Abstract
Cancer, which is a leading cause of death, contributes significantly to reducing life expectancy worldwide. Even though paclitaxel (PTX) is known as one of the main anticancer drugs, it has several limitations, including low solubility in aqueous solutions, a limited dosage range, an insufficient release amount, and patient resistance. To overcome these limitations, we suggest the development of PTX-loaded thermosponge nanoparticles (PTX@TNP), which result in improved anticancer effects, via a simple nanoprecipitation method, which allows the preparation of PTX@TNPs with hydrophobic interactions without any chemical conjugation. Further, to improve the drug content and yield of the prepared complex, the co-organic solvent ratio was optimized. Thus, it was observed that the drug release rate increased as the drug capacity of PTX@TNPs increased. Furthermore, increasing PTX loading led to considerable anticancer activity against multidrug resistance (MDR)-related colorectal cancer cells (HCT 15), implying a synergistic anticancer effect. These results suggest that the solubilization of high drug amounts and the controlled release of poorly water-soluble PTX using TNPs could significantly improve its anticancer therapy, particularly in the treatment of MDR-p-glycoprotein-overexpressing cancers.
Highlights
Accepted: 23 July 2021Cancer is a leading cause of death and a significant contributor to reducing life expectancy worldwide [1]
The TNPs, consisting of a PLA core and a Pluronic F127 shell, as biocompatible polymers approved by the FDA, were successfully prepared using the nanoprecipitation method [23]
Via the optimization of the co-solvent ratios for5 the preparation of PTX-loaded thermosponge nanoparticles (PTX@TNP), the loading amounts and controlled release of PTX were enhanced
Summary
Cancer is a leading cause of death and a significant contributor to reducing life expectancy worldwide [1]. To overcome the MDR effect associated with PTX and enhance its therapeutic index, there is a need for other PTX formulations that show improved solubility in aqueous environments In this regard, numerous carriers, including microspheres, nanoparticles, liposomes, noisomes, PTX-conjugated polymers, and micelles, have been studied to the end of improving the solubility of PTX [5,14,15,16]. In this study, we developed an optimized process for the preparation of PTXloaded thermosponge nanoparticles (PTX@TNPs) to the end of improving the solubility and release kinetics of the poorly water-soluble PTX, via a simple nanoprecipitation method with various ratios of co-organic solvents This resulted in effective chemotherapeutic effects in MDR-related colorectal cancer cells (Figure 1).
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