ISSN: 2155-952X

Journal of Biotechnology & Biomaterials
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  • Review Article   
  • J Biotechnol Biomate 2023 13:324, Vol 13(3)
  • DOI: 10.4172/2155-952X.1000324

Green Synthesis of Silver Nanoparticles

Kishore Thirunavukarasu1,2, Muhammed Ali Siham1,3*, Jayenth Jayachandran1,4, Mohan Rao1,4, Gandhi Raj1 and Kurunchu Divya1,5,6
1Chettinad Academy of Research and Education, Chennai, Tamil Nadu, India
2Bharathiar University, Coimbatore, India
3Garden City University, Bengaluru, Karnataka, India
4Sathyabama Institute of Science and Technology, India
5Tamil Nadu Veterinary and Animal Sciences University, India
6University of Madras, India
*Corresponding Author: Muhammed Ali Siham, Garden City University Bengaluru, Karnataka, India, Tel: +917397239448, Email: 21msmh108@gcu.edu.in, hrsiham. education@gmail.com, hrsiham.website@gmail.com

Received: 01-May-2023 / Manuscript No. jbtbm-23-88274 / Editor assigned: 03-May-2023 / PreQC No. jbtbm-23-88274 (PQ) / Reviewed: 17-May-2023 / QC No. jbtbm-23-88274 / Revised: 22-May-2023 / Manuscript No. jbtbm-23-88274 (R) / Published Date: 29-May-2023 DOI: 10.4172/2155-952X.1000324

Abstract

Over the years, there have been numerous attempts to develop new green synthesis technologies. Precious metals like copper, zinc, titanium, magnesium, silver, gold, and platinum are used to make nanoparticles. They have drawn a lot of interest due to their versatility as theragnostic agents. Significant antibacterial efficacy against Escherichia coli and Staphylococcus aureus, as well as antifungal activity against Trichosporon seinelii and Candida albicans, has been demonstrated by silver nanoparticles (Ag NP). AgNPs function in both drug delivery and successfully inducing the death of cancer cells. With the addition of Enterobacteriaceae cell filtrate (Escherichia coli, Klebsiella pneumonia, and Enterobacter cloacae) to AgNO3 solution, the silver ions are rapidly reduced within 5 minutes. The Temperature, pH, and AgNO3 concentration all influence the size of AgNPs generated using Escherichia coli, Klebsiella pneumoniae and Enterobacter cloacae, all of which create AgNPs. Since pH is essential for the effective synthesis of nanoparticles, this element increases the reactivity of plant extract with silver ions. Silver nanoparticle dilutions of 10,20,40,80,160 g/ ml were prepared and used in this analysis. 200μl of bacterial suspension was inoculated into each test tube containing varying amounts of AgNPs and a comparable volume of Muller Hinton Broth (MHB) and incubated for 24 hours at 37°C.

Keywords: Green Synthesis; Fourier-transform infrared spectroscopy; Transmission electron microscopy; Silver nanoparticle

Keywords

Green Synthesis; Fourier-transform infrared spectroscopy; Transmission electron microscopy; Silver nanoparticle

Introduction

Nanotechnology has become one of the largest and most active areas of research, offering unique properties and broad applications in various fields such as agriculture, food, and biomedicine. Compared to larger particles in bulk solids, nanoparticles have completely new or improved properties, and these new properties are based on variations in specific properties such as particle size, morphology and distribution. Nanoparticles are made of precious metals such as silver, gold, platinum, copper, zinc, titanium, and magnesium. They have received considerable attention because of their multifunctional theranostic ability. Nanoparticles have various structures with shapes such as rods, spheres, tubes, hollow spheres, and blood platelets. There were different types of nanoparticles like semiconductors, core-shell particles, polymers, metal and metal oxides . These types of metal nanoparticles have exceptionally high physical and chemical properties. AgNPs have the properties like large surface area to volume ratio (silver is a powerful bactericidal metal as it is non-toxic to animal cells and highly toxic to bacteria, have antioxidant and antimicrobial properties and AgNPs are used in coatings or inlays for medical purposes. In addition to their medical use, AgNPs are also used in clothing, Paints, Food, Electronics, and Other Areas AgNPs are used worldwide to manufacture a wide range of products including aerosols, water filters, water treatment, detergents, refrigerators, paints, cosmetics, washing machines and electronic products, because of its high antimicrobial properties [1-6].

In recent years the increase in antibiotic resistance of microbes posed a serious threat to the health sector. Nanoparticles are a promising antibacterial agent candidate due to their small size and high surface to volume ratio, which assures a broad assault area on the bacterial surface. Silver functions as a highly efficient antibacterial. Several tests were carried out on silver nanoparticles to investigate their antimicrobial activity. It showed significant antibacterial activity against Escherichia coli, Staphylococcus aureus, and antifungal activity against Trichosporon seinelii and Candida albicans. AgNPs are one of the most important Materials in nanomedicine. In the treatment of bacterial skin infections, silver nanoparticles (Ag NP) have been utilized as an antibacterial agent for topical administration. In other situations, Ag NPs have drawn a lot of attention due to their possible application in cancer treatment. AgNPs successfully trigger cancer cell death and also have a role in medication delivery. The development of new chemical and physical methods has led to environmental pollution as the chemical processes used to synthesize the materials generate a large no. of hazardous by-products. Whereas the green synthesis method does not require the use of high energy, pressure or temperature and toxic chemicals for the production.

The Biological methods include the synthesis of nanomaterials from extracts of plants, bacteria, fungi, etc. Plant extracts comprising leaves, fruit, bark, roots, flowers, rhizoids and latex, are utilized for nanoparticles synthesis. These nanoparticles have different morphological features including size, shape, and dispersion that are more efficient than those synthesized by chemical or physical processes. Hence, using green plants for nanoparticle biosynthesis process is an exciting method that is compatible with pharmaceutical and biomedical applications as no toxic chemicals are used for nanoparticle synthesis. When the nanoparticles are produced with an extract method, the extract is added at room temperature to a metal salt solution and the reaction is finished within a few minutes. With this process, nanoparticles were produced from silver, gold, and other metals in the amount of silver and the released silver. Silver is inactive in metallic form, but reacts with moisture in the skin and wound fluids and ionizes. Silver ions are highly reactive and stick to tissue proteins this leads to structural changes in the bacterial cell wall and the cell nuclear membrane and ultimately to deformations and Cell death. The use of plants to synthesize nanoparticles prevents the release of large amounts of toxic chemicals in solid, liquid, and gaseous forms into the environment and also eliminates the adhesion of toxic substances to synthesized nanoparticles [7-9].

The size, stability, morphology as well as physical and chemical properties of nanoparticles, plays an important role in their applications. Tools are needed to control the size and shape of metallic nanostructures and improve their specific uses, much like metals developed for macroscopic devices. The size and shape of the nanoparticles can be controlled by maintaining several reaction parameters such as temperature, Ph, the concentration of the metal solution, and concentration of reducing agents, the particles obtained were analyzed and characterized by UV-Vis spectroscopy, Scanning electron microscope (SEM) and Transmission electron Microscope (TEM), X-ray diffraction (XRD) and Fourier transform spectroscopy (FTIR).The antibacterial activity of AgNPs was investigated by performing Agar well diffusion test and MIC.

