Effects of hydralazine-induced vasodilation on the energy metabolism of murine tumors studied by in vivo 31P-nuclear magnetic resonance spectroscopy.

The effects of hydralazine on tumor energy metabolism and on some cardiovascular parameters were measured. Tumor energy metabolism was studied in C3Hf/Sed mice with isotransplants of a spontaneous murine fibrosarcoma (FSaII, congruent to 100 mm3 in volume) and 31P-NMR. Cardiovascular parameters were measured in anesthetized C3Hf/Sed mice via intracarotid catheter. Hydralazine doses of 0.25 mg/kg given ip caused an increase of the phosphocreatine to inorganic phosphate ratio (PCr: Pi) in 5 of 6 animals. These doses had minimal effects on mean arterial blood pressure, though there may have been an increased cardiac output due to a decreased afterload. Hydralazine doses greater than or equal to 2.0 mg/kg given ip were associated with a decrease in PCr, nucleotide triphosphate, and pH, and an increase in Pi (P less than .01 for control vs. 10 mg hydralazine/kg). This substantial decrease in high-energy phosphates was associated with a pronounced decrement in mean arterial blood pressure. These findings provide a rational basis for the study in experimental systems of hydralazine-induced enhancement of cell killing by hyperthermia and by agents toxic to hypoxic cells. Further, these results can be taken as a sign that hydralazine should be used with care in patients undergoing radiation treatment.

Quantitative differential effects of rhodamine 123 on normal cells and human colon cancer cells by magnetic resonance spectroscopy.

Rhodamine 123 is a lipophilic cationic compound that is selectively taken up by cancer cell mitochondria. This compound is toxic to epithelial cancer cells in vitro and displays significant anticancer activity in vivo. However, the mechanism of action of rhodamine 123 in intact, actively metabolizing cell preparations is unknown. We have used 31P- and 13C-nuclear magnetic resonance spectroscopy to quantitatively characterize how rhodamine 123 affects the energetics of human colon cancer cells (HCT-116) and spontaneously immortalized normal epithelial cells (CV-1). Rhodamine 123 differentially altered the phosphorus and glucose metabolism of HCT-116 and CV-1 cells. 31P-nuclear magnetic resonance detected mitochondrial poisoning in the HCT-116 human colon cancer cell line in its early stages after selective uptake of rhodamine 123. When we compared administration of rhodamine 123 and [1-C13]glucose to administration of [1-C13]glucose alone in the HCT-116 cells, we noted a marked decrease in intracellular pH to 6.7 +/- 0.06 (mean +/- SD) units, a 2.2-fold increase in lactate production, and a 1.8-fold increase in glucose consumption after 10 h. In addition, we found a 2-fold rise in intracellular free magnesium 12 h after rhodamine 123 administration. These results suggest that when rhodamine 123 inhibits mitochondrial ATP production, it initially stimulates cytoplasmic glycolysis in an attempt to maintain cellular energy demands. The marked fall in intracellular pH and rise in intracellular free magnesium after administration of rhodamine 123 may inhibit activity of several glycolytic enzymes: this effect would inhibit cytoplasmic ATP generation and interfere with multiple cell enzymatic processes, leading to cell death. The CV-1 cells showed no change in intracellular pH, intracellular free magnesium, or magnesium-bound ATP levels over the 24-h period following rhodamine 123 administration. Rhodamine 123 also failed to alter glucose utilization and lactate production levels significantly in the CV-1 cells. These results prove the usefulness of 31P- and 13C-nuclear magnetic resonance spectroscopy for quantifying differing effects of rhodamine 123 on the high energy phosphate metabolism and glucose metabolism of HCT-116 and CV-1 cells.

Angiogenesis determines blood flow, metabolism, growth rate, and ATPase kinetics of tumors growing in an irradiated bed: 31P and 2H nuclear magnetic resonance studies.

