4.6 Article

Microfluidic Formulation of Curcumin-Loaded Multiresponsive Gelatin Nanoparticles for Anticancer Therapy

Journal

ACS BIOMATERIALS SCIENCE & ENGINEERING
Volume 9, Issue 6, Pages 3402-3413

Publisher

AMER CHEMICAL SOC
DOI: 10.1021/acsbiomaterials.3c00318

Keywords

microfluidics; nanomedicine; anticancer therapy; targeted drug delivery; gelatin nanoparticles; photothermal ablation

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Current anticancer research suggests that combining multiple treatment methods can enhance the killing of tumor cells. In this study, we developed multi-responsive targeted antitumor nanoparticles (NPs) using microfluidic swirl mixer technology. The NPs were made of folate-functionalized gelatin NPs, CuS NPs, Fe3O4 NPs, and curcumin. The results showed that the combination of photothermal-ablation therapy, chemotherapy, and targeted delivery of the NPs efficiently killed tumor cells.
Current anticancer research shows that a combination of multiple treatment methods can greatly improve the killing of tumor cells. Using the latest microfluidic swirl mixer technology, combined with chemotherapy and photothermal-ablation therapy, we developed multi-responsive targeted antitumor nanoparticles (NPs) made of folate-functionalized gelatin NPs under 200 nm in size and with encapsulated CuS NPs, Fe3O4 NPs, and curcumin (Cur). By exploring gelatin's structure, adjusting its concentration and pH, and fine-tuning the fluid dynamics in the microfluidic device, the best preparation conditions were obtained for gelatin NPs with an average particle size of 90 +/- 7 nm. The comparative targeting of the drug delivery system (DDS) was demonstrated on lung adenocarcinoma A549 cells (low level of folate receptors) and breast adenocarcinoma MCF-7 cells (high level of folate receptors). Folic acid helps achieve targeting and accurate delivery of NPs to the MCF-7 tumor cells. The synergistic photothermal ablation and curcumin's anticancer activity are achieved through infrared light irradiation (980 nm), while Fe3O4 is guided with an external magnetic field to target gelatin NPs and accelerate the uptake of drugs, thus efficiently killing tumor cells. The method described in this work is simple, easy to repeat, and has great potential to be scaled up for industrial production and subsequent clinical use.

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