Intracellular sodium and lithium NMR relaxation times in the perfused frog heart

The feasibility of monitoring intracellular sodium changes using Na triple quantum filtered NMR without a chemical shift reagent (SR) was investigated in an isolated rat heart during a variety of interventions for Na(i) loading. Perfusion with 1 mM ouabain or without K+ present in the perfusate for

## Abstract Intracellular [Na^+^], [H^+^], and [ATP] and mechanical performance were measured in the isovolumic perfused rat heart during ischemia. The concentration of intracellular sodium, [Na^+^]~i~, was determined by atomic absorption spectroscopy under control conditions, and [Na^+^] was monit

## Abstract Each of six perfused rat hearts was subjected to 30 min of hypoxia followed by 60 min of reoxygenation. Inversion‐recovery data on the intracellular Na NMR signal, differentiated by a shift reagent, 6 m__M__ Dy(PPP)~2~, were obtained every 5 min, and __T__~1~ values were calculated. The

## Abstract The effect of ischemia and reperfusion on transverse relax ation (__T__~2~) of intracellular Na^+^ (Na^+^~i~) was measured with 5‐min time resolution in isolated rat hearts. Na~i~ __T__~2~ relaxation was biexponential with 28 ± 7% fast (T~2f~)and 72 ± 7% slow (__T__~2s~) decay. This rat

## Abstract Although Ca^2+^ transport regulation at subcellular organelles is of great interest, only limited methodology has been available for measuring organellar [Ca^2+^] levels. The present study employs the ^19^F NMR resonance frequency of 4F‐BAPTA to measure free [Ca^2+^]. In 4F‐BAPTA loaded

## Abstract The hyperfine shift reagent, TmDOTP^5−^, was used to resolve the ^39^K NMR resonances of intra‐ (K~i~^+^) and extracellular (K~e~^+^) potassium in isolated, perfused guinea pig hearts. [K~i~^+^] as measured by ^39^K NMR was 25.9 ± 10.3 mM, compared with 114.4 ± 10.8 mM as measured by at