Folic acid-targeted redox responsive polylactic acid-based nanoparticles co-delivering pirarubicin and salinomycin suppress breast cancer tumor growth in vivo

Abstract

Targeted cancer therapy using nanocarriers has emerged as a promising solution to the majority of drawbacks associated with conventional chemotherapy. The present research work describes the development of folic acid (FA)-targeted redox responsive [S-(PLA-b-PEG-CONH)]₂ polymeric nanoparticles for the co-delivery of pirarubicin (Pira) and salinomycin (Sal). The nanoparticles’ redox responsiveness arises from embedded disulfide bonds within the polymer, which gradually break in response to high GSH levels in tumors, enabling sustained drug release. The nanoparticles exhibited a hydrodynamic size of ∼104 nm and a surface charge density of −15.5 mV with low PDI values. Blank nanoparticles (w/o drug) showed negligible toxicity towards both non-malignant human and murine cells and exhibited excellent stability under different environmental conditions for up to 3 weeks. A cellular internalization study conducted using Rho B/C6 dual-dye-encapsulated nanoparticles showed efficient uptake of the nanoparticles after just 1 hour of incubation with SUM-149 2D adherent cells and 3D spheroids. The release of Pira and Sal from Pira/Sal dual-loaded nanoparticles increased significantly in a reducing environment. The % cumulative release of Pira increased from 20.5% ± 1.0 in PBS (pH 7.4) to 40.1% ± 0.4 in dithiothreitol (DTT) after 20 days; similarly, the % cumulative release of Sal increased from 36.2% ± 1.7 in PBS (pH 7.4) to 51.5% ± 1.7 in DTT. The cytotoxicity studies of FA-targeted Pira/Sal dual-loaded nanoparticles with varying Pira : Sal ratios (1 : 1, 3 : 1 and 1 : 3) revealed that the nanoparticles displayed 8–10 fold lower IC₅₀ values than the respective free drug formulations across multiple breast cancer cell lines including SUM-149, MDA-MB-231 and EAC as well as in 3D mammospheres. Balb/c syngeneic mice bearing EAC tumors experienced ∼100% tumor regression upon treatment with FA-targeted Pira/Sal (3 : 1) dual-loaded nanoparticles, indicating synergistic anti-tumor potency. In vivo survival and histopathological studies indicated no significant toxicity in vital organs of the body as compared to free drugs. Based on the performance, the currently investigated FA-targeted Pira/Sal dual-loaded nano-formulation is recommended to be further explored in other cancer types as well as in higher animals for cancer therapy.