Editorial: Nanomedicine targeting central nervous system

This study explores the recent advances in intranasal drug delivery and focuses on the cutting-edge nose-to-brain (N2B) approach, its advantages over conventional therapy, and its limitations (Kisku et al.). The manuscript underscores the necessity of prolonged therapeutic interventions in cases of neuropsychiatric conditions and how the application of nanomedicine-based targeted drug delivery offers a compelling solution to facilitate site-directed, sustained-drug release, improved pharmacokinetics and enhanced BBB penetration efficiency and efficacy for CNS disorders. Apart from discussing technical advances, this article expands current understanding of CNS drug delivery by evaluating formulation strategies designed to achieve sustained release, improve pharmacokinetics, and extend therapeutic residence time in the brain. Importantly, it also raises timely questions regarding the long-term safety and clinical translatability of intranasal nanoformulations for the treatment of neuropsychiatric disorders.This manuscript evaluates nanotechnology-based approaches for the management of Parkinson's disease (Yadav et al.). It underlines the limitations of current treatment options available to curb and treat Parkinson's symptoms, including surgical methods and receptor-based pharmacological therapies using small molecules. The emphasis is laid on employing nanocarriers like carbon nanotubes, metallic nanoparticles, polymeric and lipid-based nanoparticles, including dendrimers and solid-lipid nanoparticles, to improve therapeutic delivery and achieve better clinical outcomes. This article draws attention to emerging disease-specific nanocarriers and their ability to overcome the limitations of receptor-based therapies and invasive surgical treatment procedures. It further emphasizes the integration of diagnostic and therapeutic interventions to aid early disease prediction and precision-guided therapy, while underscoring the need for longitudinal in vivo validation and patient-specific drug delivery approaches.This review article briefly summarizes the potential of nanotechnology-based platforms for neurodegenerative disorders using nanotherapeutics (Dhariwal et al.). It highlights how advanced nanomedicine approaches can enhance penetration through the BBB and improve transport of therapeutic agents such as GM-CSF to disease-relevant sites. These strategies offer promising avenues to overcome current challenges associated with the treatment of progressive neurodegenerative disorders, such as Huntington's diseases Alzheimer's, and Parkinson's. The salient features discussed in this article revolves around immune-modulatory cargo delivery and its potential to support disease-modifying, rather than merely symptomatic, therapeutic strategies, while prompting future investigations into combinatorial nanoformulations and smart, responsive delivery systems tailored to disease exacerbation and progresssion.This narrative systematic review analysis underscores the imperative need for machine learning, deep learning and artificial intelligence to modulate nanomedicine therapy (Dipankar et al.). It offers critical insights into the design and fabrication of nanomedicine using computational methods to accelerate disease diagnosis and biomarker identification for better management of brain cancer, as well as neurodegenerative disorders, including multiple sclerosis, Parkinson's disease, and Alzheimer's disease. This article meaningfully extends the emerging role of artificial intelligence (AI) beyond formulation design, positioning AI as an integrative platform for biomarker discovery, predictive modelling, and optimization of therapeutic interventions. It further highlights critical future needs for data standardization, regulatory frameworks, and real-world clinical integration of AI-guided nanotherapeutic interventions.Exosomes are extracellular vesicles capable of delivering drugs to target sites and are being comprehensibly explored to target brain to improve the therapeutic efficiency of drugs, especially in brain cancers, due to their endogenous origin, excellent biocompatibility, high drug-loading capacity, and BBB penetration potential (Mohiyuddin et al.). This review article summarizes the enhanced efficiency of drug-loaded/ functionalized exosomes in crossing the BBB, efficient cellular-uptake and their remarkable ability in treating brain cancers and their applications in disease diagnosis and theragnostic. The key strength of this article is its emphasis on the shift from synthetic to endogenous, cell-based delivery carriers with theragnostic potential, while drawing attention to strategies for enhancing BBB penetration and minimizing immunogenic responses. The article also acknowledges unresolved challenges related to cargo heterogeneity, regulatory considerations, and scalability, all of which are critical for successful clinical translation.This review article discusses targeted brain delivery using nanodrug-delivery systems, including polymeric micelles, dendrimers, and liposomes to improve the clinical outcomes in neurodegenerative disorders (Kumar et al.). It also highlights, how fabricated nanodrug delivery platforms results in enhanced bioavailability and biocompatibility, and nanosizing leads to large surface area and offers tunable properties, involving functionalization with small molecules, antibodies, nucleic acids, and peptides, rendering these nano-delivery systems excellent carriers for therapeutic interventions in gene therapy. This article advances the field of gene therapy and multifunctional, immune-compatible nanoplatforms, thereby extending the scope of nanomedicine beyond conventional small-molecule delivery. It also outlines future directions and emerging trends, include tailored functionalization, controlled regulation of gene expression, and comprehensive biosafety evaluations.Collectively, these articles demonstrate the evolving landscape of nanomedicine and provide a proof-of-concept drug delivery approach to integrate smart and biologically informed platforms capable of transforming CNS disease diagnosis, mitigation and treatment. This special issue also underscores a paradigm shift in brain-targeting using nanomedicine using computationally optimized therapeutic systems to circumvent physical delivery barriers and lead to biologically responsive precision-medicine. Future research needs to be more focused on prioritizing the enhancement of safety and efficacy profile, increasing the scalability and regulatory standardization of advanced nanocarriers, and integration of artificial intelligence to render personalized therapy, realtime disease modelling and treatment optimization. Tackling these incumbent challenges using interdisciplinary teamwork will be crucial to translating these nanomedicine-based interventions from bench to clinically viable solutions with positive effect on patient care.