Eco-friendly silver nanoparticles from neem extracts: a dual approach to heavy metal sensing and antimicrobial applications

Samar O. Aljazzar; Abidemi Mercy Babatimehin; Oyebola Elizabeth Ogunbamowo; Moamen S. Refat; Lamia A. Albedair; Edwin Andrew Ofudje

doi:10.1186/s40643-026-01011-w

Bioresources and Bioprocessing ›› 2026, Vol. 13 ›› Issue (1) :18 DOI: 10.1186/s40643-026-01011-w

Research

research-article

Eco-friendly silver nanoparticles from neem extracts: a dual approach to heavy metal sensing and antimicrobial applications

Author information +

History +

PDF

Abstract

This work investigates the green synthesis of silver nanoparticles (AgNPs) using mixed aqueous extracts of Azadirachta indica leaves and roots as natural reducing and stabilizing agents. The synthesis was optimized by varying extract concentration, pH, and temperature, and nanoparticle formation was confirmed by UV–Vis spectroscopy showing a characteristic surface plasmon resonance between 350 and 450 nm. Structural and morphological analyses {X-ray diffraction (XRD), scanning electron microscope (SEM), Fourier-Transform Infrared (FT-IR), particle size analysis} revealed predominantly crystalline, spherical AgNPs capped by phytochemicals like flavonoids, phenols, amide- and carbonyl-containing compounds. The phytochemical profile of the extract was further validated by Gas Chromatography-Mass Spectrometry (GC–MS) analysis. The biosynthesized AgNPs exhibited strong colorimetric sensing capability for heavy metals, showing noticeable spectral and visible color changes particularly in the presence of Hg²⁺, Pb²⁺, and Cd²⁺ ions. Antibacterial evaluation indicated significant inhibitory activity against Staphylococcus aureus (33±0.13 mm) and Escherichia coli (45±0.21 mm), outperforming standard gentamycin controls. These findings highlight neem-derived AgNPs as low-cost, eco-friendly nanomaterials with dual applications in environmental monitoring of heavy metals and antimicrobial therapy.

Keywords

Green synthesis / Silver nanoparticles / Azadirachta indica / Heavy metals / Colorimetric

Cite this article

Download citation ▾

Samar O. Aljazzar, Abidemi Mercy Babatimehin, Oyebola Elizabeth Ogunbamowo, Moamen S. Refat, Lamia A. Albedair, Edwin Andrew Ofudje. Eco-friendly silver nanoparticles from neem extracts: a dual approach to heavy metal sensing and antimicrobial applications. Bioresources and Bioprocessing, 2026, 13(1): 18 DOI:10.1186/s40643-026-01011-w

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Adegoke HI, Adekola MF, Fatoki OSet al.. Adsorption of Cr (VI) on synthetic hematite (α-Fe₂O₃) nanoparticles of different morphologies. Korean J Chem Eng, 2014, 31: 142-154

[2]	Ahmed RH, Mustafa DE. Green synthesis of silver nanoparticles mediated by traditionally used medicinal plants in Sudan. Int Nano Lett, 2020, 10(1): 1-14

[3]	Alabdallah NM, Hasan MM. Plant-based green synthesis of silver nanoparticles and its effective role in abiotic stress tolerance in crop plants. Saudi J Biol Sci, 2021, 28(10): 5631-5639

[4]	Ali H, Khan E, Sajad MA. Phytoremediation of heavy metals—concepts and applications. Chemosphere, 2013, 91(7): 869-881

[5]	Ansari M, Ahmed S, Abbasi Aet al.. Plant mediated fabrication of silver nanoparticles, process optimization, and impact on tomato plant. Sci Rep, 2023, 13 18048

[6]	Aziz KHH, Mustafa FS, Omer KMet al.. Heavy metal pollution in the aquatic environment: efficient and low-cost removal approaches to eliminate their toxicity: a review. RSC Adv, 2023, 13: 17595-17610

[7]	Babatimehin AM, Ajayi GO, Ogunbamowo OEet al.. Synthesis of silver nanoparticles using Azadirachta indica leaf extracts for heavy metal sensing. BioResources, 2025, 20(2): 334

[8]	Babatimehin AM, Ogunbamowo OE, Ajayi GOet al.. Colorimetric sensing of chlorpyrifos pesticides using green synthesized silver nanoparticles from neem root extracts. BioResources, 2025, 2036948-6965

[9]	Balali-Mood M, Naseri K, Tahergorabi Zet al.. Toxic mechanisms of five heavy metals: mercury, lead, chromium, cadmium, and arsenic. Front Pharmacol, 2021, 12 643972

