Exploiting hydrogen bonding to enhance lidocaine loading and stability in a poly ethylene-co-vinyl acetate carrier matrix

Sustained release of lidocaine from poly ethylene-co-vinyl acetate (EVA) implants can significantly improve pain management outcomes; however, poor drug loading is a major limitation. Recently, myristic acid was found to improve drug loading in EVA by inhibiting the crystallization of lidocaine. Here, lidocaine’s interaction with myristic acid was studied by differential scanning calorimetry. Spectra of lidocaine-myristic acid mixtures were analysed using two-dimensional correlation (2DCOS) maps. Furthermore, spectroscopic analysis of EVA matrices containing lidocaine, alone and in combination with myristic acid, was also performed and drug release was evaluated in vitro. A eutectic was obtained on combining lidocaine and myristic acid at the molar ratio of 1:1 due to loss of myristic acid’s dimeric conformation resulting in hydrogen bonding of its COOH group with lidocaine’s amide I moieties. In EVA, hydrogen bonding between adjacent lidocaine molecules caused crystallization above a threshold concentration and could be inhibited by incorporation of myristic acid by eutectic formation. By altering the molecular confirmation and solid state properties of lidocaine in EVA, myristic acid reduces lidocaine crystallization, increases drug loading and influences drug release kinetics. Exploiting these interactions and promoting further hydrogen bonding through the addition of specific excipients presents a viable strategy to enhance and stabilise drug loading in polymer matrices for various applications.