3-Dimensional visualization of lesions in rat brain using magnetic resonance imaging microscopy.

High-resolution (< 50 microm) magnetic resonance imaging microscopy (MRM) has been used to identify brain regions and localization of excitotoxin-induced lesions in fixed rat brains, subsequently confirmed using standard histology. The anatomical extent of lesions identified by MRM was identical to that seen in histological sections and various histopathological changes could be visualized. In contrast to the time involved in preparing and examining histological sections, lesions in intact brains could be rapidly identified and visualized in three dimensions by examining digitally generated sections in any plane. This study shows that MRM has tremendous potential as a prescreening tool for neurotoxicity and neuropathology. These observations suggest that MRM has the potential to affect pathology much as conventional MRI has influenced clinical imaging.

Sodium or chloride deficiency lowers muscle intracellular pH in growing rats.

Sodium deficiency and chloride deficiency are associated with a contracted extracellular (ECF) volume and impaired growth in young children and growing rats. In cell culture, lowering sodium in the medium reduces growth factor-stimulated Na+/H+ exchange activity, intracellular pH (pHi), and DNA synthesis. We studied the effect of chronic sodium deficiency and chloride deficiency upon growth, extracellular acid base status, and muscle pHi in young rats. We fed growing rats for 21 days either a control diet, or one deficient in sodium (0.005%), chloride (0.005%), or calories. Muscle pHi was measured using 31phosphorus nuclear magnetic resonance spectroscopy. Rats fed either the sodium-deficient or chloride-deficient diet developed ECF volume contraction and hyponatremia; growth in length and weight was impaired. Muscle pHi was decreased (pHi = 7.074 +/- 0.006, 7.078 +/- 0.006 vs. control 7.100 +/- 0.002; P < 0.02). In calorie-restricted rats, growth was impaired but pHi was not affected (pHi 7.103 +/- 0.008). Metabolic alkalosis developed in the chloride-deficient group; acid base status was not affected in the sodium-deficient group. Despite differences in ECF acid base status, both groups had a low muscle pHi. We speculate that the low muscle pHi was a result of the ECF volume contraction and hyponatremia; low muscle pHi may contribute to retarded cell growth.

Double-quantum-filtered 23Na NMR study of intracellular sodium in the perfused liver.

We acquired double-quantum-filtered 23Na NMR spectra from perfused liver, using a range of tau values from 0.2 to 24 ms, where tau is the separation between the first and second pi/2 pulses in the radio-frequency pulse sequence. For each tau value we compared the amplitude of the double-quantum-filtered 23Na NMR signal acquired from intracellular sodium ions when the liver was perfused with buffer containing the "shift reagent" Dy(PPP)2 to the amplitude of the total double-quantum-filtered 23Na NMR signal acquired when the liver was perfused with buffer containing no Dy(PPP)2. For tau < or = 4 ms, the average ratio of the two amplitudes was 0.98 +/- 0.03 (mean +/- SEM). For tau > or = 8 ms, the average ratio was significantly less than 1. These results demonstrate that double-quantum-filtered 23Na NMR signals acquired from perfused liver using short tau values arise almost exclusively from intracellular sodium ions, but double-quantum-filtered 23Na NMR signals acquired from perfused liver using long tau values contain contributions from both intracellular and extracellular sodium ions. This conclusion suggests that multiple-quantum-filtered 23Na NMR spectroscopy will be useful in studying intracellular sodium levels in the perfused liver, and possibly in the intact liver in vivo.

In vivo 17O NMR study of rat brain during 17O2 inhalation.

In vivo 17O NMR has been used to monitor the H2(17)O concentration in rat brain during inhalation of 17O2. The results are discussed in terms of oxygen consumption in the brain and recirculation into the brain of H2(17)O produced in other organs.

In vivo measurement of cerebral oxygen consumption and blood flow using 17O magnetic resonance imaging.

We used 17O NMR imaging techniques to measure the H2(17)O concentration in a 0.8-ml voxel in the cat brain following injection of an arterial bolus of enriched H2(17)O and during inhalation of enriched 17O2. We also measured the H2(17)O concentration in arterial blood during 17O2 inhalation. The data from the first measurement were used to calculate the blood flow in the voxel. The data from all three measurements were combined to calculate the oxygen consumption in the voxel. The values of cerebral blood flow and oxygen consumption calculated with 17O NMR techniques agree reasonably well with values calculated for a similar region of the cat brain using autoradiographic techniques.

