RESUMO
Applying nanotechnology to design drug delivery systems is a promising turning point in cancer treatment strategies. In the current study, Lawson, a nonpolar anticancer phytochemical, was entrapped into ß-cyclodextrin polymer to evaluate its selective cytotoxicity in several types of human cancer cell lines including MCF-7, AGS, A549, and PC3. The Lawson-loaded ß-cyclodextrin nanocarriers (LB-NCs) were produced by applying a high-energy ultrasound-mediated homogenization technique. The LB-NCs were characterized by applying dynamic light scattering (DLS), Fourier transform infrared spectroscopy (FTIR), zeta potential, and field emission scanning electron microscopy (FESEM) analysis. Also, the selective cytotoxic impact of the LB-NCs was studied by conducting the MTT assay on human MCF-7, AGS, A549, and PC3 cancer cell lines. Finally, the type of cellular death was evaluated by measuring the cell cycle status and apoptotic gene expression profile of the treated MCF-7 cells by conducting flow cytometry and Q-PCR methods, respectively. The synthesized negatively charged (- 23.8 mV) nanoparticles (348.12 nm) exhibited apoptotic activity in the human breast MCF-7 cancer cells by upregulating the apoptotic gene expression profile (Caspase 3, 8, and 9). The LB-NCs exhibited a significant selective cytotoxic effect on the human cancer cell lines compared with the normal HUVEC cells. However, variable toxic intensities were detected depending on the cancer cell type. Selective cancer cell-depended anticancer activity of the produced LB-NCs has the potential to be considered their safe efficient targeted anticancer activity. However, studying the animal cancer models has to be conducted to verify their selective toxicity and clarify the cellular death mechanism.