Manganese ions as intracellular contrast agents: proton relaxation and calcium interactions in rat myocardium.

Paramagnetic manganese (Mn) ions (Mn(2+)) are taken up into cardiomyocytes where they are retained for hours. Mn content and relaxation parameters, T(1) and T(2), were measured in right plus left ventricular myocardium excised from isolated perfused rat hearts. In the experiments 5 min wash-in of MnCl(2) were followed by 15 min wash-out to remove extracellular (ec) Mn(2+) MnCl(2), 25 and 100 micro M, elevated tissue Mn content to six and 12 times the level of control (0 micro M MnCl(2)). Variations in perfusate calcium (Ca(2+)) during wash-in of MnCl(2) and experiments including nifedipine showed that myocardial slow Ca(2+) channels are the main pathway for Mn(2+) uptake and that Mn(2+) acts as a pure Ca(2+) competitor and a preferred substrate for slow Ca(2+) channel entry. Inversion recovery analysis at 20 MHz revealed two components for longitudinal relaxation: a short T(1 - 1) and a longer T(1 - 2). Approximate values for control and Mn-treated hearts were in the range 600-125 ms for T(1 - 1) and 2200-750 ms for T(1 - 2). The population fractions were about 59 and 41% for the short and the long component, respectively. The intracellular (ic) R(1 - 1) and R(2 - 1) correlated best with tissue Mn content. Applying two-site exchange analyses on the obtained T(1) data yielded results in parallel to, but also differing from, results reported with an ec contrast agent. The calculated lifetime of ic water (tau(ic)) of about 10 s is compatible with a slow water exchange in the present excised cardiac tissue. The longitudinal relaxivity of Mn ions in ic water [60 (s mM)(-1)] was about one order of magnitude higher than that of MnCl(2) in water in vitro [6.9 (s mM)(-1)], indicating that ic Mn-protein binding is an important potentiating factor in relaxation enhancement.