[10]	Barakat MA. New trends in removing heavy metals from industrial wastewater. Arab J Chem, 2011, 4(4): 361-377

[11]	Barbalinardo M, Benvenuti E, Gentili Det al.. Differential cytotoxicity of surface-functionalized silver nanoparticles in colorectal cancer and x-vivo healthy colonocyte models. Cancers, 2025, 17(9 1475

[12]	Baruah S, Khan NM, Dutta J. Perspectives and applications of nanotechnology in water treatment. Environ Chem Lett, 2016, 14: 1-14

[13]	Bashir N, Afzaal M, Khan ALet al.. Green-synthesized silver nanoparticle-enhanced nanofiltration mixed matrix membranes for high-performance water purification. Sci Rep, 2025, 15 1001

[14]	Bhat RS, Almusallam J, Al Daihan Set al.. Biosynthesis of silver nanoparticles using Azadirachta indica leaves: characterisation and impact on Staphylococcus aureus growth and glutathione-S-transferase activity. IET Nanobiotechnol, 2019, 35): 498-502

[15]	Chandraker SK, Ghosh MK, Lal Met al.. Colorimetric sensing of Fe³⁺ and Hg²⁺ and photocatalytic activity of green synthesized silver nanoparticles from the leaf extract of Sonchus arvensis L. New J Chem, 2019, 43(46): 18175-18183

[16]	Chandramohan B, Murugan K, Panneerselvam Cet al.. Characterization and mosquitocidal potential of neem cake-synthesized silver nanoparticles: genotoxicity and impact on predation efficiency of mosquito natural enemies. Parasitol Res, 2016, 115: 1015-1025

[17]	Chen W, Liu Q, Tian S, Zhao X. Exposed facet dependent stability of ZnO micro/nano crystals as a photocatalyst. Appl Surf Sci, 2019, 470: 807-816

[18]	Dakal TC, Kumar A, Majumdar RS, Yadav V. Mechanistic basis of antimicrobial actions of silver nanoparticles. Front Microbiol, 2016, 7 1831

[19]	Dash SP, Dixit S, Sahoo S. Phytochemical and biochemical characterizations from leaf extracts from Azadirachta indica: an important medicinal plant. Biochem Anal Biochem, 2017, 6: 2161-1009

[20]	Das U, Daimari NK, Biswas R, Mazumder N. Elucidating impact of solvent and pH in synthesizing silver nanoparticles via green and chemical route. Discov Appl Sci, 2024, 6: 320

[21]	Dawadi S, Katuwal S, Gupta Aet al.. Current research on silver nanoparticles: synthesis, characterization, and applications. J Nanomater, 2021, 1: 6687290

[22]	De Silva M, Cao G, Tam KC. Nanomaterials for the removal and detection of heavy metals: a review. Environ Sci Nano, 2025, 12: 2154-2176

[23]	Dhir R, Chauhan S, Subham Pet al.. Plant-mediated synthesis of silver nanoparticles: unlocking their pharmacological potential–a comprehensive review. Front Bioeng Biotechnol, 2023

[24]	Eker F, Duman H, Akdaşçi Eet al.. Silver nanoparticles in therapeutics and beyond: a review of mechanism insights and applications. Nanomaterials, 2024, 14(20 1618

[25]	Ekundayo TC, Swalaha FM, Ijabadeniyi OA. Global and regional final point-of-drinking water prevalence of Vibrio pathogens: a systematic analysis with socioeconomic, global health security, and WASH indices-guided meta-regressions. Sci Total Environ, 2024

[26]	Ershov VA, Ershov BG. Effect of silver nanoparticle size on antibacterial activity. Toxics, 2024, 1211 801

[27]	Fahimmunisha BA, Ishwarya R, AlSalhi MSet al.. Green fabrication, characterization and antibacterial potential of zinc oxide nanoparticles using Aloe socotrina leaf extract: a novel drug delivery approach. J Drug Deliv Sci Technol, 2020, 55 101465

[28]	Francine U, Jeannette U, Pierre RJ. Assessment of antibacterial activity of neem plant (Azadirachta indica) on Staphylococcus aureus and Escherichia coli. J Med Plants Stud, 2015, 34): 85-91

[29]	Gholami M, Shahzamani K, Marzban Aet al.. Evaluation of antimicrobial activity of synthesised silver nanoparticles using Thymus kotschyanus aqueous extract. IET Nanobiotechnol, 2018, 12(8): 1114-1117

