This study aimed to fabricate a curcumin@platinum nanohybrid (CUR@Pt NPs) through a green tea–based synthesis method and to evaluate its various functions, including antioxidant, burn-healing, and selective anticancer activities against PANC-1 pancreatic cancer cells. Green tea polyphenols served as natural reducing and stabilizing agents, facilitating an eco-friendly, single-step manufacturing process. Physicochemical characterization confirmed successful nanohybrid formation: a CUR@Pt band appeared at 457 nm in the UV–Vis spectrum, XRD displayed crystalline platinum peaks at 2θ = 46.9°, and 67.0°, matching the (200), and (220) planes, respectively, and TEM images showed well-dispersed spherical nanoparticles with an average size of 50 nm. FTIR spectra showed shifts in O–H and C = O vibrational bands, indicating coordination between curcumin, tea polyphenols, and platinum. DLS analysis indicated a hydrodynamic diameter of 162.2 ± 12.8 nm, with a zeta potential of − 5.6 mV. Antioxidant assessment using the DPPH assay revealed that CUR@Pt NPs had enhanced radical-scavenging activity with an IC₅₀ of 17.58 ppm, compared to 22.45 ppm for free curcumin. In vivo burn-healing tests in mice demonstrated faster wound contraction, with the CUR@Pt group achieving significantly improved closure by day 14, along with increased re-epithelialization and dense collagen deposition similar to silver sulfadiazine (1%). Cytotoxicity assays showed selective anticancer effects against PANC-1 cells (IC₅₀ = 89.4 µg/mL), while normal NIH cells displayed higher tolerance (IC₅₀ = 119.8 µg/mL), indicating a favorable therapeutic index. In conclusion, CUR@Pt NPs are a promising, environmentally friendly nanoplatform that combines the complementary pharmacological effects of curcumin and platinum.
