Molecular basis of water proton relaxation in gels and tissue

The NMR relaxation times T i , T2, and TI were measured in isolated rat lungs as functions of external magnetic field Bo, temperature, and lung inflation. The observed linear dependence on Bo of the tissue-induced free induction decay rate (Tb)-' provides independent confirmation of the air/water in

In this study the exchange between 'H magnetization in "free" water ( 'Hf) and that in a pool with restricted motion (' H,) was observed in tissues in vivo using NMR saturation transfer methods. Exchange between these two pools was demonstrated by a decrease in the steady-state magnetization and rel

## Abstract A molecular theory is presented for the field‐dependent spin‐lattice relaxation time of water in tissue. The theory attributes the large relaxation enhancement observed at low frequencies to intermediary protons in labile groups or internal water molecules that act as relaxation sinks f

It is well established that the longitudinal magnetic relaxation rate of solvent water protons, 1/T1, increases markedly in homogeneous protein solutions as the magnetic field is reduced well below the traditional NMR range. For a 5% solution of protein of 10(5) Da, for example, 1/T1 increases from

The effect of induced field inhomogeneity (IFI) on transverse NMR relaxation of water protons in tissue has been investigated by examining the field dependence of the effective transverse relaxation rates (1/T2 efF) for in vitro canine brain tissue samples. At fields of 0.47, 2.35, 7.05 T (correspon