[30]	Giacoma W, Carere CM, Mancini L. Chemical pollution as a driver of biodiversity loss and potential deterioration of ecosystem services in Eastern Africa: a critical review. S Afr J Sci, 2021, 117: 9-10

[31]	Gupta P, Ilyas H, Raghav DSet al.. Sustainable synthesis of silver nanoparticles via hordeum vulgare seed extract: catalysis, antioxidant, anti-cancerous and antimicrobial potential. Discov Mater, 2025, 5 143

[32]	Gwada CA, Ndivhuwo PS, Matshetshe Ket al.. Phytochemical-assisted synthesis, optimization, and characterization of silver nanoparticles for antimicrobial activity. RSC Adv, 2025, 15: 14170-14181

[33]	Hosney A, Kundrotaitė A, Drapanauskaitė Det al.. Green synthesis of chitosan silver nanoparticle composite materials: a comparative study of microwave and one-pot reduction methods. Polymers, 2025, 17(21 2960

[34]	Hosny S, Gaber GA, Ragab MSet al.. A comprehensive review of silver nanoparticles (AgNPs): synthesis strategies, toxicity concerns, biomedical applications, AI-driven advancements, challenges, and future perspectives. Arab J Sci Eng, 2025

[35]	Ibrahim NH, Taha GM, Hagaggi NSAet al.. Green synthesis of silver nanoparticles and its environmental sensor ability to some heavy metals. BMC Chem, 2024, 18 7

[36]	Inaba T, Kobayashi E, Suwazono Yet al.. Estimation of cumulative cadmium intake causing Itai-itai disease. Toxicol Lett, 2005, 1592): 192-201

[37]	Karthiga D, Savarimuthu PA. Selective colorimetric sensing of toxic metal cations by green synthesized silver nanoparticles over a wide pH range. RSC Adv, 2013, 3: 16765-16774

[38]	Khalifa HO, Oreiby A, Mohammed Tet al.. Silver nanoparticles as next- generation antimicrobial agents: mechanisms, challenges, and innovations against multidrug- resistant bacteria. Front Cell Infect Microbiol, 2025

[39]	Kemala P, Khairan K, Ramli Met al.. Optimizing antimicrobial synergy: green synthesis of silver nanoparticles from Calotropis gigantea leaves enhanced by patchouli oil. Narra J, 2024, 4(2 e800

[40]	Kumar SR, Nallaswamy D, Rajeshkumar Set al.. Green synthesis of silver nanoparticles using neem and turmeric extract and its antimicrobial activity of plant mediated silver nanoparticles. J Oral Biol. Craniofac. Res., 2025, 152): 395-401

[41]	Laoye B, Olagbemide P, Ogunnusi Tet al.. Heavy metal contamination: sources, health impacts, and sustainable mitigation strategies with insights from Nigerian case studies. F1000Res, 2025, 14 134

[42]	Lashgarian HE, Karkhane M, Alhameedawi AKet al.. Phyco-mediated synthesis of Ag/AgCl nanoparticles using ethanol extract of a marine green algae, ulva fasciata delile with biological activity. Biointerface Res Appl Chem, 2021, 11(6): 14545-14554

[43]	Liaqat N, Jahan N, Khalil-Ur-Rahmanet al.. Green synthesized silver nanoparticles: optimization, characterization, antimicrobial activity, and cytotoxicity study by hemolysis assay. Front Chem, 2022, 10: 952006

[44]	Mason LH, Harp JP, Han DY. Pb neurotoxicity: neuropsychological effects of lead toxicity. BioMed Res Int, 2014

[45]	Meher A, Tandi A, Moharana Set al.. Silver nanoparticle for biomedical applications: a review. Hybrid Adv, 2024, 6 100184

[46]	Mirzaei SZ, Lashgarian HE, Karkhane Met al.. Bio-inspired silver selenide nano-chalcogens using aqueous extract of Melilotus officinalis with biological activities. Bioresour Bioprocess, 2021, 8(1 56

[47]	Mohammad SJ, Ling YE, Halim KAet al.. Heavy metal pollution and transformation in soil: a comprehensive review of natural bioremediation strategies. J Umm Al-Qura Univ Appll Sci, 2025, 11: 528-544

[48]	Mohd F, Adnan S, Nahid Net al.. Green synthesis of silver nanoparticles: a comprehensive review of methods, influencing factors, and applications. JCIS Open, 2024, 16: 00125

[49]	Muhammad A, Birnin-Yauri AU, Sani HAet al.. Plant-based silver nanoparticles for the detection of eald (II) ions. Am J Appl Chem, 2023, 113): 75-80