Green synthesis

Using Bacteria:

Bacteria are one of the best bioagent for nanoparticle synthesis due to their remarkable ability to reduce heavy metal ions. Bacteria are known to produce inorganic materials either intracellularly or extracellularly. As a result, they could be used as biofactories to produce gold and silver nanoparticles. Shahverdi et al. demonstrated fast production of Ag NPs (within 5 minutes) using culture supernatants of K. pneumonia, E. coli, and Enterobacter cloacae. Saravanan et al. have reported an extracellular production of Ag NPs using B. megaterium culture supernatant in the presence of Aq solutions of silver ions in minutes. With the addition of Enterobacteriaceae cell filtrate (Escherichia coli, Klebsiella pneumonia, and Enterobacter cloacae) to AgNO3 solution, the silver ions are rapidly reduced within 5 minutes. Saifuddin et al. used a combination of B. subtilis culture supernatant and microwave irradiation in water to show extracellular production of Ag NPs (5–50 nm). Bacillus flexus formed anisotropic nanoparticles with spherical (12 nm) and triangular (61 nm) dimensions. For the manufacture of AgNPs utilizing Bacillus cereus, an incubation time of 3–5 days at room temperature is required. The interaction of silver ions with bacteria influences the size and structure of AgNPs generated by microorganisms.

The Temperature, pH, and AgNO3 concentration all influence the size of AgNPs generated using Escherichia coli, Klebsiella pneumoniae and Enterobacter cloacae, all of which create AgNPs. Green synthesis based on bacteria is adaptable, affordable, and suited for large-scale manufacturing. The biggest disadvantage of utilizing bacteria as nano factories is the sluggish synthesis rate and the restricted variety of shapes and sizes accessible when compared to standard chemical synthesis methods. As a result, fungi-based nano factories and chemical reactions involving plant-based materials have been studied [10-14] (Table 1).

s.no Article/Author Particle Characterization Operating Conditions Particle Characterization Particle Characteristics
1 Synthesis of Gold and Silver Nanoparticles Using Purified URAK. Colloids and Surfaces B: Bio-interfaces. Fibrinolytic URAK enzyme produced by Bacillus cereus NK1 1 mM, 24 hr without NaOH and 5 min with NaOH, 37˚C. TEM XRD
UV-Vis
Size- 50 - 80 nm
Shape--spherical. Structure- FCC
2 Extracellular Biosynthesis of Silver Nanoparticles Using Cell Filtrate of Streptomyces sp. ERI-3. Aqueous cell filtrate of Streptomyces sp. ERI-3 1 mM, 28˚C,48 hr,. Dark. Shaken UV-Vis TEM SEM
XRD
10 - 100 nm Spherical
3 The Antibacterial and Anti-Biofouling Performance of Biogenic Silver Nanoparticles by Lactobacillus fermentum. Lactobacillus fermentum.L 10 g/L,
24 hr, 30˚C, 10 g/L, Shaken, 6 min at 5000 rpm and 10 min at 6000 rpm
UV-Vis TEM XRD 6 nm
spherical
FCC
4 Biogenic Synthesis of Antimicrobial Silver Nanoparticles Caped with L-Cystine. Escherichia coli cells 1 or 5mM,  30˚C, 24 hr, Ratio of AgNO3: L-cysteine = 1:5, Shaken, 10 min at 1851 g UV-Vis TEM
FTIR
Size-~5 nm
5 Biosynthesis, Purification and Characterization of Silver Nanoparticles Using Escherichia coli. E. coli supernatant 1 - 10mM, , 20˚C - 90˚C, 24 hr, pH: 5 - 12, 10 min at 10000 rpm Stati UV-Vis TEM FTIR
DLS
10 - 90 nm
Spherical
Crystalline
6 Rapid Synthesis of Silver Nanoparticles Using Cultural Supernatants of Enterobacteria: A Novel Biological Approach. K. pneumonia (Enterobacteria) 1mM,
5 min, Room temperature.
UV-Vis EDS
TEM
Average: 52.25 nm
Spherical.
7 Biosynthesis of Silver and Gold Nanoparticles Using Brevibacterium casei. Brevibacterium casei 1mM, 24 hr, 37˚C, 1 g, Shaken, 30 min at 16000 g UV-Vis XRD FTIR
TEM
10 - 50 nm. Spherical. FCC
8 Biosynthesis of Silver Nanoparticles from Staphylococcus aureus and Its Antimicrobial Activity against MRSA and MRSE. Supernatant of Staphylococcus aureus 1 mM AgNO3,
5 min
AFM
UV-Vis
160 - 180 nm
Nature-PD
9 Production and Structural Characterization of Crystalline Silver Nanoparticles from Bacillus cereus Isolate. Bacillus cereus PGN1 cells 1 mM, 10 g/100 ml,
12hr, 37˚C,
15 min at 15000 rpm. Shaken
UV-Vis
FTIR TEM
XRD
4-5 nm Spherical
FCC.
Nature-MD.
10 Intensified Biosynthesis of Silver Nanoparticles Using a Native Extremophilic Ureibacillus thermosphaerius Strain. supernatant of Ureibacillus thermo sphaerius 1 - 100 mM,
24 hr, 60˚C - 80˚C, Dark,
15 min,13000 rpm Static
UV-Vis DLS XRD FTIR 10 - 100 nm Spherical FCC
11 Biosynthesis of Silver Nanocrystals by Bacillus licheniformis. Bacillus icheniormis cells 1 mM,
24 hr, 37˚C,
30 min at 15000 rpm. Shaken
UV-Vis SEM EDX XRD 50 nm
Crystalline
12 Green synthesis of silver nanoparticles using Rhodobacter sphaeroides. Rhodobacter sphaeroides 1mM,5g,
30˚c,72hr,
,10min at 4000g
UV–vis XRD TEM and HRTEM 3–15nm
Spherical
crystalline
13 Intracellular and extracellular biosynthesis of silver nanoparticles by using marine bacteria Vibrio alginolyticus. Vibrio alginolyticus 1M,
24-48hr,37˚C,
7500rpm for 15min
UV-Vis SEM EDX 50–100 nm; Spherical
14 Intra/extracellular biosynthesis of silver nanoparticles by an autochthonous strain of Proteus mirabilis isolated from photographic waste. Proteus mirabilis 1mM,
24hr,37˚C,
7000rpm for 30 min
UV–Visible Spectroscopy, TEM and EDS 10–20 nm; spherical
15 Synthesis and characterization of bactericidal silver nanoparticles using cultural fltrate of simulated microgravity grown Klebsiella pneumoniae. Klebsiella pneumoniae 1mM,
72hr,35˚C,
10000rpm for 30 min
UV-Vis FTIR TEM 15–37 nm; spherical
16 In vitro antiplatelet activity of silver nanoparticles synthesized using the microorganism Gluconobacter roseus: an AFM-based study. Gluconobacter roseus 1mM,
24hr,37˚C,
7000rpm for 12hr
UV-Vis TEM EDS FTIR 10 nm
17 Synthesis, optimization, and characterization of silver nanoparticles from Acinetobacter calcoaceticus and their enhanced antibacterial activity when combined with antibiotics. Acinetobacter calcoaceticus 1mM,
72hr,40˚C,
6000rpm for 10min
UV-Vis XRD TEM SEM 8–12 nm; spherical
18 Biosynthesis of silver
nanoparticles using Bacillus thuringiensis against dengue vector, Aedes
aegypti (Diptera: Culicidae).
B. thuringiensis 1mM,
72hr,37˚C,
5000rpm for 10min
UV-Vis SEM EDX XRD 43.52–142.97 nm
19 Mechanistic antimicrobial approach of extracellularly synthesized silver nanoparticles against gram positive and gram negative bacteria. Exiguobacterium sp. 1mM,
24hr,30˚C,
8000g for 10min
UV-Vis FTIR TEM XPS 5–50 nm; spherical
20 Green synthesis of silver nanoparticles using keratinase obtained from a strain of Bacillus safensis LAU 13 B. safensis LAU 13 1mM,
2hr,30˚C,
10000rpm for 20 min
UV-Vis FTIR TEM XRD 5–30 nm; spherical
21 Microbial synthesis of silver nanoparticles by Bacillus sp. Bacillus sp. 3.5mM,
7days,27˚C,
10,000rpm for 10min
TEM EDX 5–15 nm
22 Synthesis of anisotropic silver nanoparticles using novel strain, Bacillus fexus and its biomedical application. B. fexus 1mM,
24hr,30˚C
UV-Vis FTIR AFM XRD EDAX 12 & 65 nm; spherical and triangular
23 Biosynthesis of silver nanoparticles using a probiotic Bacillus licheniformis Dahb1 and their antibioflm activity and toxicity efects in Ceriodaphnia cornuta. B. licheniformis Dahb1 1mM,
24hr,37˚C,
5000g for 10 min
UV-Vis TEM
XRD
18.69–63.42 nm
Spherical.
24 Biosynthesis of silver and gold nanoparticles using thermophilic bacterium Geobacillus stearothermophilus. Geobacillus stearothermophilus 0.01M,
48hr,27˚C,
5000rpm for 10 min
UV-Vis TEM
XRD
5–35 nm; spherical
25 comparative study of morphology, reactivity and stability of synthesized silver nanoparticles using Bacillus subtilis and Catharanthus roseus. B. subtilis 1mM,
24hr,27˚C
UV-Vis XRD
EDAX
Triangular, hexagonal