Experimental tumors growing in irradiated tissue have been used to study the biological differences characteristic of locally recurrent tumors. Since the hypoxic cell fraction of tumors growing in irradiated tissue is increased and growth rate is slowed, these tumors are assumed to be metabolically deprived with hypoperfusion. In this study, we directly measured the effect of tumor bed irradiation on blood flow, growth rate, rate of nucleoside triphosphate (NTP) turnover, and metabolic state using 31P and 2H nuclear magnetic resonance, and an intradermal assay for angiogenesis. (NTP turnover refers to ATP-synthetase mediated NTP turnover that is visible to 31P nuclear magnetic resonance using the technique of saturation transfer.) A decrease in the number of small blood vessels perfusing tumors in a preirradiated bed was found. Most of the decrease was due to a loss of vessels with diameters less than 0.04 mm. When tumors growing in preirradiated tissue reached approximately 100 mm3 in volume, a high frequency of gross and microscopic necrosis and hemorrhage was already observed in most tumors. Consistent with these observations, the phosphocreatine/inorganic phosphate and nucleoside triphosphate/inorganic phosphate ratios were significantly lower in the tumors growing in a preirradiated bed compared with tumors in a nonirradiated bed. The blood flow rate was similar to control for tumors less than 100 mm3 (45.8 versus 40.5 ml/100 g/min, P = not significant), but was significantly lower than control for tumors greater than 100 mm3 (40.4 versus 12.2 ml/100 g/min, P less than 0.01). The NTP turnover rates correlated (P less than 0.005, r = 0.66) with the volume doubling rate (1/tumor volume doubling time), but for tumors approximately 100 mm3 in size neither the volume doubling rate nor the NTP turnover rate of tumors growing in an irradiated bed was statistically lower than control [NTP turnover: 14 +/- 3%/s versus 9 +/- 2%/s; volume doubling rate: 0.47 +/- 0.07/day versus 0.33 +/- 0.04/day (mean +/- SE)]. A large intertumor variability of all metabolic parameters was observed.

Deuterium NMR studies of cerebroside-phospholipid bilayers.

2H-NMR was used to probe the interaction of non-hydroxy fatty acid cerebroside and 2-hydroxy fatty acid cerebroside with the polar head group and with the acyl chains of dipalmitoylphosphatidylcholine in unsonicated bilayers. It is shown that the interior of the bilayer exhibits uniformly increasing orientational order as the concentration of both types of cerebroside increases, whereas the surface of the bilayer, as reflected by the head group motion, becomes disordered. The extent of the disorder at the surface is dependent upon the type and concentration of the cerebroside. These results are discussed in terms of hydrogen-bonding interactions.

A calorimetry and deuterium NMR study of mixed model membranes of 1-palmitoyl-2-oleylphosphatidylcholine and saturated phosphatidylcholines.

Binary phase diagrams have been constructed from differential scanning calorimetry (DSC) data for the systems 1-palmitoyl-2-oleylphosphatidylcholine (POPC)/dimyristoylphosphatidylcholine (DMPC), POPC/dipalmitoylphosphatidylcholine (DPPC) and POPC/distearoylphosphatidylcholine (DSPC). Mixtures of POPC with DMPC exhibit complete miscibility in the gel and liquid crystalline states. Mixtures of POPC with DPPC or with DSPC exhibit gel phase immiscibility over the composition range 0-75% DPPC (or DSPC). These results, when taken together with previous studies of mixtures of phosphatidylcholines, are consistent with the hypothesis that PCs whose order-disorder transition temperatures (Tm values) differ by less than 33 deg. C exhibit gel state miscibility. Those whose Tm values differ by more than 33 deg. C exhibit gel state immiscibility. 2H-NMR spectroscopy has been used to further study mixed model membranes composed of POPC and DPPC, in which either lipid has been labeled with deuterium in the 2-, 10- or 16-position of the palmitoyl chain(s) or in the N-methyls of the choline head group. POPC/DPPC mixtures in the liquid crystalline state are intermediate in order between pure POPC and DPPC at the same temperature. The POPC palmitoyl chain is always more disordered than the palmitoyl chains of DPPC in liquid crystalline POPC/DPPC mixtures. This is attributed to the fact that a POPC palmitoyl chain is constrained by direct bonding to have at least one oleyl chain among its nearest neighbors, while a DPPC palmitoyl chain must have at least one neighboring palmitoyl chain. When liquid crystalline POPC, DPPC and POPC/DPPC mixtures are compared at a reduced temperature (relative to the acyl chain order-disorder transition), POPC/DPPC mixtures are more disordered than predicted from the behavior of the pure components, in agreement with enthalpy data derived from DSC studies. Within the temperature range of the broad phase transition of 1:1 POPC/DPPC, a superposition of gel and liquid crystalline spectra is observed for 1:1 POPC/[2H]DPPC, while 1:1[2H]POPC/DPPC exhibits only a liquid crystalline spectrum. Thus, at temperatures within the phase transition region, the liquid crystalline phase is POPC-rich and the gel phase is DPPC-rich. Comparison of the liquid crystalline quadrupole splittings within the thermal phase transition range suggests that mixing of the residual liquid crystalline POPC and DPPC is highly non-ideal.

