Grucker D, Guiberteau T, Eclancher B, Chambron J, Chiarelli R, Rassat A, Subra G, Gallez B

Institut de Physique Biologique, URA 1173 du CNRS, Faculte de Medecine, Strasbourg, France.

The most widely used free radicals for dynamic nuclear polarization (DNP) experiments or related Overhauser imaging are nitroxides. The DNP parameters in biological fluids were measured in order to provide guidelines for the design of new nitroxides, adapted to the biological applications of DNP. Eighteen nitroxides were studied at a concentration of 1 mM. Extrapolation at complete electron paramagnetic resonance saturation and proton  -relaxation-time measurements enable calculation of the coupling factor between nitroxide free electrons and water protons. In deoxygenated phosphate-buffered solutios, the NMR signal enhancement by DNP ranged from  -36.3 to -6.7, and the coupling factor ranged from 0.31 to 0.03. Nitroxides with a long side chain yield poor enhancement, although their relaxivity is far greater than that of nitroxides with small chains. In a 1 mM albumin solution, the loss in enhancement factor is mainly caused by the fact that proton relaxation occurs via inter  ctions, not only with the dissolved free radicals but also with the albumin macromolecules. In serum, the enhancement factor isower than that in an albumin solution, because of the higher protein concentration in serum. In red-blood-cell suspensions, the enhancement factor was further decreased. Two effects contribute to this decrease: first, the increased viscosity due to the presence of red blood cells, and second, the susceptibility effects of the paramagnetism of deoxyhemoglobin. The high sensitivity to oxygen of DNP in phosphate-buffered solution is also greatly reduced when nitroxides are dissolved in blood.
 

PMID: 7850180, UI: 95153024