Gelatin-Based Hydrogels for Peripheral Nerve Regeneration: A Multifunctional Vehicle for Cellular, Molecular, and Pharmacological Therapy

Peripheral nerve injuries (PNIs) present a significant clinical challenge due to the inherently limited regenerative capacity of the adult nervous system. Conventional therapeutic strategies, such as nerve autografting and systemic pharmacological interventions, are often limited by donor site morbidity, restricted graft availability, and suboptimal drug bioavailability. In this context, gelatin-based hydrogels have emerged as a promising class of biomaterials due to their excellent biocompatibility, biodegradability, and structural similarity to the native extracellular matrix. These hydrogels could offer a highly tunable platform capable of supporting cellular adhesion, promoting axonal elongation, and enabling localized and sustained release of therapeutic agents. This narrative review synthesizes recent advances in the application of gelatin-based hydrogels for peripheral nerve regeneration, with a particular focus on their use as delivery vehicles for neurotrophic factors, stem cells, and pharmacologically active compounds. Additionally, this review provides a foundation for extending our ongoing preclinical study, evaluating the neuroregenerative effects of alpha-lipoic acid, B-complex vitamins, and a deproteinized hemoderivative in a murine PNI model. Although systemic administration has demonstrated promising neuroprotective effects, limitations related to local drug availability and off-target exposure highlight the need for site-specific delivery strategies. In this regard, gelatin hydrogels might represent an excellent candidate for localized, controlled drug delivery. The review concludes by discussing formulation techniques, manufacturing considerations, biological performance, and key translational and regulatory aspects.