Green Synthesis of AgNPs Stabilized with biowaste and their antimicrobial activities

Jasuja, Nakuleshwar Dut; Gupta, Deepak Kumar; Reza, Mohtashim; Joshi, Suresh C.

doi:10.1590/S1517-83822014000400024

Abstract

In the present study, rapid reduction and stabilization of Ag+ ions with different NaOH molar concentration (0.5 mM, 1.0 mM and 1.5 mM) has been carried out in the aqueous solution of silver nitrate by the bio waste peel extract of P.granatum. Generally, chemical methods used for the synthesis of AgNPs are quite toxic, flammable and have adverse effect in medical application but green synthesis is a better option due to eco-friendliness, non-toxicity and safe for human. Stable AgNPs were synthesized by treating 90 mL aqueous solution of 2 mM AgNO3 with the 5 mL plant peels extract (0.4% w/v) at different NaOH concentration (5 mL). The synthesized AgNPs were characterized by UV-Vis spectroscopy, TEM and SEM. Further, antimicrobial activities of AgNPs were performed on Gram positive i.e. Staphylococcus aureus, Bacillus subtilius and Gram negative i.e. E. coli, Pseudomonas aeruginosa bacteria. The AgNPs synthesized at 1.5 mM NaOH concentration had shown maximum zone of inhibition (ZOI) i.e. 49 ± 0.64 in E. coli, whereas Pseudomonas aeruginosa, Staphylococcus aureus and Bacillus subtilius had shown 40 ± 0.29 mm, 28 ± 0.13 and 42 ± 0.49 mm ZOI respectively. The MIC value of 30 g/mL observed for E. coli Whereas, Staphylococcus aureus, Bacillus subtilius and Pseudomonas aeruginosa had shown 45 µg/mL, 38 µg/mL, 35 µg/mL respectively. The study revealed that AgNPs had shown significant antimicrobial activity as compared to Streptomycin.

Silver nanoparticles; biowaste; antibacterial activity; MIC; SEM; TEM

RESEARCH PAPER

Green Synthesis of AgNPs Stabilized with biowaste and their antimicrobial activities

Nakuleshwar Dut Jasuja^I; Deepak Kumar Gupta^II; Mohtashim Reza^III; Suresh C. Joshi^IV

^ISchool of Science, Suresh Gyan Vihar University, Mahal, Jagatpura, Jaipur, India

^IICentre for Converging Technologies, University of Rajasthan, Jaipur, India

^IIIUniversity Science Instrumentation Centre (USIC), University of Rajasthan, Jaipur, India

^IVDepartment of Zoology, University of Rajasthan, Jaipur, India

^{Correspondence} Correspondence: N.D. Jasuja School of Science Suresh Gyan Vihar University Mahal, Jagatpura Jaipur, India E-mail: nakuljasuja@gmail.com

ABSTRACT

In the present study, rapid reduction and stabilization of Ag+ ions with different NaOH molar concentration (0.5 mM, 1.0 mM and 1.5 mM) has been carried out in the aqueous solution of silver nitrate by the bio waste peel extract of P.granatum. Generally, chemical methods used for the synthesis of AgNPs are quite toxic, flammable and have adverse effect in medical application but green synthesis is a better option due to eco-friendliness, non-toxicity and safe for human. Stable AgNPs were synthesized by treating 90 mL aqueous solution of 2 mM AgNO₃ with the 5 mL plant peels extract (0.4% w/v) at different NaOH concentration (5 mL). The synthesized AgNPs were characterized by UV-Vis spectroscopy, TEM and SEM. Further, antimicrobial activities of AgNPs were performed on Gram positive i.e. Staphylococcus aureus, Bacillus subtilius and Gram negative i.e. E. coli, Pseudomonas aeruginosa bacteria. The AgNPs synthesized at 1.5 mM NaOH concentration had shown maximum zone of inhibition (ZOI) i.e. 49 ± 0.64 in E. coli, whereas Pseudomonas aeruginosa, Staphylococcus aureus and Bacillus subtilius had shown 40 ± 0.29 mm, 28 ± 0.13 and 42 ± 0.49 mm ZOI respectively. The MIC value of 30 g/mL observed for E. coli Whereas, Staphylococcus aureus, Bacillus subtilius and Pseudomonas aeruginosa had shown 45 µg/mL, 38 µg/mL, 35 µg/mL respectively. The study revealed that AgNPs had shown significant antimicrobial activity as compared to Streptomycin.

Key words: Silver nanoparticles, biowaste, antibacterial activity, MIC, SEM, TEM.

