Phenol release from pNIPAM hydrogels: Scaling Molecular Dynamics simulations with Dynamical Density Functional Theory

Abstract

We employed molecular dynamics simulations (MD) and Bennett's acceptance ratio method to compute the free energy of transfer (Delta Gtrans) of phenol, methane, and 5-fluorouracil (5-FU) between bulk water and water-pNIPAM mixtures with different polymer volume fractions (phip). To this end, we first calculate the solvation free energies in both media to obtain Delta Gtrans. Phenol and 5-FU (a drug used in cancer treatment) adsorb onto the pNIPAM surface and exhibit negative values of Delta Gtrans irrespective of temperature, both above and below the lower critical solution temperature (Tc) of pNIPAM. In contrast, methane changes the sign of Delta Gtrans, being positive below and negative above Tc. In all cases, and in contrast with some theoretical predictions, Delta Gtrans shows a linear dependence on pNIPAM concentration up to high polymer densities. We also compute the diffusion coefficient (D) of phenol in water-pNIPAM mixtures as a function of phip in the dilute limit. Both Delta Gtrans and D as functions of phip are key inputs to estimate the release halftime of hollow pNIPAM microgels using dynamic density functional theory (DDFT). Our scaling approach reproduces the experimental value of 2200 s for microgels of 50 micrometer radius without a cavity, at phip approximately 0.83 and 315 K.

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