Failure of 1H nuclear magnetic resonance spectroscopy of blood plasma to detect malignancy.

Water-suppressed proton nuclear magnetic resonance (NMR) of plasma was proposed as a technique for detecting malignant tumors. In that analysis, bloods drawn from cancer patients at the Beth Israel Hospital (BIH; Boston, MA), were easily distinguished from normal subjects by measuring and averaging the proton NMR methyl and methylene line widths of plasma lipoproteins. We collected blood at the Massachusetts General Hospital (MGH), including from normal controls, patients with untreated and treated malignant tumors, and patients with nontumor diseases. The plasma NMR analyses were carried out blind. The code was not broken until all patient charts and pathology records were reviewed, plasma analyses were completed, and patients had been divided into appropriate clinical groups. Analysis of these data showed no differences between the means of the study groups (false-positive and false-negative frequencies 46% and 57%, respectively). An inverse correlation of methyl/methylene line widths with age (P less than .01), and a correlation with nitrate-requiring cardiovascular disease (P less than .05) was, however, evident. This test cannot be validly used to detect malignancy.

Creatine kinase-catalyzed reaction rate in the cyanide-poisoned mouse brain.

Brain creatine kinase (CK)-catalyzed phosphorus flux from phosphocreatine (PC) to ATP was measured in vivo in young adult mice made reversibly hypoxic by injection of cyanide. Phosphorus spectra and saturation transfer measurements of CK-catalyzed flux were acquired using a high-field (8.45 T) nuclear magnetic resonance (NMR) spectrometer. After low cyanide doses (1-3 mg/kg of body weight), there were no measurable changes in brain pH or in concentrations of PC, the nucleoside triphosphates (including ATP), and Pi. The CK-catalyzed phosphorus flux increased about 75% after the low cyanide dose. Higher doses (4-6 mg/kg) produced a transient 30-40% decrease in PC concentration, doubling of Pi, and a 0.2 unit decrease in pH. The CK-catalyzed phosphorus flux decreased 50-80% after the higher cyanide doses. This decrease in phosphorus flux was present long after reactant concentrations returned to precyanide values. It is proposed that the increase in brain CK-catalyzed phosphorus flux with the lower cyanide doses is due to an increase in ADP concentration. The large, prolonged decrease in CK-catalyzed reaction rate in the moderately poisoned brain may be due to loss of activity of the mitochondrial CK isoform.

Tumors growing in irradiated tissue: oxygenation, metabolic state, and pH.