Introduction

Recently, nanoparticles are used in multidisciplinary areas such as biomedicine, biocatalysis, electronics, chemistry and energy due to their extensive applicability. These particles have small size (1-100 nm) and elevated surface area which resulted in increase reactivity, spectacular alteration in optical, electronic and chemical properties which are significantly different from bulk materials (Catauro et al., 2004; Stevanovic et al., 2012; Vijayakumar et al., 2013). Silver nanoparticles (AgNPs) have more concerned as compare to other metallic nanoparticles (MNPs) due to their unique properties like magnetic and optical polarizability, electrical conductivity and antimicrobial activities (Evanoff and Chumanov, 2005). As Inorganic agents (i.e. Ag) have already been used in various medical and industrial processes for an inhibitory effect towards many bacterial strains and microorganisms (Saxena et al., 2010; Jain et al., 2009; Latha and Kannabiran, 2006; Krishnamurthy et al., 2012). AgNPs can be used to destroy microorganisms on textile fabrics (Vivek et al., 2011; White et al., 2012) or they can be employed for water treatment (Binupriya et al., 2010). The capability of pathogenic bacteria to get resistance against antibacterial agents is a tremendous problem in medical practice which limits the efficacy of these drugs (Quelemes et al., 2013). These drawbacks give researchers tremendous opportunities to develop new substances like AgNPs to combat them. Green synthesis of nanoparticles using plants or plant derived extracts is good option over chemical and physical methods because it is rapid, non toxic, eco-friendly, cost effective, don't require high pressure, temperature, toxic chemicals and compatible for pharmaceutical and biomedical applications (Vivek et al., 2011). Plant-based nanoparticles synthesis has advantages over other biological methods because of their rapid reaction rate for the synthesis of nanoparticles (White et al., 2012).

In the present study, rapid reduction and stabilization of Ag+ ions with different NaOH molar concentration in the aqueous solution of silver nitrate by the bio waste peel extract of P.granatum reported. Further, the anti-bacterial activity of these biologically synthesized nanoparticles performed against Gram positive (G+) and Gram negative (G-) bacteria.

Experimental

Punica granatum were collected from the National Institute of Ayurveda, Jaipur. Further, plant was identified and registered (Reg. No. RUBL21110) by Herbarium, Department of Botany, University of Rajasthan, Jaipur, India. Punica granatum peels were removed and dried under shade at room temperature for about 10 days. The dried peels were powdered by mechanical grinder and sieved to give particle size 50-150 mm. Powder (34 g) was filled in the thimble and extracted successively with 70% ethanol in soxhlet extractor at 40 °C for 48 h. The extracts were concentrated to dryness using rotary evaporator and used as reducing and capping agent. The stable AgNPs were synthesized by treating 90 mL aqueous solution of AgNO3 (2 mM) with 5 mL filtered (0.45 m) peels extract (0.4% w/v) and 5 mL NaOH of different molar concentration (0.5 mM, 1.0 mM and 1.5 mM) at room temperature (25 °C) for 20 min (Vasireddy et al., 2012). The obtained solutions were centrifuged at 15,000 rpm for 20 min (Vijayakumar et al., 2013; Gan et al., 2012) subjected to purification and dried for the analysis of the prepared AgNPs. UV-Vis spectral analysis was done between a range of 300-600 nm using a double-beam spectrophotometer (Hitachi, U-3010) with all the samples dispersed in distilled water and kept in a quartz cuvette with a path length of 10 mm (Vasireddy et al., 2012). Scanning electron microscopy (Carl Zeiss EVO® 18 electron microscope) and Transmission electron microscopy (FEI Tecnai T20 TEM System) for the morphological analysis of the prepared AgNPs samples was performed (Vasireddy et al., 2012).

Screening of nanoparticles using disc diffusion method

The antibacterial activities of the synthesized AgNPs were studied against four bacteria, viz. Staphylococcus aureus (G+), Bacillus subtilis (G+), Escherichia coli (G-), and Pseudomonas aeruginosa (G-) by discs diffusion method (Gould, 1952; Rios et al., 1988; Kim et al., 2007). Standard size Whatman No. 1 filter paper discs, 6.0 mm in diameter, sterilized by moist heat at 121 lb in an autoclave for 15 min were used to determine antimicrobial activity of AgNPs (Bhadauria and Kumar, 2012). Muller Hinton Agar (MHA) medium was poured into autoclaved petriplates and allowed to solidify. The homogeneous suspension (100 µL) of test inoculums 1-5 x 10⁶ cfu/mL was used for inoculation over the respective agar medium plates. Sterilized filter paper discs were impregnated with 50 µL of AgNPs (100 µg/mL) and placed over the surface of agar plates containing bacterial culture. Negative controls were prepared in the same way but using 50 µL of pure solvent (autoclaved distilled water) on sterile discs. Similarly, The disc of control antibiotics i.e. Streptomycin sulphate (100 g/mL) for antibacterial activity were also aseptically placed over the seeded agar plates for comparison of antibacterial activity of AgNPs. The plates were incubated at 37 °C for 24 h after which the average diameter of the inhibition zone surrounding the disk was measured with a ruler with up to 1 mm resolution. The mean and standard deviation (SD) reported for each type of nanoparticles (0.5 mM, 1.0 mM, 1.05 mM) and with each microbial strain were based on six replicates (Qi et al., 2004). The activity index was calculated on the basis of the size of the inhibition zone by the following formula:

