Magnetic field dependence of solvent proton relaxation in aqueous solutions of Fe3+ complexes

The effect of solute paramagnetic ions on the longitudinal magnetic relaxation rate 1/T1 of solvent water protons depends on magnetic field strength and on the chemical environment of the ions. The variation of 1/T1 with field has been measured for solutions of Gd3+ and Mn2+ ions in three grossly di

The longitudinal proton magnetic relaxation times TI were measured for ferri (met)and carbonmonoxy-bovine haemoglobin and equine myoglobin in 0.1 M KH2P04 aqueous solutions near pH 6 a t 5°C and 35°C from 1.5-to 60-MHx Larmor frequencies. I t is concluded that the correlation time T C for the dipole

The magnetic field dependence of the water-proton spin-lattice relaxation rate (1/T(1)) in tissues results from magnetic coupling to the protons of the rotationally immobilized components of the tissue. As a consequence, the magnetic field dependence of the water-proton (1/T(1)) is a scaled report o

A new model is presented for nuclear-spin relaxation in paraspin relaxation was assumed to be due to distortional modumagnetic transition metal complexes in solution, allowing the eleclation of the zero-field splitting (ZFS) interaction. They also tron-spin relaxation to be outside the Redfield limi

The proton magnetic relaxation time, 2'1, has been measured at 29 MHz in 0.1M KH2P04 and 0.1M NaCl (both pH 6 ) aqueous solutions of human ferrihaemoglobin, the protein concentrations ranging from 0.5 to 5 mM per haem. The linear dependence on protein concentration of the enhancement in relaxation r

The magnetic field dependence of the water proton T, is calculated for aqueous solutions of nitroxides based on a detailed analysis of early T, measurements on nitroxide solutions made as a function of magnetic field. The results parallel those for TI closely and, unlike metal systems, the implicati