Table 1:Fungi-based nano factories and chemical reactions involving plant-based materials have been studied.

Using Fungi:

Fungi, like bacteria, have been studied in the biological creation of metallic nanoparticles because of their high binding capacity and metal bioaccumulation ability, high tolerance and intracellular absorption. The switch from bacteria to fungus as a technique of generating natural nano factories has the advantage of simplified biomass handling and downstream processing. Fungus is known to release far greater amounts of proteins than bacteria, which increases the productivity of this biosynthetic technique; also, fungi might be utilized to produce enormous numbers of metal nanoparticles Polydispersed spherical AgNPs with sizes ranging from 17-33 nm were produced with Helminthosporium tetramera cell-free filtrate and had considerable antibacterial activity.

Fungi are easier to work within a laboratory setting than bacteria. Fungus employs a distinct process to produce nanoparticles; fungi release enormous amounts of enzymes that are utilized to decrease Ag ions that stimulate the synthesis of metal nanoparticles. Bipolaris nodulosa was used to create silver nanoparticles with spherical, semi pentagonal, and hexahedral structures (10–60 nm). Silver ions are reduced by the enzymes present on the surface of Verticillium, and cells were observed to grow even after the formation of AgNPs.

Thus, the biomimetic conduit towards plant species has been established using the microbially aided syntheses of AgNPs. Enzymes found in microbes are responsible for the reduction of silver ions, which results in the formation of AgNPs. Higher amounts of silver ions are toxic to these species. As a result, when employed in biomedical applications, nanosilver generated by microorganisms presents several challenges(Table 2).

s.no Article/Author Reducing Agent Particle Characterization Particle Characterization Particle Characterization
1 Biosynthesis of Silver Nanoparticles Using Aqueous Extract from the Compactin Producing Fungal Strain. Penicillium brevicompatum 1 mM,
25˚C, 72 hr Shake
UV-Vis TEM XRD FTIR Size—17.8 nm Structure—FCC
2 Silver-NanoBiohybrid Material: Synthesis, Characterization and Application in Water Purification. Mycelia of Rhizopus oryzae 1 to 5 mM, 72 hr, 30˚C, 0.2 g/25 ml. pH—2 to 8, Shaken UV-Vis FTIR
HRTEM EDAX
15 nm spherical
FCC
3 Extracellular Biosynthesis of Silver Nanoparticles Using the Filamentous Fungus Penicillium sp. Aqueous cell filtrate of Penicillium Sp. fungi 1 mM, 24 hr, room temp, dark 50 ml/50 ml, Agitated, Lyophilized UV-Vis FTIR AFM 52 -104 nm
4 Extracellular Biosynthesis of Functionalized Silver Nanoparticles by Strains of Cladosporium cladosporioides Fungus. Cladosporium clado sporioides 10 ml,
27˚C, 78 h Shaken
UV-Vis TEM XRD FTIR Average: 35 nm
Spherical
FCC
5 Fusarium solani: A Novel Biological Agent for the Extracellular Synthesis of Silver Nanoparticles. Fusarium solani 1mM, Static, 10 min, 10,000 g, room temperature. UV-Vis TEM
FTIR
5 - 35 nm
Spherical
6 Studies on Silver Nanoparticles Synthesized by Marine Fungus, Penicillium fellutanum Isolated from Coastal Mangrove Sediment. Penicillum fellutanum 0.5 - 2.5 mM, 48 hr, 40˚C, dark, pH: 7.5. Shaken. TEM UV-Vis 5 -2 5 nm
Spherical
7 Extracellular Biosynthesis of Silver Nanoparticles Using the Fungus Fusarium semitectum. Fusarium semitectum 1 mM AgNO3, 27˚C, 48 hr Shaken. UV-Vis FTIR
XRD
TEM
10 - 60 nm
Spherical
crystalline
8 Fungal Based Synthesis of Silver Nanoparticles—An Effect of Temperature on the Size of Particles. Trichoderma viride 1 mM AgNO3,40˚C, dark, Shaken. UV-Vis
TEM FTIR
XRD
80 - 100 nm
Plate like Crystalline
9 Green synthesis of protein capped silver nanoparticles from phytopathogenic fungus Macrophomina phaseolina (Tassi) Goid with antimicrobial properties against multidrug-resistant bacteria. Macrophomina phaseolina 1mM AgNO3,
28˚C, dark,72hr
UV-Vis XRD TEM SEM AFM 5–40 nm; spherical
10 Biomimetic synthesis and characterisation of protein capped silver nanoparticles. Cladosporium cladosporioides 1mM AgNO3,
37˚C,dark
shaken
UV-Vis XRD TEM  AFM 10–100 nm
11 Biological synthesis of silver nanoparticles using the fungus Aspergillus favus. P. sajor-caju 0.1-10mM AgNO3,
37˚C,dark,10 days
UV-Vis XRD TEM FTIR 30.5 ± 4.0 nm
spherical
12 Biosynthesis of silver nanoparticles by fungus Trichoderma reesei (a route for large-scale production of AgNPs). T. reesei 1mM AgNO3,28˚C,dark,120hr UV-Vis   TEM  FTIR 5–50 nm
13 Tailoring shape and size of biogenic silver nanoparticles to enhance antimicrobial efcacy against MDR bacteria. T. viride 1mM AgNO3,30˚C-40˚C,48hr-72hr UV-Vis DLS   TEM  FTIR 2–5 nm; spherical
40–65 nm; rectangular
14 Green synthesis and characterization of silver nanoparticles using ascomycota fungi Penicillium nalgiovense AJ12. P. nalgiovense AJ12 1mM AgNO3,25˚C,dark,shaken UV-Vis DLS   TEM 
FTIR
25 ± 2.8 nm; spherical
15 Green synthesis of highly stabilized nanocrystalline silver particles by a non-pathogenic and agriculturally important fungus T. asperellum. Trichoderma asperellum 1mM AgNO3,25˚C,dark,shaken UV-Vis
XRD 
FTIR
13–18 nm; nanocrystalline
16 green synthesis of silver nanoparticles using Aspergillus terreus. A. terreus 1mM AgNO3,27˚C,24hr,shaken UV-Vis
XRD
TEM
1–20 nm; spherical

