ISSN:1420-4096    

DOI:10.1159/000173186

出版商:S. Karger AG    

年代:1989

数据来源: Karger

ISSN:1420-4096    

DOI:10.1159/000173187

出版商:S. Karger AG    

年代:1989

数据来源: Karger

ISSN:1420-4096    

DOI:10.1159/000173188

出版商:S. Karger AG    

年代:1989

数据来源: Karger

摘要:

The concentration of intracellular sodium [Na+]i has been measured in the perfused rat kidney using 23Na nuclear magnetic resonance (NMR) in combination with the extracellular shift reagent Dy(PPPi)72-. The data show 100% visibility of Na+ in interstitial spaces. A measurement of the resonance intensities of intra- and extracellular 23Na ions along with a knowledge of the extracellular space as a fraction of the total kidney water space yielded an average [Na+]i of 27 ± 2 mM for the kidney at 37°C. After prolonged ischemia [Na+]i rose to approach that in the external medium. In the absence of 5% albumin in the perfusion medium, the linewidth of the 35Cl resonance of an adult kidney (45 Hz) was about twofold larger than that of the medium alone (25 Hz). In contrast, the linewidth of 35Cl resonance of an adult kidney perfused with an albumin-containing medium (82 Hz) was only about 27% of that from the medium alone (300 Hz). We interpret this effect to be due to compartmentation of albumin in the extracellular space such that the interstitial space is not freely accessible to albumin. However, for a developing, immature kidney from a growing animal, perfused with an albumin-containing medium, the linewidth of the 35Cl resonance (233 Hz) was only slightly less than that of the medium alone (300 Hz) indicating a much greater albumin permeability of the capillary walls. 19F NMR of a perfused adult kidney, loaded with the membrane-impermeant intracellular calcium indicator 5FBAPTA, yielded a value of 256 nM for [Ca2+]i. Induction of ischemia for 10 min caused the [Ca2+]i to rapidly rise to 660 nM, which could not be fully reversed by reperfusion, suggesting irreversible injur

ISSN:1420-4096    

DOI:10.1159/000173189

出版商:S. Karger AG    

年代:1989

数据来源: Karger

摘要:

Previous studies using 31P nuclear magnetic resonance (NMR) saturation transfer techniques to quantitate the energy metabolism of the kidney have often resulted in estimates of adenosine triphosphate (ATP) turnover which are much lower than those predicted from the renal oxygen consumption and reasonable values of the P/O ratio. We measured the ATP turnover in isolated perfused kidneys of rats, using 31P NMR saturation transfer and a new procedure for quantitation of the intracellular Pi concentration. The estimated turnover rates of ATP were higher than previously reported. The P/O ratios calculated on the basis of these rates of ATP turnover and rates of renal oxygen consumption reported in the literature were within the range of theoretically possible values. Thus, 31P NMR saturation transfer can be used to quantitate the ATP turnover in the isolated perfused rat kidney.

ISSN:1420-4096    

DOI:10.1159/000173190

出版商:S. Karger AG    

年代:1989

数据来源: Karger

摘要:

87Rb, 23Na and 31P nuclear magnetic resonance (NMR) were used to monitor changes in renal cations and energetics during the induction of hypoxia in the isolated perfused rat kidney. The NMR-determined unidirectional Rb+ flux in normoxic kidneys was shown to be a good measure of net intracellular K+ influx in the perfused rat kidney model. The changes in 87Rb, 23Na and 31P spectra following the induction of hypoxia are consistent with hypoxic depletion of intracellular adenosine triphosphate (ATP) and a subsequent decrease in Na-K-ATPase transport activity. The exponential rate constant for 87Rb+ efflux measured during Rb+ uptake in normoxic kidneys (0.12 ± 0.01 min1) was not significantly different to the rate constant for 87Rb+ efflux during the induction of hypoxia (0.16+0.07 min-1). We conclude that there is no direct effect of hypoxia on renal cellular membrane integrity and that renal cell sensitivity to hypoxia is due to an inability to sustain cellular ion gradients following depletion of intracellular ATP

ISSN:1420-4096    

DOI:10.1159/000173191

出版商:S. Karger AG    

年代:1989

数据来源: Karger

摘要:

