Post-ischemic 31P NMR determination of myocardial intracellular pH in vivo using ATP peak.

31P NMR allows non-invasive measurement of intracellular pH, which drops during tissue hypoxia or ischemia. Determination is usually based on the chemical shift between the inorganic phosphate (P(i)) and phosphocreatine (PCr) peaks. During reperfusion, P(i) is taken up to form PCr and ATP, and in our model at least (an isolated, working rat heart perfused with an erythrocyte suspension), the level of P(i) reduces well below the pre-ischemic level, making pH determination difficult. The chemical shifts of the three ATP peaks also depend on pH, and the level of ATP remains high during reperfusion, so these might be used to determine pH. The results of one experiment are presented in detail, showing the time course of high energy phosphate levels before, during and after a 32 min ischemic insult, and close agreement between the pH determinations from the Pi and gamma-ATP peaks can be seen. The formula used to calculate pH from the ATP peak was: pH (ATP) = 0.59 delta 2-5.0 delta + 15.9 where delta is the shift in ppm between PCr and gamma-ATP. All pH readings by both methods from a series of seven experiments were compared and a 1:1 agreement demonstrated (correlation coefficient 0.63, p < 0.0001). Although the ATP shifts also depend on magnesium complexation which we have ignored, this appears to be justifiable within the errors of the method; the good agreement between the results of the two methods, and the ability to determine pH during reperfusion suggest that calculation of intracellular pH from the chemical shift of gamma-ATP is a useful technique.

Computer simulations in comparison with in vivo measurements of nifedipine-induced changes in renal allograft hemodynamics.

Analysis of Doppler spectrum waveforms is increasingly used in the differential diagnosis of human renal allograft dysfunction. The physiologic interpretation of changes in Doppler spectra obtained from renal allografts, however, remains a major problem. Computer simulation models of the renal circulation may provide insight into the physiologic mechanisms responsible for changes in Doppler spectrum characteristics. The results of measurements of renal allograft hemodynamics with both determinations of PAH clearance and Doppler spectrum analysis in 11 kidney allograft recipients were explained physiologically using a computer simulation model of kidney allograft hemodynamics. Using PAH clearance and blood pressure measurements a significant decrease in RVR was found (from 0.32 +/- 0.17 to 0.20 +/- 0.07 mm Hg x min/ml, P < 0.05) after administration of the vasodilatory drug nifedipine. The Doppler spectrum waveform obtained from interlobar renal arteries showed a decrease in the RI (from 0.60 +/- 0.04 to 0.56 +/- 0.06; P < 0.05) and Tmax (from 133 +/- 32 to 98 +/- 32 ms; P < 0.05). The user-designed simulation model of renal hemodynamics showed comparable changes of the waveform when, in the model, the analogs of blood pressure, impedance of the artery, and the impedance of the peripheral vascular bed were altered proportionally.