[50]	Nosrati F, Fakheri B, Ghaznavi Het al.. Green synthesis of silver nanoparticles from plant Astragalus fasciculifolius Bioss and evaluating cytotoxic effects on MCF7 human breast cancer cells. Sci Rep, 2025, 15: 25474

[51]	Ofudje EA, Adeogun IA, Idowu MAet al.. Simultaneous removals of cadmium(II) ions and reactive yellow 4 dye from aqueous solution by bone meal-derived apatite: kinetics, equilibrium and thermodynamic evaluations. J Anal Sci Technol, 2020, 11 7

[52]	Ofudje EA, Sodiya EF, Olanrele OSet al.. Adsorption of Cd²⁺ onto apatite surface: equilibrium, kinetics and thermodynamic studies. Heliyon, 2023, 9 e12971

[53]	Pasieczna-Patkowska S, Cichy M, Flieger J. Application of Fourier transform infrared (FTIR) spectroscopy in characterization of green synthesized nanoparticles. Molecules, 2025, 30 684

[54]	Patel MR, Upadhyay MD, Ghosh Set al.. Synthesis of multicolor silver nanostructures for colorimetric sensing of metal ions (Cr³⁺, Hg²⁺ and K⁺) in industrial water and urine samples with different spectral characteristics. Environ Res, 2023, 1 116318

[55]	Pechyen C, Tangnorawich B, Toommee Set al.. Green synthesis of metal nanoparticles, characterization, and biosensing applications. Sens Int, 2024, 5 100287

[56]	Tilako BH, Ogbodo SO, Okonkwo INet al.. Distribution and interactions of priority heavy metals with some antioxidant micronutrients in inhabitants of a lead-zinc mining community of Ebonyi state, Nigeria. Adv Toxicol Toxic Effects, 2020, 4(1): 011-0017

[57]	Rahuman HBH, Dhandapani R, Narayanan Set al.. Medicinal plants mediated the green synthesis of silver nanoparticles and their biomedical applications. IET Nanobiotechnol, 2022, 6(4): 115-144

[58]	Rodriguez-Loya J, Lerma M, Gardea-Torresdey JL. Dynamic light scattering and its application to control nanoparticle aggregation in colloidal systems: a review. Micromachines, 2024, 15(1 24

[59]	Rossi A, Zannotti M, Cuccioloni Met al.. Silver nanoparticle-based sensor for the selective detection of nickel ions. Nanomaterials, 2021, 117 1733

[60]	Roto R, Mellisani B, Kuncaka Aet al.. Colorimetric sensing of Pb²⁺ ion by using Ag nanoparticles in the presence of dithizone. Chemosensors, 2019, 73 28

[61]	Sahu D, Khute M, Pillai AK. Plasmonic colorimetric sensor based on alpha-cyclodextrin-functionalized silver nanoparticles for the selective detection of arsenic(III) in aqueous media. RSC Adv, 2024, 14: 40160-40172

[62]	Saki R, Shakib P, Nomanpour Bet al.. Bio-assessments of the antibiofilm, antioxidant, and plasmid inhibitory effects of zinc selenide nanoparticles synthesized using Stachys lavandulifolia extract. Sci Rep, 2025, 15 35633

[63]	Shakib P, Mirzaei SZ, Sharafi Zet al.. Biofabrication of copper oxide nanoparticles mediated with Echium amoenum petal extract for evaluation of biological functions. Biomass Conv Biorefin, 2024, 1420): 25651-25661

[64]	Sithara R, Selvakumar P, Arun Cet al.. Economical synthesis of silver nanoparticles using leaf extract of Acalypha hispida and its application in the detection of Mn(II) ions. J Adv Res, 2017, 8(6): 561-568

[65]	Tin-Oo MM, Gopalakrishnan V, Samsuddin ARet al.. Shamsuria, antibacterial property of locally produced hydroxyapatite. Arch Orofac Sci, 2007, 2(2007): 41-44

[66]	Tosini L, Cartereau M, Bagousse-Pinguet LYet al.. Plant biodiversity offsets negative effects of metals and metalloids soil multi-contamination on ecosystem multifunctionality. Sci Total Environ, 2023, 898: 165567

[67]	Xu L, Zhao F, Xing Xet al.. A review on remediation technology and the remediation evaluation of heavy metal-contaminated soils. Toxics, 2024, 1212 897

[68]	Zhang J, Chen Y, Xu Yet al.. Salicylic acid-mediated silver nanoparticle green synthesis: characterization, enhanced antimicrobial, and antibiofilm efficacy. Pharmaceutics, 2025, 174 532