Table 2:As a result,when employed in biomedical applications,nanosilver generated by microorganisms presents several challenges.

Using Plants:

Plant components such as leaves, stems, roots, shoots, flowers, barks, seeds, and their metabolites have been effectively employed for the efficient production of nanoparticles. The Protocol for nanoparticle synthesis includes that the section of the plant of interest is collected at the accessible places and rinsed in tap water twice/three, completely, to eliminate the two epiphytes and the necrotic plants. These are clean and fresh sources, then pulverized by the household blender for 10-15 days and shaded. About 10 g dry powder is cooked in 100 mL of deionized distilled water for plant broth production. The resultant infusion is next carefully filtered until there is no precipitate on the broth. Following the addition of a few ml of plant extract to a 10 M AgNO3 solution, the reduction of pure Ag(I) ions to Ag (0) may be observed at regular intervals by monitoring the solution's UV–visible spectra [15-19].

Beg et al. recently reported green production of Ag NPs from Pongamia pinnata seed extract. A maximum absorption at 439nm confirmed the development of nanoparticles. The well-distributed nanoparticles with an average size of 16.4 nm exhibited a zeta potential of 23.7 mV, indicating dispersion and stability. The biosynthesis of AgNPs from the fruit extract of Piper longum has also been accomplished. The nanoparticles produced were spherical, with an average size of 46nm as assessed by SEM and a dynamic light scattering (DLS) analyzer. The extract's polyphenols are thought to work as a silver nanoparticle stabilizer. In vitro, both the fruit extract and the stabilized nanoparticles demonstrated antioxidant capabilities. The nanoparticles were discovered to be more effective against pathogenic bacteria than P. longum flower extract.

The comparatively high quantities of steroids, carbohydrates, sapogenins and flavonoids work as reducing agents, and Phytochemicals act as capping agents, providing silver nanoparticle stability. The produced nanoparticles were discovered to be spherical and of average size approximately 7–17 nm. The XRD technique revealed that these nanoparticles had a crystalline structure with a facecentered cubic shape. Using tea as a capping agent, 20–90 nm AgNPs with the crystalline structure were produced. The reaction temperature and tea extract dose influenced the production efficiency and pace of nanoparticle formation. According to TEM, the size of spherical AgNPs ranges from 5-20nm. Silver nanoparticles revealed a progressive change in color of the extracts to yellowish-brown when treated with callus extract of the Sesuvium portulacastrum L plant , as the strength of the extract increased over the incubation period. Because of its quick, non-pathogenic, eco-friendly affordable protocol and provision of a one-step methodology for biosynthesis processes, the use of plants as a production assembly of silver nanoparticles has piqued the interest of researchers. The stabilization and reduction of silver ions through the use of biomolecules such as enzymes, proteins, alkaloids, amino acids, phenolics, polysaccharides, tannins, saponins and vitamins that are present in plant extracts with medicinal properties and are environmentally friendly but have chemically complex structures [20- 24] (Table 3).