Determination of the minimum inhibitory concentration (MIC)

The lowest concentration of AgNPs that exhibits antibacterial activity was quantified by modified tube dilution method (Qi et al., 2004). The MIC was determined based on batch cultures containing varying concentration of AgNPs in suspension (20-100 µg/mL) (Ruparelia et al., 2008). Muller Hinton broth media were poured into a 16- by 125-mm glass tubes and autoclaved. A standard suspension of test bacterium (~0.5 McFarland standard), was prepared for bacterial inoculums (1-5 x 10⁶ cfu/mL). The Ag-NPs solutions of different pH (9-11) and concentration were diluted with Mueller-Hinton broth and inoculated with the tested bacterial suspension. The tubes were then incubated to determine the MIC. The high rotary shaking speed was selected to minimize aggregation and settlement of the nanoparticles over the incubation period. Lower rpm setting during incubation may cause underestimation of the antimicrobial activity of the nanoparticles (Ruparelia et al., 2008). All the experiments were carried out in triplicate. The average bacterial growth was measured as increase in absorbance at 600 nm determined using a spectrophotometer (Thermo Spectronic, Helios Epsilon, USA). The experiments included a positive control (tubes containing nanoparticles and Mueller-Hinton broth, devoid of inoculum) and a negative control (tubes containing inoculum and Mueller-Hinton broth, devoid of nanoparticles. The negative controls indicated the microbial growth profile in the absence of nanoparticles. Afterwards, the growth in all tubes at different concentrations of AgNPs was compared with that of the nanoparticles-free control in order to determine inhibition after 24 and 48 hours of incubation.

Statistical analysis

Statistical analysis was carried out by SPSS version 16.0 software. The result express as arithmetic mean ± SD.

Results and Discussion

In the present study, the AgNO₃ solution immediately turned dark brown after the addition of P. garnatum peel extract as a reducing and stabilizing agent in all of the samples of different NaOH molar concentrations, which shows the formation of AgNPs (Figure 1). The oxidation reaction of phenol groups (Figure 2 a-d) in peel extract was responsible for the reduction of silver ions (Wang et al., 2007; Soundarrajan et al., 2012). It is observed that addition of 0.5 mM (I) NaOH showed broadening of the surface plasmon resonance (SPR) peak at 406 nm. Whereas, addition of 1.0 mM (II) NaOH shifted the absorption peak at 401 nm and 1.5 mM (III) NaOH resulted in a blue shift of λmax to 395 nm (Figure 3). Study revealed that increase in NaOH concentration may accelerate the nucleation process which increases the absorption intensity and the shifting of absorption peaks may be due to decrease in the particle size of Ag-NPs (Vasireddy et al., 2012). Further, the phenolic groups of flavonoids and glycosides (Figure 2 a-d) of P. granatumpeels (Van Elswijk et al., 2004; Jasuja et al., 2012) act as a reducing agent may be ionized at higher molar NaOH concentration which leads rapid reduction reaction and synthesized spherical particles of AgNPs. The mechanistic reaction of the formation of AgNPs is expressed in Figure 4.

The electrons moves freely in conduction band and valence band which lie very close to each other in Metal NPs i.e. AgNPs. The collective oscillations of electrons (Plasmon) generate surface plasmon resonance (SPR) absorption band (Taleb et al., 1998; Noginov et al., 2007; Link and El-Sayed, 2003; Kreibig and Vollmer, 1995) occurring due to the resonance with the incident light wave (Nath et al., 2007). The electric field of an incident wave induces a polarization of these electrons with respect to much heavier ionic core of AgNPs (Das et al., 2009). UV-Visible wave induces a polarization of the loosely bound surface electron due to low penetration depth (approximate 50 nm). As a result the net charge difference take place which acts as a restoring force. This creates a dipolar oscillation of all the electrons with the same phase (Inbakandan et al., 2010). A strong absorption takes place when the frequency of the electromagnetic field becomes resonant with the coherent electron motion, which may be the origin of dark brown colour. Due to the localized SPR, Metal NPs Shows strong absorption peak while bulk metal particles shows propagating SPR. This absorption strongly depends on the particle size, dielectric medium and chemical surroundings (Noginov et al., 2007; Link and El-Sayed, 2003; Umashankari et al., 2012). The UV/Vis absorption spectra of the silver nano particles dispersed in water is shown in the Figure 1. When the size of particles is smaller than the average free path of the electrons (52 nm for silver metal (Abdullin et al., 1998; Henglein, 1998), silver dielectric function modifies which leads to an increased Plasmon bandwidth with decreasing size of particle (Baset et al., 2011).