Double-quantum surface-coil NMR studies of sodium and potassium in the rat brain.

Double-quantum filtered and conventional single-pulse sodium and potassium NMR spectra were obtained from in situ rat brain at 7.0 T. using a surface coil. In contrast to the ca. 14% decrease observed in single-pulse sodium NMR spectra upon death, increases as large as ca. 800% were observed in double-quantum filtered sodium spectra. Conversely, a ca. 26% increase was observed in single-pulse potassium spectra upon death, while double-quantum filtered potassium spectra decreased below the noise level, for the shortest preparation time used. The decay rate of double-quantum sodium coherence in the in situ rat brain after death was dependent upon the double-quantum preparation time: this behavior results from the nonuniformity of the brain, and may be related to physiological compartmentalization. The potential application to sodium NMR imaging of cerebral functionality is briefly discussed.

Effects of 2-deoxyglucose on drug-sensitive and drug-resistant human breast cancer cells: toxicity and magnetic resonance spectroscopy studies of metabolism.

The glycolytic inhibitor 2-deoxyglucose (2-DG) was tested as a potential chemotherapeutic agent for drug-resistant cancer cells. Previously it was found that Adriamycin-resistant human MCF-7 breast cancer cells (ADR) exhibit an enhanced rate of glycolysis compared to their parent wild-type (WT) cell line (R. C. Lyon et al., Cancer Res., 48: 870-877, 1987). We now describe a specific toxic effect of 2-DG on the ADR cells, which is more than 15-fold greater than for WT cells. Using 31P magnetic resonance spectroscopy of perfused MCF7 cells we continuously monitored the accumulation of 2-deoxyglucose 6-phosphate together with concomitant changes in other phosphate-containing metabolites. Kinetic measurements demonstrated that ADR cells accumulated 2-deoxyglucose 6-phosphate faster and to a greater extent than WT cells, while their depletion of high energy compounds (ATP, phosphocreatine) was more pronounced and became irreversible earlier. The phosphorylation of 2-DG could be followed more effectively by the use of 13C magnetic resonance spectroscopy of 2-DG enriched with 13C at C-6, since the signals of 2-DG and 2-deoxyglucose 6-phosphate are clearly resolved and, unlike 31P magnetic resonance spectroscopy, there are no other interfering signals. With the use of this technique with ADR and WT cells the rate of phosphorylation of 2-DG was found to be 11.2 x 10(-4) and 6.5 x 10(-4) mmol/min/mg protein, respectively. The results of these studies indicate that differences in the biochemistry of energy metabolism of resistant cells may make them targets for energy antimetabolites.

Metalloporphyrin magnetic resonance contrast agents. Feasibility of tumor-specific magnetic resonance imaging.

The criteria for tumor-specific MRI contrast agents are considered. The metalloporphyrins have been shown to be potential tumor-specific contrast agents due to their selective retention by cancer cells. The Mn(III) water-soluble porphyrin complexes are preferred on the basis of relaxivity and stability. Protein binding in human plasma enhances the relaxivity of Mn(III)-tetraphenylsulfonato-porphyrin (MnTTPS). In preliminary work this agent was shown to enhance MRI contrast at 0.5 T in subcutaneous human colon carcinomas grown in nude mice. Here we report further evidence of enhanced contrast in the same system, and extend this work to human breast tumors in nude mice using a 2 T animal imager. Questions of metalloporphyrin stability, toxicity and dose-contrast relationship are discussed.

Monitoring the transport and phosphorylation of 2-deoxy-D-glucose in tumor cells in vivo and in vitro by 13C nuclear magnetic resonance spectroscopy.

We describe the use of 2-deoxy-D-[6-13C]glucose to follow simultaneously, by 13C NMR, both transport and phosphorylation to its 6-phosphate form, in MCF-7 breast cancer cells in vitro and in vivo in subcutaneous tumors in nude mice.

31P-NMR spectroscopy of human cancer cells proliferating in a basement membrane gel.

