Abstract
Treatment for Parkinson's disease (PD) has been impeded by inefficient treatment results and multiple membrane barriers during drug delivery. This study reports the design, synthesis, and application of microneedles (MNs) loaded with mitochondrion-targeted liposome encapsulated iron (Fe)-isolated single-atom nanozymes (Mito@Fe-ISAzyme, MFeI), called MFeI MNs, for in situ drug delivery into the brain parenchyma and efficient enrichment of drugs in lesion sites. In in vitro experiments, MFeI can scavenge reactive oxygen species (ROS) and protect the neurons via mitochondrial targeting, guaranteeing the subsequent treatment of PD. Using PD mouse models, we compared the intravenous injection of MFeI with the brain in situ administration of MFeI MNs (in situ MFeI MNs). Results showed that in situ MFeI MNs significantly improved the deep penetration of the drug into brain parenchyma, especially in the vital pathological sites such as the substantia nigra pars compacta and striatum. Importantly, ROS elimination and neuroinflammatory remission in the lesion site were observed, thereby efficiently alleviating the behavioral disorders and pathological symptoms of PD mice. Therefore, the MNs system for in situ single-atom nanozyme liposome delivery exhibits great potential in PD treatment.