The objective of the present study was to develop long-acting efavirenz (Efa)−enfuvirtide (Enf) Co-loaded polymer−lipid hybrid nanoparticles (PLN) with improved intracellular delivery to target T-cells and macrophage cells located in multiple human immunodeficiency virus sanctuaries. The Box−Behnken design was utilized to optimize three high-risk factors, namely, Efa amount, sonication time for primary emulsion, and sonication time for aqueous nanodispersion obtained from preliminary studies. Lyophilized Efa−Enf Co-loaded PLN using trehalose elicited spherical morphology, drug amorphization on incorporation, and absence of drugexcipient interaction. In vitro release studies revealed an sustained release of both the drugs from PLN with the differential release profile. Efa−Enf Coloaded PLN exhibited low hemolytic, platelet and leukocyte aggregation as well as low cytotoxicity in Jurkat E6.1 T-cells and U937 macrophage cells. Circular dichroism spectra confirmed the presence of an α-helix form of Enf after encapsulation in PLN. Coumarin-6-loaded PLN exhibited enhanced cellular uptake in Jurkat E6.1 T-cells and U937 macrophage cells in comparison to free coumarin-6, as evidenced by fluorescence microscopy and flow cytometry. In vivo biodistribution studies after intravenous administration of near-infrared dye-loaded PLN (surrogate for Efa−Enf PLN) revealed non-uniform distribution within 2 h in the order of spleen ≥ liver > lymph node > thymus > lungs > female reproductive tract (FRT) > heart > kidneys > brain. However, subcutaneous administration caused non-uniform biodistribution after 3 days, eliciting a long-acting slow release from the injection site depot until day 5 in the infection-spread site (lymph nodes and FRT), reservoir sites (liver and spleen) and the difficult-to-access site (brain). Furthermore, it presents a vital illustration of the available tissue-specific drug concentration prediction from simulated surrogate PLN.
Artemether oily injection is recommended for the treatment of severe malaria by the intramuscular route. The major limitations of the artemisinin combination therapy are erratic absorption from the injection site and high dosing frequency due to a very short elimination half-life of the drug. Advanced drug delivery systems have shown significant improvement in the current malaria therapy; the desired drug concentration within infected erythrocytes is yet the major challenge. Recently, we have reported the fabrication of artemether-loaded polymeric nanorods for intravenous malaria therapy which was found to be biocompatible with THP-1 monocytes and rat erythrocytes. The objective of the present study was the evaluation of pharmacokinetics, biodistribution, and antimalarial efficacy of artemether-loaded polymeric nanorods. Scanning electron microscopy and confocal microscopy studies revealed that both nanospheres and nanorods were adsorbed onto the surface of rat erythrocytes after an incubation of 10 min. After intravenous administration to rats, artemether nanorods showed higher plasma concentration and lower elimination rate of artemether when compared with nanospheres. The biodistribution studies showed that, at 30 min, the liver concentration of DiRloaded nanospheres was higher than that of DiR-loaded nanorods after intravenous administration to BALB/c mice. The in vitro schizont inhibition study showed that both nanorods and nanospheres exhibited concentration-dependent parasitic inhibition, wherein at lower concentrations (2 ppm), nanorods were more effective than nanospheres. However, at higher concentrations, nanospheres were found to be more effective. Nanorods showed higher chemosuppression on day 5 and day 7 than nanospheres and free artemether when studied with the Plasmodium berghei mouse model. Moreover, the survival rate of P. berghei infected mice was also found to be higher after treatment with artemether nanoformulations when compared with free artemether. In conclusion, polymeric nanorods could be a promising next-generation delivery system for the treatment of malaria.
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