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Overcoming drug resistance with a docetaxel and disulfiram loaded pH-sensitive nanoparticle

K. Laxmi Swetha, Milan Paul, Kavya Sree Maravajjala, Soniya Kumbham, Swati Biswas, Aniruddha Roy

2023Journal of Controlled Release35 citationsDOIOpen Access PDF

Abstract

Previous studies have demonstrated that breast cancer cells deploy a myriad array of strategies to thwart the activity of anticancer drugs like docetaxel (DTX), including acquired drug resistance due to overexpression of drug-efflux pumps like P-glycoprotein (P-gp) and innate drug resistance by cancer stem cells (CSCs). As disulfiram (DSF) can inhibit both P-gp and CSCs, we hypothesized that co-treatment of DTX and DSF could sensitize the drug-resistant breast cancer cells. To deliver a fixed dose ratio of DTX and DSF targeted to the tumor, a tumor extracellular pH-responsive nanoparticle (NP) was developed using a histidine-conjugated star-shaped PLGA with TPGS surface decoration ([DD]NpH-T). By releasing the encapsulated drugs in the tumor microenvironment, pH-sensitive NPs can overcome the tumor stroma-based resistance against nanomedicines. In in-vitro studies, [DD]NpH-T exhibited increased drug release at pH 6.8, improved penetration in a 3D tumor spheroid, reduced serum protein adsorption, and enhanced cytotoxic efficacy against both innate and acquired DTX-resistant breast cancer cells. In in-vivo studies, a significant increase in plasma AUC and tumor drug delivery was observed with [DD]NpH-T, which resulted in an enhanced in-vivo anti-tumor efficacy against a mouse orthotopic breast cancer, with a significantly increased intratumoral ROS and apoptosis, while decreasing P-gp expression and prevention of lung metastasis. Altogether, the current study demonstrated that the DTX and DSF combination could effectively target multiple drug-resistance pathways in-vitro, and the in-vivo delivery of this drug combination using TPGS-decorated pH-sensitive NPs could increase tumor accumulation, resulting in improved anti-tumor efficacy.

Topics & Concepts

In vivoDocetaxelPharmacologyCancer researchChemistryTumor microenvironmentDrug resistanceDisulfiramCancerDrug deliveryCancer cellPaclitaxelMetastasisAbcg2MedicineInternal medicineBiologyATP-binding cassette transporterBiochemistryTransporterBiotechnologyGeneMicrobiologyOrganic chemistryNanoparticle-Based Drug DeliveryNanoplatforms for cancer theranosticsCancer, Hypoxia, and Metabolism
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