P.A. Haro et al. Engineering Poly(lactic Acid)-Based Scaffolds for Abundant, Sustained, and Prolonged Lactate Release. ACS Polymers Au

P.A. Haro Gutiérrez, S. Colombi, J. Casanovas, J. Casanovas, L. Resina, J. Sans, E. Engel, H. Enshaei, J. García-Torres, M.M. Pérez-Madrigal, C. Alemán. Engineering Poly(lactic Acid)-Based Scaffolds for Abundant, Sustained, and Prolonged Lactate Release. ACS Polym. Au 2025, 5, 247−260. OPEN ACCESS.

doi: doi.org/10.1021/acspolymersau.4c00097

Abstract

Recent studies have revealed that cardiac tissue regeneration is promoted by administering an initial dose of exogenous lactate and locally maintaining an abundant concentration of this compound for a prolonged period (i.e., around 10–14 days) through sustained release. The aim of this study is to develop a scaffold based on poly(lactic acid) (PLA) for achieving a sustained daily release of lactate from the first day to the end of the recommended period. First, a five-layered electroresponsive scaffold has been engineered using three PLA layers (first, third, and fifth), each composed of electrospun microfibers (MFs), separated by spin coated lactate (second) and poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS) (fourth) intermediate layers. The hydrophobicity of the outer PLA layers (first and fifth) has been used to maintain the release of lactate from the intermediate second layer over 3 days, while the conducting fourth PEDOT:PSS layer has ensured a complete lactate release by electrostimulation. After that, in a second step, the same scaffold has been re-engineered to maintain the sustained release not only for a short period (3 days) but also for a prolonged period (>10 days). For this purpose, the PLA MFs of the intermediate third layer have been substituted by plasma-treated proteinase K-containing PLA MFs, obtained by electrospinning a PLA:enzyme mixture. The activity of the enzyme, which decomposes the ester bonds of PLA, combined with the effect of the plasma on the PLA structure, results in a prolonged sustained release that, in addition, can be modulated.