Solid lipid nanoparticles for brain tumors therapy

Engineered Solid Lipid Nanoparticles and Nanostructured Lipid Carriers as New Generations of Blood-Brain Barrier Transmitters

The blood-brain barrier (BBB) is considered as the most challenging barrier in brain drug delivery. Indeed, there is a definite link between the BBB integrity defects and central nervous systems (CNS) disorders, such as neurodegenerative diseases and brain cancers, increasing concerns in the contemporary era because of the inability of most therapeutic approaches. Solid lipid nanoparticles (SLNs) and nanostructured lipid carriers (NLCs) have already been identified as having several advantages in facilitating the transportation of hydrophilic and hydrophobic agents across the BBB. This review first explains BBB functions and its challenges in brain drug delivery, followed by a brief description of nanoparticle-based drug delivery for brain diseases. A detailed presentation of recent progressions in optimizing SLNs and NLCs for controlled release drug delivery, gene therapy, targeted drug delivery, and diagnosis of neurodegenerative diseases and brain cancers is approached. Finally, the problems, challenges, and future perspectives in optimizing these carriers for potential clinical application were described briefly.

Comparative evaluation of intranasally delivered quetiapine loaded mucoadhesive microemulsion and polymeric nanoparticles for brain targeting: pharmacokinetic and gamma scintigraphy studies

Background

Treatment in neurological disorders like schizophrenia requires continuous presence of drug in the brain for a prolonged period of time to achieve an effective therapeutic response. Delivery of antipsychotic drug quetiapine in the form of conventional delivery systems suffers from low oral bioavailability, first-pass metabolism, and frequent dosing. In addition to that biological obstacles present at the brain interface also hinders the transport of quetiapine across the brain. In the present study, nasal delivery of quetiapine loaded nanoparticles and microemulsion formulation were designed to evaluate their individual in vivo potential to achieve brain targeting. Chitosan-based polymeric nanoparticles and mucoadhesive microemulsion systems were developed through ionic gelation and water titration method respectively.

Results

Microemulsion showed globule size lower than 50 nm with 95% drug loading while, nanoparticles exhibited 65% drug loading with particle size of 131 nm. Nasal diffusion study showed highest diffusion with chitosan-based mucoadhesive microemulsion over nanoparticles suggesting permeation-enhancing effects of chitosan. Due to the overall hydrophilic nature, quetiapine-loaded nanoparticles could not diffuse superiorly across nasal mucosa, hence, showed 1.3 times lesser diffusion compared to mucoadhesive microemulsion. Pharmacokinetics in rats showed highest brain concentration and 1.9-folds higher nasal bioavailability with mucoadhesive microemulsion over nanoparticles suggesting direct brain transport through olfactory route bypassing blood-brain barrier.

Conclusion

Higher quetiapine transport with mucoadhesive microemulsion suggested that synergistic effects like tight junction modulation by chitosan and unique composition facilitating smaller globule size could be responsible for higher brain transport. Imaging study by gamma scintigraphy also supported pharmacokinetic outcomes and concluded that mucoadhesive microemulsion could be a promising nanocarrier approach for non-invasive nose to brain delivery.

Graphical abstract

Current strategies for targeted delivery of bio-active drug molecules in the treatment of brain tumor

Brain tumor is one of the most challenging diseases to treat. The major obstacle in the specific drug delivery to brain is blood-brain barrier (BBB). Mostly available anti-cancer drugs are large hydrophobic molecules which have limited permeability via BBB. Therefore, it is clear that the protective barriers confining the passage of the foreign particles into the brain are the main impediment for the brain drug delivery. Hence, the major challenge in drug development and delivery for the neurological diseases is to design non-invasive nanocarrier systems that can assist controlled and targeted drug delivery to the specific regions of the brain. In this review article, our major focus to treat brain tumor by study numerous strategies includes intracerebral implants, BBB disruption, intraventricular infusion, convection-enhanced delivery, intra-arterial drug delivery, intrathecal drug delivery, injection, catheters, pumps, microdialysis, RNA interference, antisense therapy, gene therapy, monoclonal/cationic antibodies conjugate, endogenous transporters, lipophilic analogues, prodrugs, efflux transporters, direct conjugation of antitumor drugs, direct targeting of liposomes, nanoparticles, solid-lipid nanoparticles, polymeric micelles, dendrimers and albumin-based drug carriers.