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Abstract

The rational design of biofunctional nanocomposites through structural and interfacial engineering is central to advancing next-generation biomaterials. In this study, we developed a multifunctional silver-based nanocomposite with dual-level modification; albumin (Alb) is used as a biopolymeric stabilizer, while Elettaria cardamomum extract, rich in alpha-terpinyl acetate (aTA), served as a surface-functionalizing agent. Gas chromatography–mass spectrometry (GC-MS) confirmed aTA as the predominant phytoconstituent (97.7% match). Dynamic light scattering revealed progressive size increases from 67.17 nm (AgNPs) to 145.73 nm (Alb-AgNPs) and 365.7 nm (Alb-AgNPs-aTA), indicating successful stepwise functionalization. Structural transformations were supported by UV–Vis spectroscopy and X-ray diffraction (XRD), which revealed changes in surface plasmon resonance and crystalline phases. Thermal analysis (DSC and TGA) demonstrated improved thermal stability, with a pronounced DTG peak at 333.2°C. Molecular dynamics simulations suggested strong Alb–aTA interactions that enhance nanocomposite stability. In vitro assays on HCT-116 colorectal cancer cells showed improved biocompatibility and anticancer efficacy for Alb-AgNPs-aTA (IC₅₀ = 24 µg/mL). This study presents a thermally stable, structurally engineered nanocomposite with demonstrated bioactivity and potential applicability in drug delivery and cancer therapy, contributing to the broader understanding of how nanoscale modifications influence biological performance.

Keywords

Silver nanoparticles Alpha terpinyl acetate Biofunctional nanocomposites Design of experiments (DOE)

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Structurally engineered silver-albumin nanocomposites functionalized with alpha-terpinyl acetate for enhanced biocompatibility and anticancer activity

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