear inclusion bodies and symptoms, of neuronal dysfunction in transgenic mice. Second, the presence of elevated glutamine is evidence of a profound metabolic defect. We present arguments that the elevated glutamine results from a decrease in neuronal-glial glutamate-glutamine cycling and a decrease in glutaminase activity.

Ascorbic acid, a vitamin, is observed by in vivo 13C nuclear magnetic resonance spectroscopy of rat liver.

The first in vivo detection of a vitamin with nuclear magnetic resonance (NMR) is reported for mammalian liver. Vitamin C, also known as ascorbic acid, was monitored noninvasively in rat liver by "whole body" 13C NMR spectroscopy at high field after infusion of [1,2-13C2]glucose into anesthetized rats. Generally, the carbon resonances of ascorbic acid overlap with those of other highly abundant cellular metabolites, thus precluding their observation in situ. This problem was resolved by taking advantage of the 13C-13C spin couplings introduced by the two covalently bound 13C nuclei in [1,2-13C2]glucose. During glucose metabolism, [5,6-13C2]ascorbic acid was synthesized, which also exhibited characteristic 13C homonuclear spin couplings. This feature enabled the spectral discrimination of ascorbic acid from overlapping singlet resonances of other metabolites. Quantitative analysis of the spin-coupling patterns provided an estimate of the turnover rate of hepatic ascorbic acid in vivo (1.9 +/- 0.4 nmol.min-1.g-1) and a novel approach toward a better understanding of optimal ascorbic acid requirements in humans. The results obtained in vivo were confirmed with high-resolution proton and 13C NMR spectroscopy of liver extracts.