SEM and TEM analysis

Figures 5 (A) and ^(B) showed the SEM and typical bright-field TEM micrographs of the synthesized AgNPs. The micrographs of AgNPs found polydisperse and mostly spherical in shape. In some places, Agglomeration of AgNPs may be due to possible sedimentation at a later time. The average size estimated was 15 nm for AgNPs. It is reported earlier that proteins can bind to nanoparticles either through free amine groups and therefore, stabilization of the AgNPs by protein is a possibility (Daniel and Astruc, 2004; Kawsar et al., 2009; Shahverdi et al., 2007; Chien et al., 2007; Ahmad and Sharma, 2012).

Antibacterial activity

The study demonstrated the synergistic activity of AgNPs against gram-positive and gram-negative bacteria. The maximum inhibitory effects of AgNPs observed when prepared with higher NaOH (1.5 mM) molar concentration. The study revealed that AgNPs (50 µg/mL) had shown significant inhibitory effect against E.coli and Bacilus subtilius i.e. 49 ± 0.64 and 42 ± 0.49 mm when compared with Streptomycin (100 µg/mL) i.e. 43 ± 0.52 and 40 ± 0.31 mm respectively Figure 6 (a-d) and Table 1.

Thumbnail

The MIC value of 30 µg Ag/mL was observed in E. coli. Whereas, Staphylococcus aureus, Bacillus subtilius and Pseudomonas aeruginosa had shown 45 µg/mL, 38 g/mL, 35 µg/mL MIC respectively (Table 2). AgNPs had shown more than 1 active index for E. coli and Bacillus subtilius when compared with standard drug (Figure 7).

Thumbnail

The screening results indicated that AgNPs disc (50 µg/mL) were more active against gram-negative bacteria i.e. Escherichia coli with a mean zone of inhibition 49 ± 0.64 mm (Table 1). This may be due to the differences in the cell wall of gram-positive and gram negative bacteria. The cell wall of gram positive bacteria is wider than the gram-negative bacteria (Thiel et al., 2007; Martinez-Castanon et al., 2008; Kim et al., 2007). Gram negative bacteria have a layer of lipopolysaccharide (LPS) which surrounded by a thin layer of peptidoglycan (7-8 nm) (Kreibig and Vollmer, 1995). The overall charge of bacterial cells at biological pH values is negative because of excess number of carboxylic groups, which upon dissociation make the cell surface negative (Raffi et al., 2008). Weak positive charges present on silver nanoparticles (Schultz et al., 2000) are attracted towards negative charges on the LPS. Moreover, Excess formation of free radicals may attack LPS which lead to a breakdown of membrane function. Increased permeability of the cell membrane or leakage of cell contents could be caused by Reactive Oxygen Species (ROS) (Mendis et al., 2005). This also leads morphological changes of bacterial cells and growth inhibition (Amro et al., 2000; Danilczuk et al., 2006; Sondi and Salopek-Sondi, 2004). It is logical to state that binding of the nanoparticles to the bacteria depends on the surface area available for interaction. Nanoparticles have larger surface area available for interaction which enhances bactericidal effect than the large sized particles (Raffi et al., 2008) eg. Inorganic substances or antibiotics; hence AgNPs exhibits more toxicity to the microorganism (Baker et al., 2005).

Conversely, the cell wall in gram-positive bacteria is composed of a thick layer (about 20-80 nm) of peptidoglycan, consisting of linear polysaccharide chains cross-linked by short peptides to form a three dimensional rigid structure (Wiley et al., 2006). The rigidity and extended cross-linking not only provide the cell walls with fewer anchoring sites for the silver nanoparticles but also make them difficult to penetrate. Earlier studies also revealed that silver species release Ag+ ions which interact with the thiol groups of bacterial proteins, may retard or change the replication of DNA (Marini et al., 2007; Martinez-Castanon et al., 2008). Somehow, it may be the reason that the G+ Bacillus subtilius also inhibited by AgNPs significantly when compared with control antibiotics.

Conclusions

It is concluded that the extract of P. granatum are capable of producing stable AgNPs by reduction of aqueous Ag+ ions in to Ag0. This green chemistry approach toward the synthesis of AgNPs has various advantages i.e rapid reduction, economic viability etc. Applications of such eco-friendly nanoparticles in bactericidal, wound healing, medical and electronic applications, makes this method potentially exciting for the large-scale synthesis of other inorganic nanomaterials (Ankanna et al., 2010) e.g. Au, Fe, Zn, Cu, Graphenes etc. The increase in zone of inhibition reported in this study was dependent on the concentration of nanoparticles due to higher NaOH molar concentration. Attachment of nanoparticles by cell wall of bacteria would be due to negative charges and specific functional groups on the bacterial surface. AgNPs after penetration into the bacterial cell may disturb the rigidity of cell wall or lipopolysaccharides membrane, inactivate their transport system, enzymes functioning, generate H₂O₂ which resulted in bacterial death. The silver nanoparticles synthesized via green route are highly toxic to G-ve and somehow for G+ve bacteria can be used in medical applications (Singh et al., 2010).