Experimental tumors growing in irradiated tissue have been used to study the biological differences characteristic of locally recurrent tumors. Animal tumors were early generation isotransplants of a spontaneous fibrosarcoma in a C3Hf/Sed mouse, designated FSa-II. Since the hypoxic cell fraction of tumors growing in irradiated tissue is increased, these tumors are assumed to be metabolically deprived with hypoperfusion and acidosis. In this study we directly measured the oxygen partial pressure (pO2) distribution, metabolic state, and pH of tumors growing in an irradiated tumor bed using oxygen sensitive electrodes and 31P-NMR. The results confirmed a three-fold increase in the number of pO2 readings less than or equal to 2.5 mmHg and also showed increased acidosis with a 0.17 unit decrease in pHNMR. When tumors growing in pre-irradiated tissue reached approximately 100 mm3 in volume, a high frequency of gross and microscopic necrosis and hemorrhage was already observed. Consistent with these observations, the phosphocreatine/inorganic phosphate (PCr/Pi) and nucleoside triphosphate/inorganic phosphate (NTP/Pi) ratios were significantly lower in the tumors in a pre-irradiated bed compared to tumors in a non-irradiated bed (PCr/Pi: 0.51 vs 0.79, p less than 0.05; and NTP/Pi: 0.64 vs 0.93, p less than 0.05). The longitudinal relaxation time (T1) of Pi was numerically shorter in control tumors (consistent with the better tissue oxygenation), but this did not reach statistical significance (2.09 +/- .11 sec vs 2.25 +/- .16 sec).

Evaluation of tumor energy metabolism and microvascular blood flow after glucose or mannitol administration using 31P nuclear magnetic resonance spectroscopy and laser Doppler flowmetry.

The effects of intraperitoneally administered glucose or mannitol (5 mg/g body weight, 25% solutions) on tumor energy metabolism and tumor red blood cell flux were studied using 31P-nuclear magnetic resonance spectroscopy and laser Doppler flowmetry. Isotransplants of a spontaneous murine fibrosarcoma growing in the hind foot dorsum were used. 31P-nuclear magnetic resonance and laser Doppler flowmetry studies in glucose treated animals were performed on small (congruent to 100 mm3) and large (congruent to 300 mm3) tumors. In mannitol treated animals, tumors with an average volume of congruent to 200 mm3 were used. Using this tumor model, intraperitoneally administration of the hypertonic sugar solutions caused similar declines in tumor microcirculation (mannitol, 60 +/- 8% flow reduction; glucose, 72 +/- 4% flow reduction; t = 60 min). These changes were not glucose-specific and can primarily be explained by a water shift into the abdominal cavity and an associated hypovolemic hemoconcentration. A stable (small tumors) or transiently increased (large tumors) tumor energy metabolism which occurred after glucose administration was probably caused by a transiently increased glucose availability. The decline in energy metabolism after mannitol, a non-metabolized sugar alcohol, and the earlier decline in tumor pH seen in the glucose treated animals, supports this conclusion. The differences in the high energy phosphate response to glucose seen in small compared with large tumors, suggests that the baseline metabolic state of larger tumors includes a glucose deficiency in addition to tumor hypoxia.

Estimation of tumor oxygenation and metabolic rate using 31P MRS: correlation of longitudinal relaxation with tumor growth rate and DNA synthesis.

31P MRS longitudinal relaxation times (T1) were determined for C3H murine fibrosarcomas (FSaII), and mammary carcinomas (MCaIV). Tumors were implanted in the foot dorsum, and were 100-300 mm3 in volume. T1s were repeated after the animal was allowed to breathe 100% oxygen for 30 min and then again 36-48 hr following 30 Gy. The spectrum were obtained using an 8.5 T spectrometer with a 8 cm bore and a 1.4 cm single turn antenna coil. The 31P relaxation times for untreated tumors in air breathing animals were: 3.78 sec for phosphomonoesters, 4.37 sec for inorganic phosphate (Pi), 2.73 sec for phosphocreatine, 1.37 sec for gamma ATP, 1.14 sec for alpha ATP, and 1.18 sec for beta ATP. The Pi T1s were 4.37 and 4.70 sec in control and irradiated tumors in air breathing animals. Respiration of oxygen for 30 min reduced the T1s to 3.02 and 2.62 sec in control and irradiated tumors respectively. The Pi T1 of an anoxic tumor, determined on an in situ tumor 60 min after death was 5.93 sec. The oxygen breathing induced decrease in the T1 of Pi is unlikely to have been caused by the paramagnetic properties of oxygen alone, and suggests a component of increased magnetization transfer secondary to the ATPase reaction. Oxygen breathing following 30 Gy, resulted in a decreased growth time (800 mm3 endpoint) and an increased proportion of cells in S-phase. These results support the hypothesis that the decrease in Pi T1 measured with oxygen breathing is a measure of tumor oxygen tension and metabolic rate, and suggests that T1 measurement may indirectly predict tumor growth rate and DNA synthesis.

