Nanotechnology has been rapidly advancing across diverse fields, including medicine, engineering, bioremediation, pharmacy, and cosmetics [1, 2]. Nanoparticles offer significant advantages, primarily due to their unique physicochemical properties, such as a high surface area-to-volume ratio [3]. These properties have facilitated the integration of numerous commercial nanoparticles into various industries. The global nanotechnology market was valued at $76 billion in 2020 and is projected to reach $170 billion by 2026 [4]. Among these, silver nanoparticles (AgNPs) are extensively employed, particularly for their remarkable antimicrobial properties. AgNPs can be synthesized via three main methods: chemical, physical, and biological. Among these, the biological approach, often termed green synthesis, is the most cost-effective and environmentally sustainable method [5]. Biological synthesis utilizes various natural resources, including plants, microorganisms, and algae, with plant extract-mediated synthesis being especially favored due to its simplicity, time efficiency, cost-effectiveness, and the absence of toxic by-products [6].

Before the discovery of the first antibiotic, penicillin, silver and colloidal silver were widely utilized to treat various infections and preserve crops, food, wine, and water [7]. The advancement of nanotechnology has facilitated the development of nanoscale silver particles, which demonstrate significantly enhanced chemical, physical, and biological properties [8]. Numerous studies have investigated the antimicrobial activity of AgNPs. For instance, AgNPs synthesized using Madhuca longifolia leaf extract demonstrated significant inhibitory effects on the growth of Bacillus cereus, Staphylococcus saprophyticus, Escherichia coli, and Salmonella typhimurium in a concentration-dependent manner [9]. Similarly, AgNPs synthesized using Salix viminalis leaf extract exhibited significant inhibitory effects against E. coli and Staphylococcus aureus [10]. Another study reported that green synthesized AgNPs effectively inhibited the growth of six different phytopathogenic fungi species, even at low concentrations [11]. Previously, green synthesized AgNPs via Laurus nobilis L. extract have presented an effective control for soft rot disease factor Pectobacterium carotovorum in pepper [12]. Collectively, these findings suggest that green synthesized AgNPs could serve as a new generation of antimicrobial agents.

Many plant species are highly susceptible to a diverse array of pathogens, including viruses, bacteria, fungi, and other microorganisms, which can severely compromise plant growth and significantly reduce crop yield [13]. Traditional management strategies to combat these pathogens have primarily relied on pesticide application, which has been widely adopted due to its effectiveness in disease control. However, increasing concerns regarding the environmental and health impacts of pesticide use—such as soil degradation, water contamination, and adverse effects on non-target organisms—have prompted the search for more sustainable and eco-friendly alternatives [14]. Recent advancements in nanotechnology and biopesticides present promising opportunities for improved disease management. The development of plant-based nanomaterials and natural antimicrobial agents provides innovative solutions that mitigate the adverse effects associated with traditional pesticide use [15].

Verticillium dahliae, a notorious soil-borne pathogen, inflicts severe damage on numerous plant species by causing wilting disease. Remarkably, this pathogen can persist in the soil for prolonged periods, even in the absence of a host plant [16]. Once it infects a plant, V. dahliae disrupts the water transport system by blocking the xylem vessels, which results in wilting and subsequent tissue necrosis [17]. Despite its significant impact on crop health and yield, there are currently no effective chemical control measures available for managing this disease. This highlights the critical need for alternative strategies, including the development of resistant plant varieties and innovative biological control approaches. Green synthesized AgNPs have demonstrated significant potential in agricultural applications. For instance, AgNPs derived from Melia azedarach leaf extracts have exhibited strong antifungal properties, effectively targeting V. dahliae and enhancing growth in Solanum melongena [18]. Similarly, a paracetamol-silver nanocomplex achieved over 80% inhibition against various fungal pathogens, further emphasizing the potential of silver-based nanomaterials as sustainable alternatives for pest management and crop improvement [19].

Recent research has increasingly highlighted the importance of integrated pest management strategies, which combine biological control, cultural practices, and the use of resistant plant varieties to reduce reliance on chemical pesticides. In this study, AgNPs were green synthesized using L. nobilis leaf extract. The synthesized AgNPs were characterized through UV-VIS spectroscopy, FTIR spectroscopy, SEM, and zeta potential and particle size analysis (PSA). The in vitro antifungal activity of the AgNPs was evaluated against V. dahliae, the causative agent of wilting disease. This research indicates that AgNPs have the potential to play a crucial role in the development of novel antifungal formulations, offering a promising alternative to traditional chemical treatments.