Acknowledgments

The authors are sincerely thankful to Mr. Sunil Sharma, Chancellor and Dr. Sudhanshu Sharma, Chief Mentor of Suresh Gyan Vihar University for providing a platform for this research. The authors also appreciation vows to USIC, University of Rajasthan, Jaipur, India for providing SEM and TEM facilities.

Submitted: December 21, 2013

Approved: April 17, 2014

All the content of the journal, except where otherwise noted, is licensed under a Creative Commons License CC BY-NC.

Abdullin SN, Stepanov AL, Osin YU, Khaibullin IB (1998) Kinetics of silver nanoparticle formation in a viscous-flow polymer. Surface science 395:242-245.
Ahmad N, Sharma S (2012) Biosynthesis of silver nanoparticles from biowaste pomegranate peels. International Journal of Nanoparticles 5:185-195.
Amro NA, Kotra LP, Mesthrige KW, Bulychev A, Mobashery S, Liu G (2000) High-resolution atomic force microscopy studies of the Escherichia coli outer membrane: Structural basis for permeability. Langmuir 16:2789-2796.
Ankanna S, Prasad TNVKV, Elumalai EK, Savithramma N (2010) Production of biogenic silver nanoparticles using boswellia ovalifoliolata stem bark. Digest Journal of Nanomaterials & Biostructures 5:369-372.
Baker C, Pradhan A, Pakstis L, Pochan DJ, Shah SI (2005) Synthesis and antibacterial properties of silver nanoparticles. J Nanosci Nanotechnol 5:244-249.
Baset S, Akbari H, Zeynali H, Morteza S (2011) Size measurement of metal and semiconductor nanoparticles via uv-vis absorption spectra. Digest J Nanomater Biostructures 6:709-716.
Bhadauria S, Kumar P (2012) Broad spectrum antidermatophytic drug for the control of tinea infection in human beings. Mycoses 55:339-343.
Binupriya AR, Muthuswamy S, Soon-In Y (2010) Myco-crystallization of silver ions to nano-sized particles by live and dead cell filtrates of Aspergillus oryzae var viridis and its bactericidal activity towards Staphylococcus aureus KCCM 12256. Ind Eng Chem Res 49:852-858.
Catauro M, Raucci MG, De Gaaetano F, Marotta A (2004) Antibacterial and bioactive silver-containing Na₂O•CaO•2SiO₂ glass prepared by sol-gel method. J Mater Sci 15:831-837.
Chien SW, Wang MC, Huang CC, Seshaiah K (2007) Characterization of humic substances derived from swine manure-based compost and correlation of their characteristics with reactivities with heavy metals. J Agric Food Chem 55:4820-4827.
Daniel MC, Astruc D (2004) Gold Nanoparticles: Assembly, Supramolecular Chemistry, Quantum-Size-Related Properties and Applications toward Biology, Catalysis and Nanotechnology. Chem Rev 104:293-346.
Danilczuk M, Lund A, Sadlo J, Yamada H, Michalik J (2006) Conduction electron spin resonance of small silver particles. Spectrochimica Acta A 63:189-191.
Das R, Nath SS, Chakdar D, Gope G, Bhattacharjee R (2009) Preparation of silver nanoparticles and their characterization. J Nanotechnol 5:1-6.
Evanoff Jr DD, Chumanov G (2005) Synthesis and optical properties of silver nanoparticles and arrays. Chem Phys Chem 6:1221-1231.
Gan PP, Ng SH, Huang Y, Li SF (2012) Green synthesis of gold nanoparticles using palm oil mill effluent (POME): A low-cost and eco-friendly viable approach. Bioresour Technol 113:132-137.
Gould JC (1952) The determination of bacterial sensitivity of antibiotics. Edinburgh Med J 59 :178-199.
Henglein A (1998) Colloidal silver nanoparticles: Photochemical preparation and interaction with O₂, CCl₄, and some metal ions. Chem Mater 10:444-450.
Inbakandan D, Venkatesan R, Khan SA (2010) Biosynthesis of gold nanoparticles utilizing marine sponge Acanthella elongata (Dendy, 1905). Colloids Surf B Biointerfaces 81:634-639.
Jain D, Daima HK, Kachnwaha S, Kothari SL (2009) Synthesis of plant-mediated silver nanoparticles using papaya fruit extract and evaluation of their anti microbial activities. Digest Journal of Nanomaterials and Biostructures 4:557-563.
Jasuja ND, Saxena R, Chandra S, Sharma R (2012) Pharmacological characterization and beneficial uses of Punica granatum Asian J Plant Sci 11:251-267.
Kawsar SMA, Mostafa G, Huq E, Nahar N, Ozeki Y (2009) Chemical Constituents and Hemolytic Activity of Macrotyloma uniflorum L. International Journal of Biological Chemistry 3:42-48.
Kim JS, Kuk E, Yu KN, Kim JH, Park SJ, Lee HJ, Kim SH, Park YK, Park YH, Hwang CY, Kim YK, Lee YS, Jeong DH, Cho MH (2007) Antimicrobial effects of silver nanoparticles. Nanomedicine 3:95-101.
Kreibig U, Vollmer M (1995) Optical Properties of Metal Clusters Springer Berlin, 535.
Krishnamurthy NB, Nagaraj B, Barasa M, Liny P, Dinesh R (2012) Green synthesis of gold nanoparticles using Tagetes erectal (mari gold) flower extract and evaluation of their antimicrobial activities. Int J Pharm Bio Sci 3:212-221.
Latha PS, Kannabiran K (2006) Antimicrobial activity and phytochemicals of Solanum trilobatum Linn. Afr J Biotechnol 5:2402-2404.
Link S, El-Sayed MA (2003) Optical Properties and ultrafast dynamics of metallic nanocrystals. Annu Rev Phys Chem 54:331-366.
Marini M, De Niederhausern N, Iseppi R, Bondi M, Sabia C, Toselli M, Pilati F (2007) Antibacterial activity of plastics coated with silver-doped organic-inorganic hybrid coatings prepared by sol-gel processes. Biomacromolecules 8:1246-1254.