Effects of hydralazine on in vivo tumor energy metabolism, hematopoietic radiation sensitivity, and cardiovascular parameters.

Energy metabolism of murine FSaII foot tumors was studied by in vivo 31P-MRS in C3Hf/Sed mice. Spectroscopy was performed following exposure to escalating doses of hydralazine (HYD) ip. At 0.25 mg/kg, HYD caused a 20% increase in PCr/Pi and had no significant effect on mean arterial blood pressure. HYD doses greater than or equal to 2 mg/kg lead to hypotension which was associated with a decrease in PCr, NTP, pH, and an increase in Pi (p less than 0.01 for control vs 10 mg/kg HYD). When mice were given ip injections of HYD (0.25, 1, 2 and 10 mg/kg) 10 min prior to whole body irradiation, spleen stem cell survival after 6 Gy was increased (2.19 colonies in control animals vs 6.74 colonies per spleen in animals treated with greater than or equal to 2 mg/kg HYD), as was the LD50/30 dose (6.49 Gy [control] vs 9.00 Gy [10 mg/kg HYD]). The data provide evidence that PCr/Pi is a useful indicator of perfusion efficiency (and indirectly of hypoxic cell fraction) in FSaII tumors. These observations suggest that HYD may be a useful adjuvant for hyperthermic treatment of tumors and for potentiation of agents specifically toxic to hypoxic or nutrient-deprived cancer cells. HYD should be used with care in patients receiving radiation treatments or other therapies for which hypoxia can unfavorably affect treatment outcome.

Correlations between 31P-NMR spectroscopy and tissue O2 tension measurements in a murine fibrosarcoma.

Size-dependent changes in therapeutically relevant and interrelated metabolic parameters of a murine fibrosarcoma (FSaII) were investigated in vivo using conscious (unanesthetized) animals and tumor sizes less than or equal to 2% of body weight. Tumor pH and bioenergetics were evaluated by 31P nuclear magnetic resonance spectroscopy (31P-MRS), and tumor tissue oxygen tension (pO2) distribution was examined using O2-sensitive needle electrodes. During growth FSaII tumors showed a progressive loss of phosphocreatine (PCr) and nucleoside triphosphate (NTP) with increasing inorganic phosphate (Pi) and phosphomonoester (PME) signals. Ratios for PCr/Pi, PME/Pi, NTP/Pi, and phosphodiester/inorganic phosphate (PDE/Pi) as well as pH determined by 31P-NMR (pHNMR) and the mean tissue pO2 progressively declined as the tumors increased in size. The only relevant ratio increasing with tumor growth was PME/NTP. When the mean tissue pO2 value was plotted against pHNMR, NTP/Pi, PCr/Pi, PME/Pi, and PDE/Pi for tumor groups of similar mean volumes, a highly significant positive correlation was observed. There was a negative correlation between mean tumor tissue pO2 values and PME/NTP. From these results we concluded that 31P-MRS can detect changes in tumor bioenergetics brought about by changes in tumor oxygenation. Furthermore, the close correlation between oxygenation and energy status suggests that the microcirculation in FSaII tumors yields an O2-limited energy metabolism. Finally, a correlation between the proportion of pO2 readings between 0 and 2.5 mmHg and the radiobiologically hypoxic cell fraction in FSaII tumors was observed. The latter finding might be of particular importance for radiation therapy.

