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This review examines the synthesis methods, properties, and applications of gold nanoparticles, highlighting their significance in biomedicine.

June 18, 2026Open Access

Review of gold nanoparticles: synthesis, properties and applications

Key Points

This review examines the synthesis methods, properties, and applications of gold nanoparticles, highlighting their significance in biomedicine.
Systematic examination of synthesis methods, focusing on pulsed laser ablation in liquid (PLAL) and green biosynthesis.
PLAL analyzed for producing pristine gold nanoparticles between 5–50 nm with eco-friendly attributes.
Comparison of PLAL and biological methods regarding purity, yield, scalability, and multifunctionality.
PLAL demonstrated higher purity and yield over conventional chemical methods for gold nanoparticle synthesis.
Biological methods provided better scalability and multifunctionality, yielding biofunctionalized gold nanoparticles (10–80 nm).
Shape-dependent plasmonic heating was observed, with nanorods achieving temperature increases of 45–55 °C versus 25 °C for spheres, enhancing photothermal therapy efficacy.

Abstract

Gold nanoparticles (AuNPs) exhibit exceptional physicochemical properties, notably localized surface plasmon resonance (LSPR), enabling diverse applications in biomedicine, molecular imaging (CT/PAI/MRI), photothermal therapy (PTT), and targeted drug delivery. This review systematically examines synthesis strategies, emphasizing pulsed laser ablation in liquid (PLAL) as a surfactant-free, eco-friendly “top-down” method producing pristine 5–50 nm AuNPs via plasma plume confinement and cavitation-induced nucleation. Complementary “bottom-up” green biosynthesis leverages plant/fruit extracts (polyphenols/flavonoids), microorganisms, and fungi (nitrate reductase) to yield biofunctionalized AuNPs (10–80 nm) with inherent stability for theranostics. Comparative analyses highlight PLAL’s superiority in purity/yield compared to chemical methods, while biological methods excel in scalability and multifunctionality. Shape-dependent plasmonic heating: nanorods achieve ΔT = 45–55 °C vs. spheres (25 °C), underpinning PTT efficacy. The review elucidates targeting strategies (passive EPR vs. active ligand-receptor), hybrid imaging, and challenges, including EPR heterogeneity, synthesis reproducibility, and clinical translation. Future directions prioritize fs-PLAL optimization, biohybrid architectures, and multimodal AuNP platforms for precision oncology. Graphical abstract

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