S.No Article/Author Reducing Agent Operating Conditions Characterization Particle Characerization
1 Biosynthesis of silver nanoparticles using Capparis spinosa L. leaf extract and their antibacterial activity Leaf extract of Capparis spinosa 0.01M AgNO3,
15min, room temperature,static
UV
FTIR
SEM
TEM
XRD
Size:20-25nm
Shape: spherical
Structure: crystalline
2 Facile green synthesis of silver nanoparticles using Berberis vulgaris leaf and root aqueous extract and its antibacterial activity Leaf and Root extract of Berberis Vulgaris 10mM of AgNo3, 24 hrs, room temp, shaker UV
XRD
DLS
TEM
30 to 70 nm
Spherical
variable
3 Controllable synthesis of silver nanoparticles using Neem leaves and their antimicrobial activity Leaf extract of Neem 5 ml of leaf extract,1 mM silver nitrate, 45 min, 10-50⁰, shaken. XRD
SEM
FTIR
Optical absorption
PL
402-407 nm
Spherical
FCC
4 Green synthesis of silver nanoparticles using Gymnema sylvestre leaf extract and evaluation of its antibacterial activity Leaf extract of Gymnema sylvestre 5ml of leaf extract, 0.1mM of silver nitrate, 100⁰C for 2 hours dried, centrifuged. UV
XRD
TEM
FTIR
20 to 30 nm
Spherical
Cube or crystal
5 Antioxidant and antibacterial activity of silver nanoparticles biosynthesized using Chenopodium murale leaf extract Chenopodium
murale leaf extract
1ml of leaf extract, 0.01mM of silver nitrate, room temperature, 24 hours, static. UV
TEM
30 to 50 nm
Spherical
FCC
6 Green synthesis of silver nanoparticles using Azadirachta indica aqueous leaf extract Azadirachta indica aqueous leaf extract 1mM silver nitrate, 5ml leaf extract, Room temperature, incubated. UV
TEM
DLS
Photoluminescence
436 to 446 nm
Spherical
Crystal
7 Green synthesis of silver nanoparticles using olive leaf extract and its antibacterial activity Olive leaf extract 9ml olive extract, 1ml of Silver nitrate, room temperature, shaker. UV
XRD
SEM
TGA
20-25 nm
Spherical
FCC
8 Green biosynthesis of silver nanoparticles using Torreya nucifera and their antibacterial activity Torreya nucifera leaf extract 1 mM Silver nitrate, 10ml of the aqueous solution, incubated at 20⁰ C, shaker. XRD
FT-IR
10 to 125 nm
Crystalline
FCC
9 Green biosynthesis of silver nanoparticles using Calliandra haematocephala leaf extract, their antibacterial activity, and hydrogen peroxide sensing capability Calliandra haematocephala leaf extract 10 ml of leaf extract, 1 mM silver nitrate, water bath, 80⁰ C for 10 minutes, static UV
SEM
XRD
EDS
FT-IR
414 nm
Crystalline
FCC
10 Green synthesis of silver nanoparticles using extract of Parkia speciosa Hassk pods assisted by microwave irradiation Parkia speciosa Hassk extract 10ml of extract, 1mM  AgNO3,
heated microwave at 300W for 4min, static.
UV
SEM
TEM
FT-IR
271-273 nm
Spherical
FCC
11 Green synthesis of silver nanoparticles using aqueous extract of saffron (Crocus sativus L.) wastages and its antibacterial activity against six bacteria Extract of saffron (Crocus sativus L.) 0.45 mM AgNO3,5 mL of extract and centrifuged at 8 000 r/min for 10 min, static, dried. UV
TEM
FTIR
XRD
12–20 nm
Spherical
Crystalline
12 Synthesis of silver nanoparticles using fresh bark of Pongamia pinnata and characterization of its antibacterial activity against gram-positive and gram-negative pathogens P. pinnata fresh bark extracts. 1mM AgNO3,10 ml extract and kept at room temperature. UV
TEM
SEM
XRD
EDAX
5-55 nm
Spherical
FCC
13 Green synthesis of silver nanoparticles using Capsicum frutescence and its intensified activity against E. coli Fruit Extract of  Capsicum frutescence 1 mM silver nitrate, 10 ml of fruit extract,
27°,
shaker at 150 rpm.
UV
XRD
SEM
385– 435 nm
Crystalline
FCC
14 Synthesis of Pomegranate Peel Extract Mediated Silver Nanoparticles and its Antibacterial Activity Pomegranate Peel Extract (Fruit) 1mM AgNO3, 5 ml of filtrate, 24 hours incubation with intermittent shaking. UV
FT-IR
SEM
 5-50 nm
Spherical
crystal
15 Mangrove plant, Rhizophora mucronata (Lamk, 1804) mediated one-pot green synthesis of silver nanoparticles and its antibacterial activity against aquatic pathogens Fresh leaf buds of R. mucronate. 1mM AgNO3,10 mL of the leaf extract of R. mucronate, 15 psi pressure at 121°C for 5 minutes. UV
XRD
FT-IR
HRTEM
4 nm
Crystalline
FCC
16 Biosynthesis of silver nanoparticles and its antibacterial activity using seaweed Urospora sp. Seaweeds were collected from the rocky shore. 1 mM AgNo3, at 70°C in dark condition at constant stirring (magnetic stirrer), centrifuged at 5000g for 20 min. UV
XRD
FT-IR
HRTEM
20 to 30 nm
Spherical
crystal
17 Retracted: Green Synthesis of Silver Nanoparticles Using Polyalthia longifolia Leaf Extract along with D-Sorbitol: Study of Antibacterial Activity Polyalthia longifolia Leaf Extract. 3 mL of extract,40 mL of  AgNO3solution, room temperature (25◦C), and 60◦C. UV
FT-IR
TEM
50 nm and 35 nm
Crystalline
FCC
18 Synthesis of Silver Nanoparticles from the Aqueous Extract of Leaves of Ocimum sanctum for Enhanced Antibacterial Activity Aqueous Extract of Leaves of Ocimum sanctum. 10 mL of aqueous extract,90 ml AgNO3, room temperature, 30 minutes. UV
TEM
XRD
18 nm
Crystalline
static
19 Antibacterial Activity of Silver Nanoparticles Synthesized by Bark Extract of Syzygium cumini Bark Extract of Syzygium cumini 1 mM AgNO3 and extract, a ratio of 9: 1 stored under dark conditions UV
SEM
AFM
20 to 60 nm
Spherical
crystal
20 Photo-Irradiated Biosynthesis of Silver Nanoparticles Using Edible Mushroom Pleurotus florida and Their Antibacterial Activity Studies Fresh Edible Mushroom Pleurotus florida 0.001 M  AgNO3 solution, double filtered mushroom extract allowed to react at room temperature. UV
AFM
FESEM
TEM
FT-IR
XRD
20 ± 5 nm
Crystal
Crystalline
21 Characterization and Antibacterial Activity of Biosynthesized Silver Nanoparticles Using the Ethanolic Extract of Pelargonium sidoides DC Extract of Pelargonium sidoides DC (Root) 80 ml 1mM AgNO3,20ml ethanolic plant extract solution, at room temperature,2hr. UV
XRD
SEM
TEM
SPB
FT-IR
EDS
11 to 90 nm
Spherical
FCC
22 Biosynthesis of Silver Nanoparticles Using Cucumis prophetarum Aqueous Leaf Extract and Their Antibacterial and Antiproliferative Activity Against Cancer Cell Lines Cucumis prophetarum Aqueous Leaf Extract
(Leaf)
aqueous leaf extract of C. prophet arum was added to silver nitrate solution, for 3 hours at room temperature,
shaker.
UV
DLS
XRD
SEM
FTIR
EDAX
30−50 nm
Spherical
FCC
23 Green synthesis of silver nanoparticles using phlomis leaf extract and investigation of their antibacterial activity phlomis leaf extract (leaf) 5.0 ml extract ,0.01 M of  AgNO3,room temperature. UV
XRD
TEM
SEM
FT-IR
25 nm
Spherical
Crystalline
24 Characterization of silver nanoparticles by green synthesis method using Pedalium murex leaf extract and their antibacterial activity Pedalium murex leaf extract (Leaf) 0.01M
AgNO3, 1-5ml leaf extract, 20 minutes at room temperature, shaker.
UV
XRD
DLS
TEM
FTIR
SEM
EDAX
430 nm
Crystalline
FCC
25 Antibacterial activity of silver nanoparticles synthesized by using whole plant extracts of Clitoria ternatea whole plant extracts of Clitoria ternatea 10ml extract, 50ml 1mM AgNO3, constant stirring at 50-60° C, incubated at room temperature for 40 hours. UV
XAS
TEM
SEM
20-30 nm
Spherical
crystalline
