Advanced insight on the water dynamics of anisotropic hydrogels by field-cycling nuclear magnetic resonance: Application of 3-Tau model

Fast field cycling (FFC) nuclear magnetic resonance (NMR) relaxometry is used to investigate an anisotropic polygalacturonate hydrogel formed by the diffusion of calcium ions from an external reservoir (external gela-tion). Such a hydrogel has a gradient of polymer density accompanied by a gradient of the mesh size of its 3D network. The NMR relaxation process is dominated by the interaction of proton spins between water molecules located at polymer interfaces and in nanoporous spaces. The FFC NMR experiment provides the spin-lattice relaxation rate R1(omega) as a function of Larmor frequency omega producing dispersion (NMRD) curves that are high-ly sensitive to the dynamics of the protons at the surfaces. The hydrogel is sliced into three parts and the NMR profile for each hydrogel slice is measured. The NMRD data for each slice is interpreted using the 3-Tau Model with the aid of user-friendly fitting software called 3TM. The key fit parameters include three nano-dynamical time constants and the average mesh size which collectively determine the bulk water and water surface layer contribution to the total relaxation rate. The results are consistent with independent studies where com-parison is possible.

Automated summary

Fast field cycling (FFC) nuclear magnetic resonance (NMR) relaxometry is used to study an anisotropic polygalacturonate hydrogel formed by the diffusion of calcium ions from an external reservoir. The NMR relaxation process is dominated by the interaction of proton spins between water molecules located at polymer interfaces and in nanoporous spaces. FFC NMR experiment provides dispersion (NMRD) curves that are highly sensitive to the dynamics of the protons at the surfaces.