Integrated Computational and Experimental Design of Copper–Gallic Acid Nanozymes for Selective Salbutamol Detection

Integrated Computational and Experimental Design of Copper–Gallic Acid Nanozymes for Selective Salbutamol Detection Publisher

Parad F ; Ghasemi F ; Khadivparsi P ; Al Amili H ; Keramati P ; Mojtabavi S ; Faramarzi MA

Source: Molecular Systems Design and Engineering Published:2025

Abstract

Salbutamol (SBM), a β2-adrenergic agonist commonly prescribed for bronchospasm, is increasingly monitored in sports medicine due to its potential misuse as a performance-enhancing agent. To address the need for rapid, cost-effective, and portable anti-doping diagnostics, a nanozyme-based sensing platform using copper–gallic acid hybrid structures (Cu@GA·HSs) was developed. These nanozymes exhibited oxidase-like activity, enabling sensitive and selective optical detection of SBM across a wide concentration range (125–5000 μg mL−1), with excellent analytical accuracy (96.8–99.8%) and precision (CV < 2.0%). The system demonstrated strong operational stability, retaining 60% catalytic activity after 24 days at 4 °C, and strong resistance to chemical interference, including metal ions and non-polar solvents (selectivity coefficient ≈1). Benchmarking against HPLC revealed excellent agreement (R2 = 0.997; deviation <0.06%), validating its analytical performance. Molecular docking and dynamics simulations further revealed specific SBM–matrix interactions underlying the sensor's selectivity and robustness. Together, these results highlight a systems-level approach integrating nanozyme chemistry with computational modeling to engineer next-generation biosensors for anti-doping applications. This journal is © The Royal Society of Chemistry, 2026

Style	Citing Format
MLA	Parad F, et al.. "Integrated Computational and Experimental Design of Copper–Gallic Acid Nanozymes for Selective Salbutamol Detection." Molecular Systems Design and Engineering, vol. 11, no. 1, 2025, pp. 70-84.
APA	Parad F, Ghasemi F, Khadivparsi P, Al Amili H, Keramati P, Mojtabavi S, Faramarzi MA (2025). Integrated Computational and Experimental Design of Copper–Gallic Acid Nanozymes for Selective Salbutamol Detection. Molecular Systems Design and Engineering, 11(1), 70-84.
Chicago	Parad F, Ghasemi F, Khadivparsi P, Al Amili H, Keramati P, Mojtabavi S, Faramarzi MA. "Integrated Computational and Experimental Design of Copper–Gallic Acid Nanozymes for Selective Salbutamol Detection." Molecular Systems Design and Engineering 11, no. 1 (2025): 70-84.
Harvard	Parad F et al. (2025) 'Integrated Computational and Experimental Design of Copper–Gallic Acid Nanozymes for Selective Salbutamol Detection', Molecular Systems Design and Engineering, 11(1), pp. 70-84.
Vancouver	Parad F, Ghasemi F, Khadivparsi P, Al Amili H, Keramati P, Mojtabavi S, et al.. Integrated Computational and Experimental Design of Copper–Gallic Acid Nanozymes for Selective Salbutamol Detection. Molecular Systems Design and Engineering. 2025;11(1):70-84.
BibTex	@article{ author = {Parad F and Ghasemi F and Khadivparsi P and Al Amili H and Keramati P and Mojtabavi S and Faramarzi MA}, title = {Integrated Computational and Experimental Design of Copper–Gallic Acid Nanozymes for Selective Salbutamol Detection}, journal = {Molecular Systems Design and Engineering}, volume = {11}, number = {1}, pages = {70-84}, year = {2025} }
RIS	TY - JOUR AU - Parad F AU - Ghasemi F AU - Khadivparsi P AU - Al Amili H AU - Keramati P AU - Mojtabavi S AU - Faramarzi MA TI - Integrated Computational and Experimental Design of Copper–Gallic Acid Nanozymes for Selective Salbutamol Detection JO - Molecular Systems Design and Engineering VL - 11 IS - 1 SP - 70 EP - 84 PY - 2025 ER -

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