We describe a system in which proliferating human breast cancer cells are monitored by NMR spectroscopy for at least 6 days in basement membrane gel (BMG)1 threads. The cells are perfused under standard sterile cell culture conditions. 31P-NMR spectra obtained continuously for up to 64 h showed an increase in the signals owing to an increasing number of cells. Cell division in the BMG is easily observed by microscope or by the human eye as the gel opacifies. Spectra of cells in the BMG threads at 20% confluency show a more rapid signal increase than at 60% confluency. Cells grown in vivo in nude mice show a spectrum markedly similar to in vitro spectra in BMG threads, whereas the same cells in agarose threads lack peaks owing to Pi, glycerophosphocholine, and glycerophosphoethanolamine. With the high resolution obtained from this system we distinguished intracellular from extracellular Pi in vitro, and found that the intracellular pH is equal to that observed in the same cell line in vivo. This cell-BMG system is in effect a model tumor, but it is composed of a homogeneous cell population that can be observed indefinitely as the cells reproduce. The material needed is inexpensive, the technique is simple and efficient, and no adaptation of the spectrometer is required. This model will be useful for studying intracellular metabolism and the interaction of cells with the basement membrane.

Glucose metabolism in drug-sensitive and drug-resistant human breast cancer cells monitored by magnetic resonance spectroscopy.

Glucose utilization and lactate production have been monitored as a function of time using 13C magnetic resonance spectroscopy and [13C1]-glucose with perfused wild type MCF-7 human breast cancer cells and a drug-resistant (AdrR) cell line derived from them. Compared to wild type cells, AdrR cells exhibited an enhanced (3-fold) rate of glycolysis, indicating an increased demand for ATP production. We have investigated the effects of glucose depletion and azide, an inhibitor of oxidative phosphorylation, on the levels of intracellular phosphates (Pi, ATP) and intracellular pH using 31P magnetic resonance spectroscopy and on the rates of glycolysis. In both cell lines, ATP levels and the rates of glucose utilization and lactate production were invariant in the presence of azide. ATP production, especially in AdrR cells, was highly dependent on active glucose metabolism. The results of these direct measurements confirm that these cells survive by predominantly utilizing glycolysis. Glutamate and myo-inositol were observed in 13C spectra of acid extracts of AdrR but not wild type cells. Both metabolites are potential substrates in drug detoxification. These differences in rates of glycolysis, ATP production, and the production of certain metabolites may reflect metabolic adaptations associated with the development of drug resistance.

A versatile multinuclear probe designed for in vivo NMR spectroscopy: applications to subcutaneous human tumors in mice.

We describe a versatile NMR probe that is designed for a variety of in vivo spectroscopic studies on small animals in vertical wide-bore magnets. Replaceable brackets enable the coils to be exchanged readily in order to observe 1H, 13C, 31P, and other nuclei, and to carry out double-resonance experiments. Two solenoidal coil designs are described and applied to observe 31P, 13C, and 1H natural abundance spectra of subcutaneously implanted human tumors in mice. For 31P and 31C observation with 1H decoupling, a concentric coil arrangement was employed with a broadband inner coil and the outer coil tuned to 1H at 400 MHz. A single coil tuned to 400 MHz was used to observe 1H resonances. A thin copper foil design was found to be superior with respect to S/N and resolution to previously described Faraday shields used to shield the NMR signals originating from nontumor tissues. 31P spectra of in vivo tumor tissue were compared to spectra of in vitro perfused tumor cells of the same origin. Tumor tissue in vivo exhibited much higher levels of inorganic phosphate and phosphocreatine. Signals from [13C2]glucose and its major metabolite, [13C2]lactate, were readily observed and monitored in an unobstructed region of the 13C spectra of tumor tissue in vivo following the injection of [13C2]glucose in adjacent tissues. A 1H spectrum of tumor tissue, characterized by five broad resonances, was observed with excellent water suppression.

Phospholipid metabolism in cancer cells monitored by 31P NMR spectroscopy.

Addition of choline, ethanolamine, or hemicholinium-3 (a choline kinase inhibitor) to the perfusate of human breast cancer cells monitored by 31P NMR spectroscopy resulted in significant changes to phosphomonoester (PME) and phosphodiester (PDE) signals. These results enable us to assign the PMEs to phosphcholine (PC) and phosphoethanolamine (PE), the PDEs to glycerophosphorylcholine and glycerophosphorylethanolamine, and to define the pathways producing them. The PMEs are products of choline and ethanolamine kinases, the first steps in phospholipid synthesis; and the PDEs are substrates of glycerophosphorylcholine phosphodiesterase, the last step in phospholipid catabolism. Furthermore, PC and PE peaks are twice as intense in cells at log phase versus confluency. We also observed these signals in vivo in human colon and breast tumors grown in mice. Since PMEs are low in most nonproliferating tissues, they could form a basis for noninvasive diagnosis. Also, PE and PC are situated between the control enzymes of two major synthetic pathways and will allow noninvasive 31P NMR studies of these pathways in intact cells and in vivo.