Martinez-Castanon GA, Nino-Martinez N, Martinez-Gutierrez F, Martinez-Mendoza JR, Ruiz F (2008) Synthesis and antibacterial activity of silver nanoparticles with different sizes. Journal of Nanoparticle Research 10:1343-1348.
Mendis E, Rajapakse N, Byun HG, Kim SK (2005) Investigation of jumbo squid (Dosidicus gigas) skin gelatin peptides for their in vitro antioxidant effects. Life Sci 77:2166-2178.
Nath SS, Chakdar D, Gope G (2007) Synthesis of CdS and ZnS quantum dots and their applications in electronics. Nanotrends 2:1-5.
Noginov MA, Zhu G, Bahoura M, Adegoke J, Small C (2007) The effect of gain and absorption on surface plasmos in metal nanoparticles. Applied Physics B-Lasers and Optics 86:455-460.
Qi L, Xu Z, Jiang X, Hu C, Zou X (2004) Preparation and antibacterial activity of chitosan nanoparticles. Carbohydr Res 339:2693-2700.
Quelemes PV, Araruna FB, de Faria BE, Kuckelhaus SA, da Silva DA, Mendonça RZ, Eiras C, Dos S Soares MJ, Leite JR (2013) Development and antibacterial activity of cashew gum-based silver nanoparticles. Int J Mol Sci14:4969-4981.
Raffi M, Hussain F, Bhatti TM, Akhter JI, Hameed A, Hasan MM (2008) Antibacterial characterization of silver nanoparticles against E coli ATCC-15224. J Mater Sci Technol 24:192-196.
Rios JL, Recio MC, Villar A (1988) Screening methods for natural products with antimicrobial activity: a review of the literature. J Ethnopharmacol 23:127-149.
Ruparelia JP, Chatterjee AK, Duttagupta SP, Mukherji S (2008) Strain specificity in antimicrobial activity of silver and copper nanoparticles. Acta Biomaterialia 4:707-716.
Saxena A, Tripathi RM, Singh RP (2010) Biological synthesis of silver nanoparticles by using onion (Allium cepa) extract and their antibacterial activity. Digest J Nanomater Biostructures 5:427-432.
Schultz S, Smith DR, Mock JJ, Schultz DA, (2000) Single-target molecule detection with no bleaching multicolor optical immunolabels. Proc Natl Acad Sci 97:996-1001.
Shahverdi AR, Minaeian S, Shahverdi HR, Jamalifar H, Nohi AA (2007) Rapid synthesis of silver nanoparticles using culture supernatants of Enterobacteria: A novel biological approach. Process Biochemistry 42:919-923.
Singh A, Jain D, Upadhyay MK, Khandelwal N, Verma HN (2010) Green synthesis of silver nanoparticles using argimone mexicana leaf extract and evaluation of their antimicrobial activities. Digest Journal of Nanomaterials & Biostructures (DJNB) 5:483-489.
Sondi I, Salopek-Sondi B (2004) Silver nanoparticles as antimicrobial agent: a case study on E coli as a model for Gram-negative bacteria. J Colloid Interface Sci 275:177-182.
Soundarrajan C, Sankari A, Dhandapani P, Maruthamuthu S, Ravichandran S, Sozhan G, Palaniswamy N (2012) Rapid biological synthesis of platinum nanoparticles using Ocimum sanctum for water electrolysis applications. Bioprocess Biosyst Eng 35:827-833.
Stevanovic M, Savanovic I, Uskokovic V, Skapin SD, Bracko I, Jovanovic U, Uskokovic D (2012) A new, simple, green and one-pot four-component synthesis of bare and poly(α,γ,l-glutamic acid)-capped silver nanoparticles. Colloid Polym Sci 290:221-231.
Taleb A, Petit C, Pileni MP (1998) Optical Properties of self assembled 2D and 3D superlattices of silver nanoparticles. J Phys Chem B 102:2214-2220.
Thiel J, Pakstis L, Buzby S, Raffi M, Ni C, Pochan DJ, Shah SI (2007) Antibacterial properties of silver-doped titania. Small 3:799-803.
Umashankari J, Inbakandan D, Ajithkumar TT, Balasubramanian T (2012) Mangrove plant, Rhizophora mucronata (Lamk, 1804) mediated one pot green synthesis of silver nanoparticles and its antibacterial activity against aquatic pathogens. Aquat Biosyst 8:11.
Van Elswijk DA, Schobel UP, Lansky EP, Irth H, van de Greef J (2004) Rapid dereplication of estrogenic compounds in pomegranate (Punica granatum) using on-line biochemical detection coupled to mass spectrometry. Phytochemistry 65:233-241.
Vasireddy R, Paul R, Mitra AK (2012) Green synthesis of silver nanoparticles and the study of optical properties. Nanomater Nanotechnol 2:1-6.
Vijayakumar M, Priya K, Nancy FT, Noorlidaha A, Ahmed ABA (2013) Biosynthesis, characterisation and anti-bacterial effect of plant-mediated silver nanoparticles using Artemisia nilagirica. Ind Crops Prod 41:235-240.
Vivek M, Kumar PS, Steffi S, Sudha S (2011) Biogenic silver nanoparticles by Gelidiella acerosa extract and their antifungal effects. Avicenna J Med Biotechnol 3:143-148.
Wang W, Chen Q, Jiang C, Yang D, Liu X, Xu S (2007) One step synthesis of biocompatible gold nanoparticles using gallic acid in the presence of poly-(N-vinyl-2-pyrrolidone). Colloids Surf A 301:73-79.
White GV, Kerscher P, Brown RM, Morella JD, McAllister W, Dean D, Kitchens CL (2012) Green synthesis of robust, biocompatible silver nanoparticles using garlic extract. J Nanomater 730746:1-12.
Wiley BJ, Im SH, Li ZY, McLellan J, Siekkkinen A, Xia Y (2006) Maneuvering the Surface Plasmon Resonance of Silver Nanoparticles through Shape- Controlled Synthesis. J Phys Chem B 110:15666-15675.