Effects of pentobarbital anesthesia on the energy metabolism of murine tumors studied by in vivo 31P nuclear magnetic resonance spectroscopy.

The effects of pentobarbital anesthesia on the energy metabolism of FSaII and MCaIV foot tumors in mice were studied by 31P MRS. Using an 8.5 T spectrometer, in vivo spectra were obtained in 15 animals before and after pentobarbital anesthesia (0.05 mg/g ip). The average phosphocreatine/inorganic phosphate ratios (PCr/Pi) with and without pentobarbital were similar for both tumor histologies. Effects on individual tumors, however, were greater than 20% in 9/15 animals and greater than 50% in 6/15 animals. Pentobarbital anesthesia increased the variability of tumor intracellular pH, and the phosphomonoester/nucleotide triphosphate (PME/NTP) and nucleotide triphosphate/inorganic phosphate ratios (NTP/Pi). When examining the average in a cohort, pentobarbital anesthesia had no significant effect on the PCr/Pi, PME/NTP, NTP/Pi ratios or the pH. However, approximately equal to 50% of individual tumors do have significant changes in these parameters. The anesthesia-induced variability of tumor energy metabolism may explain the decrease in TCD50 observed in previous studies using multifraction radiation.

Brain creatine phosphate and creatine kinase in mice fed an analogue of creatine.

Brain phosphocreatine (PCr) concentration and creatine kinase (CK) activity have been studied by 31P nuclear magnetic resonance (NMR) spectroscopy in mice fed an analogue of creatine, beta-guanidinopropionic acid (GPA). The phosphorylated analogue (GPAP), which almost completely replaces PCr in skeletal muscle, is a poor substrate for CK. Mice, which received GPA in food (2%) and water (0.5%) for up to 9 months beginning at 35 days of age, were normal in appearance and activity. Maximal brain GPAP concentration, reached after two weeks of feedings, was approximately equal to the concentration of PCr. The concentration of PCr decreased at least 20% relative to that of the nucleoside triphosphates. When GPA feedings were stopped, GPAP disappeared in about 20 days from skeletal muscle, but only after 40-50 days from brain. Steady-state NMR saturation transfer studies showed a markedly reduced chemical exchange rate from PCr to ATP in brains of GPA-fed mice. These results suggest a compartmentation of brain PCr. The GPA-accessible PCr compartment has a slow rate of PCr turnover compared to skeletal muscle. The slow reaction rate of the GPA-inaccessible PCr as a CK substrate is consistent with the hypothesis that this residual PCr is the same compartment which is stable in hypoxic or seizing animals.

Maturational increase in mouse brain creatine kinase reaction rates shown by phosphorus magnetic resonance.

In-vivo phosphorus fluxes in the reaction catalyzed by creatine kinase (CK) were measured in brains of mice from 3 to 40 days of age using high-field (8.45 T) phosphorus magnetic resonance and the saturation transfer technique. This technique gives the ratio of chemical flux to reactant concentration directly and allows the calculation of pseudo-rate constants for the forward direction from PC to ATP (kf) and for the reverse direction (kr). The spin-lattice relaxation times (T1) for phosphocreatine (PC) and for the nucleoside triphosphate (NTP) nuclei, estimated by the progressive saturation technique, did not change during this age period. The PC concentration doubled relative to the NTP concentration over the first month of life. The kf and the flux of phosphorus nuclei in the forward direction increased 2- to 3-fold in the very narrow time period from 12 to 15 days of age. Brain phosphorus flux from PC to ATP thus increased 4- to 6-fold in the first month of life. An increase at least that large occurred in the reverse direction, but the kr could not be measured consistently in the younger animals using the saturation transfer technique. Phosphorus fluxes were equal in the forward and reverse directions in the mature brain. The capacity to increase rates of glycolysis and tissue respiration in response to increased energy demand appears in the same narrow age period as the increase in CK-catalyzed reaction rates in the developing rodent brain. We propose that these coincident changes in brain energy metabolism reflect the maturation of mechanisms for coupling cell energy production to rapid changes in energy requirements.

