Abstract
Water plays a primary role in the functionality of biomedical polymers such as hydrogels. The state of water, defined as bound, intermediate, or free, and its molecular organization within hydrogels is an important factor governing biocompatibility and hemocompatibility. Here, we present a systematic study of water states in gelatin methacryloyl (GelMA) hydrogels designed for drug delivery and tissue engineering applications. We demonstrate that increasing ionic strength of the swelling media correlated with the proportion of non-freezable bound water. We attribute this to the capability of ions to create ion–dipole bonds with both the polymer and water, thereby reinforcing the first layer of polymer hydration. Both pH and ionic strength impacted the mesh size, having potential implications for drug delivery applications. The mechanical properties of GelMA hydrogels were largely unaffected by variations in ionic strength or pH. Loading of cefazolin, a small polar antibiotic molecule, led to a dose-dependent increase of non-freezable bound water, attributed to the drug’s capacity to form hydrogen bonds with water, which helped recruit water molecules in the hydrogels’ first hydration layer. This work enables a deeper understanding of water states and molecular arrangement at the hydrogel–polymer interface and how environmental cues influence them.
Highlights
Our study confirmed a greater impact of the swelling media over the crosslinking media on the molecular organization of water in gelatin methacryloyl (GelMA) hydrogels
We propose a model of ion–dipole bonding between the ions of the swelling media and both the water molecules and the polymer functional groups
The mechanism underlying the increase of Wnfb at basic pH is likely related to electrostatic repulsion of the deprotonated carboxylic groups, thereby increasing the mesh size, swelling capacity, and overall intake of water
Summary
Since polar or ionic atoms can form non-covalent bonds with water, hydrophilic drugs, when encapsulated in a hydrogel system for drug delivery purposes, may impact the molecular arrangement of water in the system This is especially the case for small drugs that can diffuse throughout the hydrogel matrix and reach the first layer of hydration constituted by Wnfb. Such molecules can interact with both water and the hydrogel, thereby potentially changing the proportional distribution of water states in the system [55]. We performed a systematic study of the effect of a wide range of both ionic strength and pH of the hydrogel swelling media on the water state distribution, swellability, hydrogel mesh size, and the mechanical properties of GelMA hydrogels. We encapsulated a model drug, cefazolin, into GelMA hydrogels to investigate the potential impact of the negatively charged and polar antibiotic on the water state distribution
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