26 Antimicrobial activity of Silver Nanoparticles Synthesized by using Medicinal Plants Leaves of Svensonia hyderobadensis and the stem barks of Boswellia, Shorea species 1mM AgNO3, plant extract was added to make upto 200ml,25 min,18,000rpm,95°C. UV 30-40 nm
Crystal
FCC
27 Green synthesis and characterization of monodispersed silver nanoparticles obtained using oak fruit bark extract and their antibacterial activity the oak fruit bark extract 0.001M AgNO3,10 ml extract at room temperature. UV
XRD
TEM
20–25 nm
Spherical
FCC
28 Green synthesis of silver nanoparticles using carob leaf extract and its antibacterial activity carob leaf extract (leaf) 5 ml extract, 0.001M   AgNO3, stirring magnetically at room temperature. UV
XRD
SEM
FTIR
AAS
5 to 40 nm
Spherical
Crystalline and FCC
29 Biosynthesis of silver nanoparticles using stem bark extracts of Diospyros montana and their antioxidant and antibacterial activities stem bark extracts of Diospyros montana 1 mM AgNO3 solution and extract in 1:9 proportions and kept at room temperature for 30 min. UV
SEM
TEM
FTIR
DPPH
28 nm
Crystalline
FCC
30 Biosynthesis of Silver Nanoparticles by Bamboo Leaves Extract and Their Antimicrobial Activity Bamboo Leaves Extract
(Leaf)
5 ml extract,5 ml of 3 mM AgNO3 heated at 65◦C with continuous stirring. UV
EDX
TEM
XRD
400-450 nm
Spherical or non-spherical
Crystalline
31 Biogenic synthesis of silver nanoparticles using guava (Psidium guajava) leaf extract and its antibacterial activity against Pseudomonas aeruginosa Psidium guajava leaf extract (Leaf) 20 ml of 1 mM of AgNO3,
0.2 ml of leaf extract and stirred for 10 min at 30°
UV
TEM
10–90 nm
Spherical
FCC
32 Green and rapid synthesis of silver nanoparticles using Borago officinalis leaf extract: anticancer and antibacterial activities Borago officinalis leaf extract (Leaf) 10 ml extract,
1mM AgNO3 ,65 0C. The dried AgNPs were finally obtained after filtration, centrifugation and lyophilization.
UV
SPR
TEM
XRD
SAED
30 to 80 nm
spherical, hexagonal,and irregular
FCC
33 Green biosynthesis of silver nanoparticles using Quercus brantii (oak) leaves hydroalcoholic extract Quercus brantii (oak) leaves hydroalcoholic extract. 1mM AgNO3 as substrate, concentrated and freeze-dried plant extract,incubated at room temperature,pH 7,Reaction vol 50ml. TEM
DLS
mean size of 6 nm
Spherical
poly-dispersed
34 Green synthesis and characterization of silver nanoparticles using banana peel extract and their antimicrobial activity against representative microorganisms banana peel extract 1 ml extract,1 mM AgNO3 at pH 4.5, incubated at 30°C for 5 min. UV
XRD
FTIR
SEM
23.7 nm
Spherical
crystallinity
35 Green synthesis of silver nanoparticles using Rheum palmatum root extract and their antibacterial activity against Staphylococcus aureus and Pseudomonas aeruginosa Rheum palmatum root extract 5 ml extract,2mM AgNO3 solution, at room temperature,24hr TEM
SEM
FTIR
DLS
121 - 2 nm
hexagonal and spherical
Crystalline
36 Green Synthesis of Silver Nanoparticles, Their Characterization, Application, and Antibacterial Activity Sansevieria trifasciata Impatiens balsamina Pelargonium graveolens 3 ml filtrated Plant extract, 0.001M AgNO3, heated 75°C,24 hr UV
TEM
AFM
3 to 15 nm
Spherical
FCC
37 Green biosynthesis of silver nanoparticles using Curcuma longa tuber powder Curcuma longa tuber powder extract 20 ml Plant extract,0.001M AgNO3 ,24 hours, at room temperature (25°C). UV
XRD
TEM
SEM
EDXRF
FTIR
6.30 ± 2.64 nm
Crystalline
FCC
38 Ipomea carnea-based silver nanoparticle synthesis for antibacterial activity against selected human pathogens Ipomea carnea against selected human pathogens. The leaf extract (1,2,5 and 10% v/v) was mixed with enough 1 mM AgNO3 at room temperature. UV
DLS
AFM
TEM
FTIR
30 to 130 nm
Spherical
FCC
39 Antibacterial Activity of Synthesized Silver Nanoparticles from Tinospora cordifolia against Multi Drug Resistant Strains of Pseudomonas aeruginosa Isolated from Burn Patients Tinospora cordifolia 1 mM AgNO3,
15 ml extract ,15-20 minutes at 70-75°C.
UV
FTIR
TEM
EDX
XRD
 9 ± 36 nm
Crystal
Crystalline
40 Low-cost and eco-friendly synthesis of silver nanoparticles using coconut (Cocos nucifera) oil cake extract and its antibacterial activity coconut (Cocos nucifera) oil cake extract 4 ml extract, 96 ml 1 mm AgNO3, incubated for 8 h in a rotary shaker (180 rpm) at 260C. TEM 10–70 nm
Spherical
crystal
41 Rapid Biosynthesis of Silver Nanoparticles Using Cymbopogan Citratus (Lemongrass) and its Antimicrobial Activity Cymbopogan Citratus (Lemongrass) 1 mM AgNO3 and extract in 1:4 ratio under aseptic conditions. The pH 8.0, incubated at 37℃ for 24 hours. UV
TEM
EDX
NTA
20-40 nm
Spherical
FCC
42 Green Biosynthesis of Silver Nanoparticles Using Callicarpa maingayi Stem Bark Extraction Callicarpa maingayi Stem Bark Extraction 100 ml extract solution,100 ml 0.01M AgNO3, at room temperature(25°C) for 48hr UV
XRD
TEM
SEM
EDX
FTIR
12.40 ± 3.27 nm
Crystalline
FCC
43 Nanoscience and Nanotechnology/Biosynthesis of Silver Nanoparticles using Olea europaea Leaves Extract and its Antibacterial Activity Olea europaea Leaves Extract (leaf) 5 ml extract 0.001 M AgNO3, at room temperature. UV
TEM
SEM
XRD
FTIR
10 nm
Spherical
FCC
44 Synthesis of silver nanoparticles from Sargassum tenerrimum and screening phytochemicals for its antibacterial activity Sargassum tenerrimum and screening Photochemical 1 mM AgNO3,
5 ml seaweed extract, gradually heated at 90°C for 20 mins.
UV
FTIR
TEM
DLS
20 nm
Spherical
Crystal
45 Biosynthesis and Characterization of Silver Nanoparticles Using Leaf Extract Abutilon indicum Leaf Extract Abutilon indicum 10 ml Plant extract 1mM   AgNO3 at
room temperature.
UV
FTIR
SEM
50-100 nm
Crystal
Crystalline
46 Plant-mediated synthesis of silver nanoparticles using parsley (Petroselinum crispum) leaf extract: spectral analysis of the particles and antibacterial study Petroselinum crispum leaf extract 20mM AgNO3, Extract added drop wise to maintain total concentration 10mM,24 hr,10000 rpm for 30min. UV
XRD
DLS
TEM
FTIR
30 nm
Spherical
FCC
47 Sunlight-induced rapid and efficient biogenic synthesis of silver nanoparticles using aqueous leaf extract of Ocimum sanctum Linn. with enhanced antibacterial activity leaf extract of Ocimum sanctum 5ml extracts of (10%, 7%, 5%, and 3%) ,45 mL of 0.001M AgNO3 to make upto 50ml, kept Under sunlight. UV
TEM
10-20 nm
Crystal
FCC
48 Biosynthesis of Silver Nanoparticles using Garcinia mangostana Fruit Extract and their Antibacterial, Antioxidant Activity Garcinia mangostana Fruit Extract 1mM  AgNO3,10ml fruit extract,boiled for 15 minutes at 80°C. UV
TEM
 30 to 50nm
Spherical
FCC
49 Coleus aromaticus leaf extract mediated synthesis of silver nanoparticles and its bactericidal activity Coleus aromaticus leaf extract 90 ml 1mM AgNO3,
10 ml plant extract,
incubated at room temperature for 10 min.
UV
XRD
FTIR
TEM
SEM
40-50 nm
Crystal
Crystalline
50 Biosynthesis of silver nanoparticles using lemon leaves extract and its application for an antimicrobial finish on fabric lemon leaves extract 5ml extract,45 ml 0.002 M AgNO3, room temperature in dark. 1 hr UV
TEM
SEM
FTIR
AFM
XRD
30-50 nm
Spherical
FCC
51 Waste-grass-mediated green synthesis of silver nanoparticles and evaluation of their anticancer, antifungal and antibacterial activity Waste-grass-mediated green extract 15ml extract,1,2.5,5 mM AgNO3,
kept in dark at 28°C
Western blot 4-34 nm
Crystal
Crystalline

