Implants offer the opportunity to improve patient adherence and real-world outcomes. However, most polymers used today are hydrophobic and limit drug properties suitable for development. Thermoplastic poly(urethanes) (TPUs) form pores upon hydration and may facilitate the development of implants containing drugs exhibiting broadly different properties. We sought to investigate the effect of drug physicochemical properties on permeability through membranes of varying TPU mixture composition; leverage imaging to visualize microstructural changes to the membrane across the TPU mixture composition range; and quantitatively characterize the membrane microstructure using equivalent pore analysis. We observed a correlation between drug hydrophobicity and its permeability through hydrophobic-rich TPU membranes. Conversely, all compounds diffused through hydrophilic-rich TPU membranes at similar rates, regardless of drug properties. Imaging revealed significant microstructure differences between hydrophobic-rich and hydrophilic-rich TPU membranes, supporting hypotheses proposed in our previous study. The hydrated hydrophilic TPU membrane pore area was determined to be 0.583% and its equivalent pore radius was found to be 128 nm, suggesting that hydrophilic TPU membranes may be used to modify the release of small molecular weight drugs and macromolecules. These findings highlight the benefits of hydrophilic TPUs as rate-controlling membranes to modulate the release rate of drugs with varying physicochemical properties.
Keywords: Atomic force microscopy; Implant; Membrane; Poly(urethane); Polyurethane; Sustained release; TPU.
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