In the last few years, we have focused our research effort on the magnetic resonance spectroscopic (NMR) studies of organ transplantation in the rat. P-31 NMR was employed to study changes in high-energy phosphates, intracellular pH in vivo of transplanted kidneys either during normal function, while undergoing the rejection process or subjected to other insults (e.g. ischemia, cyclosporine nephrotoxicity, urinary obstruction) which may also cause graft dysfunction. Nuclear magnetic resonance (NMR) parameters, specifically relative peak areas and intracellular pH, accurately distinguished among the different causes of graft dysfunction. Ureteral obstruction was clearly identified by elevations in the phosphodiester/urine phosphate peak. Ischemia and rejection were both associated with increases in inorganic phosphates and phosphomonesters and decreases in the beta-phosphate peak of adenosine triphosphate but were distinguishable from each other by differences in intracellular pH which was normal in rejected allografts (7.33 ± 0.07, n = 3) and low in ischemic allografts (7.00 ± 0.05, n = 3, p < 0.05). Grafts insulted with cyclosporine toxicity were not distinguishable from normal allografts by any of the parameters studied. To determine the temporal relationship of NMR changes in allograft rejection, similar studies were performed serially in a group of rejecting (R) kidneys (n = 7) and compared with a control group of nonrejecting (NR) kidneys (n = 7). Major decrease in adenosine triphosphate (ATP) with increases in Pi and a marked increase in the Pi/ATP ratio were noted in the R allografts over time. The R allografts could be completely segregated from the NR allografts on the basis of the Pi/ATP ratio by day 7. These data suggest that 31P NMR spectroscopy may have potential clinical application in differentiating among the causes of graft failure of human renal allograft

ISSN:1420-4096    

DOI:10.1159/000173192

出版商:S. Karger AG    

年代:1989

数据来源: Karger

摘要:

Methylamines and polyols are known to behave as organic osmolytes in the adaptation of many cells to hyperosmolar conditions. Using 1H nuclear magnetic resonance spectroscopy to analyze perchloric acid extracts we have examined several tissues in the rat for the presence of these compounds. Methylamines such as glycerophosphorylcholine, choline and betaine were observed in the renal inner medulla, urinary bladder, urine, liver, brain, and plasma. Myo-inositol was relatively abundant in the renal inner medulla and brain whereas sorbitol was detected only in the inner medulla. A variety of unidentified compounds was also detected in each tissue. Although these methylamines and polyols are known to respond to osmotic changes in the renal inner medulla, their responses in other tissues remain to be investigated.

ISSN:1420-4096    

DOI:10.1159/000173193

出版商:S. Karger AG    

年代:1989

数据来源: Karger

摘要:

Cortical, medullary and papillary T1 and T2 water proton relaxation times were measured at 37°C, 20 MHz. The measurements were made using kidneys from rats affected by many forms of experimental acute renal failure (ARF), namely acute hemorrhagic hypovolemia, angiotensin II administration, antidiuretic hormone (ADH) administration, glycerol, and other nephrotoxins (gentamicin, cisplatinum, cyclosporine), renal artery occlusion for different periods of time, and ureteral ligation. From the T1· and PW (percent tissue water content) the bound water (FB) and HF (percent water bound/g solid) were calculated according to a fast proton diffusion model. In most experimental models studied, the experiments were repeated following paramagnetic enhancement with GdDTPA administration (70 mmol/kg BW). By profiling the deviations from normal, it was possible to differentiate the ischemic (shortened T1; prolonged T2), obstructive (very high T1· and T2 in both cortex and medulla) and nephrotoxic (prolonged T2) forms of ARF Significant changes in free/bound water compartments occurred, though their biological significance is unknown. T1· and T2 ratios before and after paramagnetic enhancement correlated well with estimates of glomerular filtration rate. In the first minutes following acute hemorrhagic hypovolemia, the intrarenal water distribution remained unchanged. After GdDTPA significant water proton T1 and T2 changes characterized the immediate posthemor-rhagic state similar to the effect of

ISSN:1420-4096    

DOI:10.1159/000173194

出版商:S. Karger AG    

年代:1989

数据来源: Karger