Correspondence:

N.D. Jasuja

School of Science

Suresh Gyan Vihar University

Mahal, Jagatpura Jaipur, India

E-mail:

nakuljasuja@gmail.com

Publication Dates

Publication in this collection
13 Feb 2015
Date of issue
Dec 2014

History

Received
21 Dec 2013
Accepted
17 Apr 2014

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Abdullin SN, Stepanov AL, Osin YU, Khaibullin IB (1998) Kinetics of silver nanoparticle formation in a viscous-flow polymer. Surface science 395:242-245.

[2] Ahmad N, Sharma S (2012) Biosynthesis of silver nanoparticles from biowaste pomegranate peels. International Journal of Nanoparticles 5:185-195.

[3] Amro NA, Kotra LP, Mesthrige KW, Bulychev A, Mobashery S, Liu G (2000) High-resolution atomic force microscopy studies of the Escherichia coli outer membrane: Structural basis for permeability. Langmuir 16:2789-2796.

[4] Ankanna S, Prasad TNVKV, Elumalai EK, Savithramma N (2010) Production of biogenic silver nanoparticles using boswellia ovalifoliolata stem bark. Digest Journal of Nanomaterials & Biostructures 5:369-372.

[5] Baker C, Pradhan A, Pakstis L, Pochan DJ, Shah SI (2005) Synthesis and antibacterial properties of silver nanoparticles. J Nanosci Nanotechnol 5:244-249.

[6] Baset S, Akbari H, Zeynali H, Morteza S (2011) Size measurement of metal and semiconductor nanoparticles via uv-vis absorption spectra. Digest J Nanomater Biostructures 6:709-716.

[7] Bhadauria S, Kumar P (2012) Broad spectrum antidermatophytic drug for the control of tinea infection in human beings. Mycoses 55:339-343.

