Abstract
BACKGROUND AND PURPOSE: The delivery of therapeutics to the central nervous system (CNS) remains a major challenge due to the restrictive nature of the blood-brain barrier (BBB), a key evolutionary feature that preserves brain homeostasis. This review seeks to synthesize current knowledge on BBB composition, physiology, and transport mechanisms, and critically analyses drug delivery strategies aimed at overcoming this barrier and enabling effective CNS therapies. APPROACH: We conducted a comprehensive narrative review integrating evidence on BBB anatomy, transport and permeability mechanisms, drug delivery optimization strategies, with a particular focus on nanotechnology-based systems, and preclinical evaluation models. KEY RESULTS: We highlight how a deeper understanding of BBB architecture and dynamic regulation can inform rational design of targeted strategies. Drug delivery approaches are summarized and compared, with emphasis on the potential of nanotechnology-based platforms to enhance CNS drug delivery. Translational considerations, including scalability, reproducibility, and regulatory requirements, are critically addressed. Major challenges identified include receptor saturation, competition with endogenous ligands, disease-specific variability in BBB permeability, and the limited predictive value of current preclinical models. Emerging tools, such as organ-on-chip (for evaluation) and microfluidic mixing (for manufacturing nanomaterials), offer promising means to improve physiological relevance and accelerate translation. CONCLUSION: Progress in BBB research has laid the groundwork for innovative therapies, but significant hurdles remain. Advancing CNS drug delivery will require collaborative work refining transport-targeting mechanisms, developing standardized preclinical models, and integrating fundamental research, applied nanomedicine, and regulatory science to open new opportunities for treating neurological and psychiatric disorders and brain tumours.