In the present study, the aqueous leaf extract of laurel facilitated the reduction of silver ions from AgNO₃ to AgNPs. Over the past two decades, AgNPs have been utilized as antimicrobial agents, demonstrating notable efficacy against bacterial species [20]. However, their effectiveness against fungal species appears to be comparatively lower, which may be attributed to the protective role of chitin in the fungal cell wall, which offers a defense mechanism against elemental silver (Ag⁰). The reduction of AgNO₃ to AgNPs using L. nobilis leaf extract follows a complex mechanism primarily driven by the plant’s phenolic compounds. These compounds, including flavonoids, tannins, and other polyphenolic substances, possess strong reducing properties due to their hydroxyl groups, which can donate electrons to silver ions (Ag⁺). This electron transfer reduces Ag⁺ to elemental silver (Ag⁰), leading to the formation of nanoparticles [21]. Concurrently, the phenolic compounds act as stabilizing agents, preventing nanoparticle aggregation by capping the surface of the formed AgNPs. The hydroxyl groups of phenols form a protective layer around the nanoparticles, thus maintaining their stability and uniformity in size.

UV-VIS spectroscopy revealed characteristic SPR peak between 400 and 450 nm, indicative of the SPR of AgNPs. This observation, along with the color change of the reaction mixture, confirms the reduction of Ag⁺ ions to Ag⁰ facilitated by the natural phytomolecules in L. nobilis leaf extract [9, 22]. Additionally, no significant color change or agglomeration of the green synthesized AgNPs was observed even after ten weeks, indicating their stability over time.

The FTIR spectrum revealed significant peaks, with the band at 3,272 cm^–1 corresponding to O–H stretching, indicative of hydrogen bonds commonly found in natural compounds such as alcohols, flavonoids, or phenols [23]. The band at 2,140 cm^–1 indicates the presence of alkyne groups [24], while the peak at 1,640 cm^–1 corresponds to C=C stretching in aromatic compounds [25], suggesting that the phytochemical components of L. nobilis extract capped the AgNPs. Furthermore, the bands at 1,524 cm^–1 (C–H stretching in alkenes and aromatic compounds) and 1,199 cm^–1 (C–O stretching in phenolic compounds) were absent in the AgNP spectrum, confirming that AgNO₃ was effectively reduced without aggregation, due to the presence of phenolic compounds in the laurel extract [26].

Zeta-size and potential analyses were employed to determine the size, distribution, and stability of the nanoparticles. The PdI value confirmed that the AgNPs were monodispersed. Additionally, the zeta-potential analysis indicated the stabilization of negatively charged AgNPs. A zeta-potential value lower than –14 mV suggests effective prevention of agglomeration, ensuring the stabilization of AgNPs in solution [27]. Zeta-size analysis typically measures larger particle sizes than SEM due to its capacity to analyze millions of particles, providing more robust data on size distribution and PdI.

Green synthesized AgNPs demonstrated significant inhibition of V. dahliae mycelial growth, showing marked suppression compared to the control group. Similarly, green synthesized AgNPs using M. azedarach leaf extract have been reported to inhibit V. dahliae growth [18]. Our findings are consistent with previous studies reporting inhibition of other plant pathogens, including Macrophomina phaseolina, Alternaria alternata, Rhizoctonia solani, and Fusarium oxysporum [28, 29]. The biosynthesis of AgCl nanoparticles using Aspergillus terreus demonstrated strong antimicrobial activity against pathogenic microorganisms such as Fusarium oxysporum and V. dahliae [30]. On another study, AgNPs synthesized from Citrus maxima peel extract exhibited significant antioxidant properties and effectively inhibited the growth of V. dahliae [31]. The antifungal mechanism of AgNPs likely involves disruption of membrane integrity [32], allowing silver ions to penetrate the intracellular matrix [33]. This mechanism of AgNPs may also involve electrostatic interactions between silver ions and negatively charged cell membranes, leading to increased membrane permeability, oxidative stress, and the inactivation of enzymes and ribosomal complexes, as well as disruption of mitochondrial and chromatin structures [34]. AgNPs may also interfere with intracellular structures, potentially altering genome-wide transcription [35]. While the antifungal properties of AgNPs are well-documented, the precise mechanisms remain to be fully elucidated due to the complexity of fungal systems.