Gemcitabine Co-Encapsulated with Curcumin in Folate Decorated PLGA Nanoparticles; a Novel Approach to Treat Breast Adenocarcinoma.

PURPOSE: Curcumin (CUR), an antioxidant with p-glycoprotein inhibiting activity may be encapsulated with gemcitabine (GEM) as nanosuspension to enhance its anticancer potentiality synergistically. METHODS: Folate conjugated single (CUR/GEM) and dual (CUR + GEM) drug-loaded nanoformulations were prepared and evaluated for P-glycoprotein-1 (pgy-1) gene resistance, followed by in vitro cellular uptake and cytotoxicity assay in cells. The in vivo biodistribution and scintigraphic imaging was done after radiolabeling the nanoparticles with 99mTechnetium (99mTc). The tumor inhibition study was conducted in nude mice bearing MDA-MB-231 xenografts. RESULTS: The folate conjugated dual drug formulations (FCGNPs) gave better results in suppressing the pgy-1 gene and also showed higher cellular uptake, cytotoxicity, apoptosis, and cell cycle arrest. The radiolabeled nanoformulations were highly stable and FCGNPs showed higher accumulation in the MDA-MB-231 tumor region than folate unconjugated dual drug NPs (CGNPs) as evidenced by scintigraphic imaging and biodistribution studies. The in vivo therapeutic efficacy of FCGNPs was higher compared to unconjugated and respective single-drug formulations. CONCLUSION: Two drugs in one platform lower breast adenocarcinoma by lowering drug resistance and improving cytotoxic effects.

[Pharmacokinetics and brain distribution of NMD/TMP-nanoparticles].

This study aims to prepare nimodipine/tetramethylpyrazine-loaded poly(D, L-lactide-co-glycolide) dual-drug nanoparticles (NMD/TMP-NPs) and investigate pharmacokinetics and brain distribution to evaluate the possibility of enhancing the drug effect of dual-drug nanoparticles. NMD/TMP-NPs were prepared via W/O/W emulsion solvent evaporation. Entrapment efficiency and drug loading of NMD/TMP-NPs were investigated by ultracentrifugation, and drug release behavior in vitro was studied by dialysis method. The pharmacokinetic and brain distribution were studied in SD mice administered intravenously with NMD/TMP-NPs in comparison with NMD-suspension, NMD/TMP-suspension and NMD-NPs, (NMD-NPs+TMP)-suspension. According to the results, the entrapment efficiency and drug loading of NMD were (79.71±0.73)%, (1.74±0.02)%, those of TMP were (40.26±1.51)% and (4.38±0.16)%. The nanoparticles showed the property of sustained release. On the basis of the major parameters for in vivo pharmacokinetic and brain distribution, t1/2ß of NMD-suspension, NMD/TMP-suspension and NMD-NPs, (NMD-NPs+TMP)-suspension, NMD/TMP-NPs were (1.097±0.146), (1.055±0.06), (1.950±0.140), (1.860±0.096), (2.497±0.475） h, CL were (0.778±0.098), (1.133±0.111), (0.247±0.023), (0.497±0.040), (0.297±0.024) h•L-1, AUC0-t in rat plasma were (514.218±60.383), (352.916±33.691), (1 618.429±240.198), (804.110±75.804), (1 349.058±215.497) µg•h•L⁻¹, respectively, and AUC0-t in brain were 0.301 9, 0.624 8, 1.068 6, 1.313 0, 1.046 5 mg•h•L⁻¹, respectively. According to the in vivo study, the pharmacokinetic behavior of NMD were markedly prolonged by adding TMP or prepared dual-drug nanoparticles.

Synergistically Enhanced Therapeutic Effect of a Carrier-Free HCPT/DOX Nanodrug on Breast Cancer Cells through Improved Cellular Drug Accumulation.

We are interested in developing systems for simultaneous delivery of two or more chemotherapeutic agents. Simple physical mixing of drugs may reduce the therapeutic effect and cause unexpected or even dangerous side-effects. For example, when 10-hydroxycamptothecin (HCPT) and doxorubicin (DOX) injection solutions are mixed, the curative effect is actually reduced in clinical practice. In this study we demonstrated that when HCPT and DOX are combined into a single nanoparticle, their toxicity to tumor cells in vitro is synergistically enhanced. We used a simple and "green" reprecipitation method to successfully create a carrier-free dual-drug delivery system by self-nanocrystallization of the drug molecules. When HCPT and DOX were coassembled, they formed small, spherical nanodrug particles with a positive surface charge. Cellular uptake of HCPT was improved and nuclear accumulation increased as much as 1.57-fold in comparison to HCPT alone. The carrier-free HCPT/DOX nanoparticles demonstrated enhanced synergistic cytotoxicity against breast cancer cells in vitro, while an antagonistic effect was observed when HCPT and DOX were directly mixed at high concentration.