Table 3: Plant extracts with medicinal properties and are environmentally friendly but have chemically complex structures.

Preparation of Plant extracts:

Plant leaves were purchased fresh. They were carefully washed under running water and dried in the shade for 2-3 weeks before being ground to a fine powder with a mixer. The plant sample (5 g) was boiled for 15 minutes in 50 ml of distilled water at 60 ° C. Until filtering, the mixtures were cooled on Whattman No. 1 filter film, and the filtrates were used to produce silver nanoparticles.

Preparation of 1 mM AgNO3 solution

A precise conc. of 1 mM AgNO3 solution was prepared by dissolving 0.169 g AgNO3 in 1000 ml of double distilled water and stored in an Amber-colored bottle to avoid oxidation of Silver.

Synthesis of silver nanoparticles using plant leaf extract:

Aqueous AgNO3 (1mM) solution was freshly prepared and used to synthesize AgNPs. Each aqueous plant extract (10 ml) was mixed with 1 mM aqueous AgNO3 solution (90 ml) (for reduction of Ag+ ions into Ag0) and incubated overnight at room temperature in the dark (to prevent the photo-activation of AgNO3). The resulting reddishbrown solution serves as an indicator for the processing of AgNPs. The solutions derived from Silver nanoparticles have been purified for 15 minutes by repeated centrifugation at 10000 rpm. For the additional settlement of particles, the supernatant was then transferred to a clean dry beaker, and a repetitive centrifuge was used with a microfuge to dry and purify silver nanoparticles. The samples thus collected were dried and utilized for further characterization in an incubator. Silver nanoparticles were therefore produced in one green step.

The effect of various silver nitrate concentrations on Ag+ bioreduction:

From a 1M solution of AgNO3, various amounts of silver nitrate (1mM, 2mM, 3mM, 4mM, and 5mM) were prepared. 5 ml of the plant extract was mixed with 20 ml of solution from each AgNO3 concentration solution. After leaving the mixed solutions at 27°C (Room temperature) for one day, the maximum values were recorded using a UV-Vis Spectrophotometer.

The impact of pH on Ag+ bioreduction:

Since pH is essential for the effective synthesis of nanoparticles, this element increases the reactivity of plant extract with silver ions. The pH of the 1mM AgNO3 solution with plant extract was retained by adding a 1M sodium hydroxide solution. The impact of pH on the synthesis of AgNPs was investigated using reaction mixtures with varying pH (5, 6, 7, 8, and 9).

Time impact on Ag+ bioreduction:

25 mL of Syzygium aqueum leaf extract was blended with 75 ml of 1mM AgNO3 solution. The effect of time on silver nanoparticle synthesis was estimated from 30 minutes to 18 hours.

Phytochemical screening of plant extract

Phytochemical screening of the plant extracts was carried out by following standard procedures for different Phytoconstituents present in Syzygium aqueum leaf extract were performed as follows:

Hager's Test for Alkaloids –

A few drops of Hager's reagent were used for the test solution (saturated picric acid solution). The development of yellow precipitates confirms the presence of alkaloids.

Flavonoid assay (Shindo's assay):

A few magnesium turnings and a few drops of concentrate hydrochloric acid were applied to 2ml of the test solution before boiling for 5 minutes. The existence of flavonoids was denoted by the appearance of red pigment.

Test for Phenols:

A few drops of ferric chloride solution are applied to 2ml of the test solution to conduct the phenol test. The expression of phenols was shown by a red color.

Test for Tannins:

Tannins were determined by combining the test solution with a simple lead acetate solution. Formation of a white precipitate confirms the presence of Tannins.

Characterization of biosynthesized silver nanoparticles(AgNPs):

UV-Visible spectroscopy:

Ultraviolet-visible spectroscopy, also known as ultravioletvisible( UV-Vis) spectrophotometry, is a form of absorption spectroscopy that operates in the UV-visible spectral range. This means that visible and neighboring light (near UV and near-infrared (NIR)) are used. The observable field has a significant impact on the color perception of the chemicals involved. Molecules undergo an electrical transformation in this part of the electromagnetic spectrum. Absorption refers to a substance that absorbs light at a given wavelength. UV-Vis spectroscopy was used to monitor the color variations of the mixture over time. The UV-Vis spectrum was monitored at 54 wavelengths ranging from 200-700 nm. on a UV spectrophotometer.

UV-visible spectroscopy is utilized in this work to characterize metal nanoparticles and to comprehend surface Plasmons and electronic transitions in metal nanoparticles. To begin characterizing the synthesized silver nanoparticles, a tiny aliquot of material was placed in a UV–Visible spectrophotometer of absorption spectra at 300-700 nm. The UV-visible spectrophotometer is used to calculate the absorption spectrum of metal nanoparticles distributed in the water. The sample keeping cells were quartz cuvettes (cells) with a route length of 10 mm. Before employing UV radiation, the cuvettes are thoroughly cleaned with water, acetone, and dried.

Fourier Transform Infrared Spectroscopy (FTIR):

The technique is based on the fact that compounds and groups of compounds vibrate with characteristic frequencies. The molecule exposed to IR rays absorbs infrared energy at the characteristic frequency. Throughout FTIR analysis, a point in the sample is exposed to a modulated infrared (IR) beam. The resulting spectral pattern is then compared and analyzed to known signatures of materials identified in the FTIR-library. Silver nanoparticles and aqueous extracts were mixed with potassium bromide (KBr) and processed into a thin KBr disk under a pressure of 7845 KPa for 2 minutes, and all spectra were measured in the range of 4000 to 400 cm-1. The resultant spectrum is typical of the organic compounds contained in the sample. Without sample preparation, the method may instantly generate FTIR spectra of solid, semi-solid, and liquid materials in any shape. It can work with a minimum sample size of 15, minimal alignment, kinematic mount, and fast sample change. FTIR gives information on chemical bonding in a substance. Because the band intensities are related to the chemical concentration of the molecule, qualitative estimates are also achievable [25-28].

