Temporary suppression the sequestrated function of host macrophages for better nanoparticles tumor delivery.

Orchestration of nanoparticles to achieve targeting has become the mainstream for efficient delivery of antitumor drugs. However, the low delivery efficiency becomes the biggest barrier for clinical translation of cancer nanomedicines, as most of them are sequestrated in the liver where more macrophages located in are responsible for capture of systemic administrated nanoparticles. In this study, we found that the depletion of the liver macrophages could lead to a superior improvement in the nanoparticles delivery. Firstly, we developed clodronate-containing liposomes (clodrolip) to transiently suppress the phagocytic function of macrophages, the residual macrophages in liver only accounted for less than 1% when the mice were treated with clodrolip in advance. In addition, the pharmacokinetics results of treatment with paclitaxel-poly(lactic-co-glycolic acid) (PTX-PLGA) nanoparticles disclosed that the AUC of PTX in the macrophages depletion group increased 2.11-fold. These results meant that the removal of macrophages would decrease the nanoparticles accumulation in the liver and better the biodistribution and bioavailability of nanoparticles delivery systems. Moreover, treatment of mice with melanoma by the combination of clodrolip and PTX-PLGA nanoparticles resulted in an elevated anti-tumor efficacy, the tumor inhibition ratio was nearly reached to 80%. Furthermore, these combinatorial regimens have demonstrated negligible toxicity in incidence of adverse effects. In conclusion, the encouraging results from this study inspire the generation of a rational strategy to focus on microenvironmental priming for modulation of innate immunity and to improve delivery efficiency of nanoparticles.

Folic acid-functionalized drug delivery platform of resveratrol based on Pluronic 127/D-α-tocopheryl polyethylene glycol 1000 succinate mixed micelles.

A folic acid (FA)-functionalized drug vehicle platform based on Pluronic 127 (P127)/D-α-tocopheryl polyethylene glycol 1000 succinate (TPGS) mixed micelles was orchestrated for an effective delivery of the model drug resveratrol in order to address the problem of poor water solubility and rapid metabolism of resveratrol and improve its targeted accumulation at tumor site. The FA-decorated mixed micelles were prepared using thin-film hydration method and optimized by central composite design approach. The micelles were also characterized in terms of size and morphology, drug entrapment efficiency and in vitro release profile. In addition, the cytotoxicity and cell uptake of the micelles were evaluated in folate receptor-overexpressing MCF-7 cell line. In vivo pharmacokinetic and biodistribution studies were also performed. The average size of the micelles was ~20 nm with a spherical shape and high encapsulation efficiency (99.67%). The results of fluorescence microscopy confirmed the targeting capability of FA-conjugated micelles in MCF-7 cells. FA-modified micelles exhibited superior pharmacokinetics in comparison with that of solution. Further, the low accumulation of resveratrol-loaded FA micelles formulation in the heart and kidney avoided toxicity of these vital organs. It could be concluded that folate-modified P127/TPGS mixed micelles might serve as a potential delivery platform for resveratrol.

Fabrication of an ionic-sensitive in situ gel loaded with resveratrol nanosuspensions intended for direct nose-to-brain delivery.

The objective of this study was to fabricate a composite in situ gelling formulation combining nanoparticulates and an ionic-triggered deacetylated gellan gum (DGG) matrix for challenging intranasal drug delivery. The prepared resveratrol nanosuspensions (Res-NSs) were distributed in DGG solutions. Parameters such as the in situ gelation capability, particle size, rheological properties, and texture profiles were used to describe the properties of the in situ gel. Pharmacokinetic and brain-targeting efficiency studies were performed after intranasal and intravenous administration, respectively. Biodistribution and localization using in vivo imaging systems and fluorescence microscopy are also described. The formulation containing 0.6% w/v DGG displayed a favorable gelling ability and the desired viscosity. The rheology results established that the DGG in situ gel possesses the characteristics of shear thinning, thixotropy and yield stress. The results of the textural profile revealed an increase in adhesiveness and viscosity for the in situ gel compared to the DGG solution. In vitro penetration studies followed a Higuchi mathematic model. Pharmacokinetics revealed a 2.88-times increase of bioavailability in the brain by intranasal Res-NSs in situ gel formulation. The drug targeting efficiency (458.2%) and direct transport percentages (78.18%) demonstrated direct delivery via the nose-brain pathway. The distribution and localization further illustrated the existence of direct nose-to-brain transport, bypassing the BBB. In sum, this hybrid in situ gel system is a promising approach for intranasal application in terms of the enhancement of nasal mucosal permeability and increased nasal cavity residence time by a nanotechnology delivery system and in situ gelling technology.