13C- and 31P-NMR studies of human colon cancer in-vitro and in-vivo.

We report comparative 31P-NMR studies in-vivo and in-vitro of the human adenocarcinoma cell line HCT-116 in a high-density, perfused microcarrier culture and as a tumour from the same cell line grown in three different immune-suppressed animal models (NIH triple deficient, Nude, SCID). The phosphate metabolite ratios, pHNMR and intracellular free magnesium, derived from the 31P-NMR spectra, were compared for the in-vivo and in-vitro systems. Results obtained with HCT-116 cells on microcarrier beads are quantitatively similar to that of small (122 mm3), tumours in-vivo derived from the same cell line in any of the immune-suppressed animal systems studied. This suggests that in-vitro microcarrier cell culture serves as a useful model system for deriving information about metabolism of small, tumours in-vivo. It offers the additional advantages of allowing for precise control of substrate milieu, perfusion and oxygenation. The microcarrier system was also used to measure flux through glycolysis and the pentose cycle. In particular, we measured glucose utilization and the production of lactate, alanine, glutamine and glycogen in proton-decoupled 13C-NMR experiments following administration of [1-13C]glucose. We found that (63% +/- 6%) of the glucose utilized was released as [3-13C] lactate in the presence of oxygen, indicating that the HCT-116 cells have a high level of aerobic glycolysis. Serial labelling experiments with [1-13C] glucose and [6-13C] glucose reveal that at least (11.6% +/- 1.3%) of the glucose utilized enters the pentose cycle. We determined that (6.9% +/- 1.2%) of the glucose utilized is recycled to glucose via the pentose cycle while (4.7% +/- 1.4%) of the glucose utilized enters the pentose cycle to form lactate. The high rate of recycling via the pentose cycle suggests that a significant fraction of cellular NADPH is generated by the pentose cycle as opposed to generation by the malate-pyruvate shuttle.

Gradient moment nulling for steady-state free precession MR imaging of cerebrospinal fluid.

Steady-state free precession (SSFP) pulse sequences can produce magnetic resonance (MR) images rapidly, in which cerebrospinal fluid (CSF) is several times more intense than the other tissues. However, motion in the presence of magnetic field gradients reduces the intensity of CSF drastically, unless the time integral of the gradient waveform between each radio-frequency (rf) pulse vanishes. The consequences of motion on SSFP are explored here in detail theoretically and experimentally. The principle of gradient moment nulling is applied with the objective of giving CSF in SSFP images uniformly high intensity everywhere, in spite of motion. Theoretical analysis of the phase of the transverse magnetization from a group of isochromats, with a trajectory described by a Taylor series, reveals how motion along each direction disrupts SSFP and also causes ghost artifacts. Images of CSF in the cervical spine are found to have less extensive flow voids and weaker ghosts from pulsation if the first moment calculated from the rf pulse to the center of the gradient echo vanishes for both the frequency encoding and slice selection gradient waveforms. However, first-order moment nulling of the phase encoding gradient waveform is unnecessary for SSFP imaging of CSF.

Chemical exchange magnetic resonance imaging (CHEMI).

Systems investigated with NMR spectroscopy are sometimes heterogeneous with respect to chemical composition, rates of chemical exchange, and other properties influencing magnetic resonance parameters. A method was developed to spatially encode reaction kinetic information and produce NMR images sensitive to chemical exchange. A modified spin-echo pulse sequence was used to allow chemical shift-selective imaging and chemical exchange encoding. 1H and 31P images with microscopic resolution were obtained which yielded chemical exchange as a function of position. Chemical exchange images of the base-catalyzed proton exchange of acetylacetone and of the enzyme-catalyzed 31P transfer between PCr and ATP were obtained at 8.4 T in phantoms at 360 and 146 MHz, respectively. These images demonstrate a means of investigating kinetic heterogeneity and compartmentalization of reactions that are important in the study of both living and non-living systems.