Studies on the mechanism of selective retention of porphyrins and metalloporphyrins by cancer cells.

Comparative studies of the toxicity, stability, and retention of the water-soluble porphyrin, tetraphenylporphyrin sulfonate (TPPS), and its complex with Mn(III), have been made with the human breast cancer cell line MCF-7 wild type, and an adriamycin-resistant line derived from it, termed AdrR. Based on growth inhibition, we determined the maximum non-toxic concentration of MnTPPS tolerated by these cells. The integrity of MnTPPS in vitro was investigated by fluorescence microscopy, and we found that there is very little dissociation of MnTPPS within these cells within 4 days. We report novel proton magnetic resonance relaxation measurements of the bulk water of cells in a gel matrix undergoing perfusion. A slightly greater net uptake of MnTPPS in the wild-type cells was observed compared to AdrR; however, there was no significant difference in retention of MnTPPS. These results indicate that over a period of several hours the mechanism of selective retention of these compounds in tumour cells is not due to specific interaction with heme-binding protein, of which there is enhanced expression in the resistant cells. The fact that the net rate of washout of MnTPPS is approximately the same as the net rate of uptake also appears to eliminate compartmentalization or enzymatic modification of MnTPPS within these cells.

Tissue distribution and stability of metalloporphyrin MRI contrast agents.

Mn(III), Fe(III), and Gd(III) complexes of tetrakis(4-sulfonatophenyl)porphyrin (TPPS) and several other porphyrins were evaluated as potential MRI contrast agents. Based on consideration of relaxivity and stability properties in solution, MnTPPS was found to be the compound of choice. At pH 7 the Gd and Mn complexes significantly enhanced the water proton relaxation rate, while the relaxivity of FeTPPS exhibited a significant loss of relaxivity above pH 6 due to oxy-dimer formation. Although GdTPPS exhibited the highest relaxivity in solution, this property was rapidly lost due to dissociation of the metal ion. By contrast MnTPPS remained stable in human plasma after incubation for 9 days. Upon intravenous injection into athymic mice bearing subcutaneous human colon carcinoma xenografts, MnTPPS provided enhanced relaxation of the tissue water in several excised mouse tissues, notably kidney, liver, and tumor. The results at a fixed field (0.25 T) and relaxation dispersion studies showed decreases in water relaxation rates with time for kidney and liver, but an increase for the tumor, with a maximum near 4 days at the highest dose used.

A perfusion technique for 13C NMR studies of the metabolism of 13C-labeled substrates by mammalian cells.

We describe an improved perfusion system designed for NMR studies with 13C-labeled metabolites. Using this system we have monitored the uptake and metabolism of [13C]acetate and [13C]glucose in pooled human lymphocytes cast in an agarose gel thread.

Differences in phosphate metabolite levels in drug-sensitive and -resistant human breast cancer cell lines determined by 31P magnetic resonance spectroscopy.

31P magnetic resonance spectra of perfused human breast cancer cells with the phenotype of pleiotropic drug resistance exhibit striking differences in the levels of phosphate metabolites from the wild-type, drug-sensitive parent cell line. Resistant cells demonstrated elevated levels of phosphocreatine and depressed levels of phosphomonoesters, phosphodiesters, and diphosphodiesters. These differences may reflect significant alterations in the control of bioenergetic metabolism between drug-resistant and -sensitive cells.

In vivo dephosphorylation of WR-2721 monitored by 31P NMR spectroscopy.

The in vivo dephosphorylation of the radioprotective agent S-2-[3-(aminopropylamino)]ethylphosphorothioic acid (WR-2721) in male CD2F1 mice was measured by 31P NMR spectroscopy after i.p. injection. The disappearance of the WR-2721 phosphate NMR signal with time was concurrent with an increase and splitting of the inorganic phosphate NMR signal. The more acidic inorganic phosphate resonance is shown to be attributed to phosphate (inorganic phosphate) in the urine. Using regression first-order kinetic analysis of data, after i.p. injection of 600 mg/kg, the half-life of WR-2721 was determined to be 40.9 +/- 5.9 (S.D.) min (n = 10).