Magnetophoretic Intranasal Drug-loaded Magnetic Nano-aggregates as a Platform for Drug Delivery in Status Epilepticus

Abstract

BACKGROUND: Status epilepticus is associated with substantial morbidity and neuronal necrosis, and the duration of the seizure would affect its following complications. Eliminating the duration would have valuable outcomes; however, the presence of BBB is an obstacle. The purpose of the current study was to achieve a nose-to-brain magnetic drug delivery system to accelerate the onset of action, and to reduce the mucociliary clearance via implementing the magnetic field. MATERIALS AND METHODS: The drug-entrapped magnetic nanoaggregates were prepared via a 2-step method, synthesis of the magnetic nanoparticles and drug loading. Optimization of the variables, including ammonium hydroxide:water ratio, beta-cyclodextrin, duration of the mixing time, amount of Pluronic, and drug:magnetic nanoaggregates mass ratio was performed according to particle size, PDI, zeta potential, release profile and entrapment efficiency. The efficacy of optimized formulation was assessed in the animal model. RESULTS: According to the analysis performed by the software, drug-to-nanoparticle ratio and the duration of mixing time were found to be significantly effective (p < 0.05) for entrapment efficiency and particle size distribution, respectively. The optimum formulation with an approximate average size of 581 nm and 61 entrapment efficiency was obtained, which released about 80 of its drug content within the first 20 minutes. The in vivo efficacy was significantly improved (p < 0.05) by administration of magnetic nanoaggregates in the presence of a simple external magnet placed on the glabellar region of the animals, compared to the control groups. CONCLUSION: This drug delivery system could be suggested as a fast-acting alternative for seizure cessation in status epilepticus emergencies.