Scanning Electron Microscopy (SEM):

SEM is a high magnification microscope that creates images of the synthesized sample using a directed scanned electron beam. Thin films of the synthesized nanoparticles were made on a carbon-coated aluminum grid by simply dropping a small amount of sample onto the grid. An additional solution was made. It was removed using blotting paper and then the film was placed under a mercury-lamp for 5 minutes. EM images were observed at different levels of magnification. It's kind of an electron Microscope that images a sample in a raster scan pattern by scanning an electron beam. The electrons interact with the atoms present in the sample and generate signals which contain information about the surface topography, chemical content, and crystalline structure of the synthesized nanoparticles. Data is gathered across a predetermined region of the sample's surface, and a 2-dimensional picture displaying spatial variation in these characteristics is created. The crystals were analyzed and separated using SEM to determine the sizes and forms of the materials.

Transmission Electron Microscopy (TEM):

TEM is a microscopy technique in which an electron beam is passed through a highly thin specimen, interfering with it as it travels. The association of electrons emitted through the specimen creates an image, which is focused and magnified onto an imaging system. The morphology of the nanoparticles was studied using high-resolution pictures taken with a transmission electron microscope (TEM) set to 300kV. AgNPs were sonicated for 5 minutes before analysis, and a drop of properly diluted sample was put onto a carbon-covered copper grid. Blotting paper was used to remove excess solution. The liquid portion was then allowed to dry at ambient temperature.

Dynamic Light Scattering (DLS) and Zeta potential :

The particle size distribution of silver was determined using DLS measurements, and the stability of the synthesized AgNPs was evaluated using zeta potential analysis. Both measurements were taken with Zeta-sizer Nano series compact dispersion spectrometer.

Antibacterial activity of biosynthesized silver nanoparticles (AgNPs):

In recent years, antibiotic resistance has been a major public health issue. Unlike traditional and limited spectrum antibiotics, metallic silver nanoparticles have a deadly impact on a wide variety of bacteria and do not allow pathogens to build resistance. Biosynthesized Silver nanoparticles can be utilized as a powerful tool to control harmful infections caused by microorganisms at extremely low concentrations and as a preventative agent. While silver ions or silver salts have antibacterial properties, the mechanisms for the action of silver nanoparticles are not yet completely characterized. Nutrient agar and nutrient broth were used for the sub-culturing of the bacterial isolates. Mueller-Hinton agar was used for the bacterial sensitivity screening. The antibacterial screening of the synthesized nanoparticles was done by agar well diffusion and MIC.

Agar well diffusion method:

The antibacterial behavior of the synthesized nanoparticles was tested using the nutrient agar well diffusion system defined by Schillenger and Luke (1989). The nutrient agar medium was inoculated with 0.1mL of a fresh overnight nutrient broth culture of Staphylococcus aureus and poured onto sterile Petri plates. Six 6mm diameter wells were punched in each plate using a borer, and the plates were dried for 5 minutes. After keeping the plate at 27°C for 2 hours to enable diffusion of the controls and samples into the nutrient agar medium, the well-known antibacterial medication Ofloxin was used as a positive control for silver nanoparticles synthesized. The plates were incubated for 24 - 48 hours at 37°C. The test organism's exposure to any of the synthesized samples was demonstrated by a clear halo around the well. The diameters of the halos were determined with a translucent plastic ruler to calculate the degree of sensitivity. They were then tested to see whether they inhibited bacterial development. In each case, the diameters of inhibition zones were represented in millimeters of sensitivity.

Minimum Inhibitory Concentration (MIC):

Silver nanoparticle dilutions of 10,20,40,80,160 g/ml were prepared and used in this analysis. 200μl of bacterial suspension was inoculated into each test tube containing varying amounts of AgNPs and a comparable volume of Muller Hinton Broth (MHB) and incubated for 24 hours at 37°C. The technique also contained a positive control (tube containing only bacterial suspension and nutrient media without nanoparticles) and negative control (tube containing nanoparticles and nutrient medium without bacterial suspension) [29, 30].

Conclusion

Many attempts have been made over the previous decades to create novel technologies for green synthesis. Live organisms offer a great potential for nanomaterial synthesis which may be used in various areas and in particular in healthcare. Organisms from basic to very sophisticated eukaryotes can be utilized to produce the appropriate size and form of nanoobjects. Prokaryotes are simplest of biomass forms and are easier to modify genetically to generate more desirable synthesis ingredients. However, in comparison to others, the culture of bacteria and manufacturing at a big scale remains challenging. Bacteria have therefore been explored as initial nano fabrics in the development of noble metal nanoparticles as a first attempt. The poor synthesis rates of fungus and algae were nonetheless determined by the restricted size and shape distribution available. Fungi offer an appropriate choice for big green nano production. They are easy to handle and exude vast quantities of enzymes essential to reduce downstream processing. Filamentous metal tolerance, strong binding capacity, and intracellular uptake are also found. Nevertheless, it is considerably more difficult for eukaryotes to manipulate genes to press certain enzymes to accelerate synthesis.

Most recently, several studies were undertaken on potential plant extracts. Due to their simple availability, comfort of mind, and costeffectiveness, the numbers of publications published in this sector have risen exponentially during the previous few years. In addition, plants contain the most effective phytochemicals and hence improve the pace of synthesis. The distribution in size and form of the nanoparticles derived from TEM investigations reveals that several factors impact their morphologies, including the plant extract origin, solution pH, and reaction temperature. Green-produced silver nanoparticles have unrivaled uses that have important features of nanotechnology. For the production of nanoparticles that use plants, it can be of benefit to other biological entities, which can take time to use microorganisms to maintain their culture and lose their potential for nanoparticles synthesis. However, it remains the subject of research to achieve the uniform size and form distribution of AgNPs.

Regardless of the manufacturing process, AgNPs are used as antibacterial agents, electrochemical sensors, and biosensors in the fields of medicine, healthcare, agriculture, and biotechnology, and are highly bactericidal against both Gram-positive and Gram-negative pathogens. Antibiotics are effective against many drug-resistant bacteria. As a ready-made medicine, they can be used to treat many infections. Silver nanoparticles in drug delivery systems generally increase solubility, stability, and biodistribution, thereby increasing their effectiveness. In the presence of nanoparticles, drug uptake has increased many times, so AgNPs can be utilized as a drug delivery system. Many papers on silver nanoparticles synthesis utilizing plant extracts like the one just described have been published. There is still a need to uncover the capability of natural reductions to create silver nanoparticles that have not previously been examined, which can be economically feasible, economical, and environmentally favorable.

Therefore, the utilization of plant extract for synthesis in the next decades can have an incredible effect.

Statements & Declarations

Funding:

The authors declare that no funding, grants, or other support were received during the creation of this manuscript.

Competing Interests:

The authors have no material conflicts of interest, either financial or otherwise.

Contribution of authors

All authors have invested their time, effort and knowledge into designing, drafting and editing this manuscript. The final draft was agreed upon mutual satisfaction after having gone through multiple rigorous revisions.

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Citation: Thirunavukarasu K, Siham MA, Jayachandran J, Rao M, Raj G, et al. (2023) Green Synthesis of Silver Nanoparticles. J Biotechnol Biomater, 13: 324. DOI: 10.4172/2155-952X.1000324

Copyright: © 2023 Thirunavukarasu K, et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

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