[8] Binupriya AR, Muthuswamy S, Soon-In Y (2010) Myco-crystallization of silver ions to nano-sized particles by live and dead cell filtrates of Aspergillus oryzae var viridis and its bactericidal activity towards Staphylococcus aureus KCCM 12256. Ind Eng Chem Res 49:852-858.

[9] Catauro M, Raucci MG, De Gaaetano F, Marotta A (2004) Antibacterial and bioactive silver-containing Na₂O•CaO•2SiO₂ glass prepared by sol-gel method. J Mater Sci 15:831-837.

[10] Chien SW, Wang MC, Huang CC, Seshaiah K (2007) Characterization of humic substances derived from swine manure-based compost and correlation of their characteristics with reactivities with heavy metals. J Agric Food Chem 55:4820-4827.

[11] Daniel MC, Astruc D (2004) Gold Nanoparticles: Assembly, Supramolecular Chemistry, Quantum-Size-Related Properties and Applications toward Biology, Catalysis and Nanotechnology. Chem Rev 104:293-346.

[12] Danilczuk M, Lund A, Sadlo J, Yamada H, Michalik J (2006) Conduction electron spin resonance of small silver particles. Spectrochimica Acta A 63:189-191.

[13] Das R, Nath SS, Chakdar D, Gope G, Bhattacharjee R (2009) Preparation of silver nanoparticles and their characterization. J Nanotechnol 5:1-6.

[14] Evanoff Jr DD, Chumanov G (2005) Synthesis and optical properties of silver nanoparticles and arrays. Chem Phys Chem 6:1221-1231.

[15] Gan PP, Ng SH, Huang Y, Li SF (2012) Green synthesis of gold nanoparticles using palm oil mill effluent (POME): A low-cost and eco-friendly viable approach. Bioresour Technol 113:132-137.

[16] Gould JC (1952) The determination of bacterial sensitivity of antibiotics. Edinburgh Med J 59 :178-199.

[17] Henglein A (1998) Colloidal silver nanoparticles: Photochemical preparation and interaction with O₂, CCl₄, and some metal ions. Chem Mater 10:444-450.

[18] Inbakandan D, Venkatesan R, Khan SA (2010) Biosynthesis of gold nanoparticles utilizing marine sponge Acanthella elongata (Dendy, 1905). Colloids Surf B Biointerfaces 81:634-639.

[19] Jain D, Daima HK, Kachnwaha S, Kothari SL (2009) Synthesis of plant-mediated silver nanoparticles using papaya fruit extract and evaluation of their anti microbial activities. Digest Journal of Nanomaterials and Biostructures 4:557-563.

[20] Jasuja ND, Saxena R, Chandra S, Sharma R (2012) Pharmacological characterization and beneficial uses of Punica granatum Asian J Plant Sci 11:251-267.

[21] Kawsar SMA, Mostafa G, Huq E, Nahar N, Ozeki Y (2009) Chemical Constituents and Hemolytic Activity of Macrotyloma uniflorum L. International Journal of Biological Chemistry 3:42-48.

[22] Kim JS, Kuk E, Yu KN, Kim JH, Park SJ, Lee HJ, Kim SH, Park YK, Park YH, Hwang CY, Kim YK, Lee YS, Jeong DH, Cho MH (2007) Antimicrobial effects of silver nanoparticles. Nanomedicine 3:95-101.

[23] Kreibig U, Vollmer M (1995) Optical Properties of Metal Clusters Springer Berlin, 535.

[24] Krishnamurthy NB, Nagaraj B, Barasa M, Liny P, Dinesh R (2012) Green synthesis of gold nanoparticles using Tagetes erectal (mari gold) flower extract and evaluation of their antimicrobial activities. Int J Pharm Bio Sci 3:212-221.

[25] Latha PS, Kannabiran K (2006) Antimicrobial activity and phytochemicals of Solanum trilobatum Linn. Afr J Biotechnol 5:2402-2404.

[26] Link S, El-Sayed MA (2003) Optical Properties and ultrafast dynamics of metallic nanocrystals. Annu Rev Phys Chem 54:331-366.

[27] Marini M, De Niederhausern N, Iseppi R, Bondi M, Sabia C, Toselli M, Pilati F (2007) Antibacterial activity of plastics coated with silver-doped organic-inorganic hybrid coatings prepared by sol-gel processes. Biomacromolecules 8:1246-1254.

[28] Martinez-Castanon GA, Nino-Martinez N, Martinez-Gutierrez F, Martinez-Mendoza JR, Ruiz F (2008) Synthesis and antibacterial activity of silver nanoparticles with different sizes. Journal of Nanoparticle Research 10:1343-1348.

[29] Mendis E, Rajapakse N, Byun HG, Kim SK (2005) Investigation of jumbo squid (Dosidicus gigas) skin gelatin peptides for their in vitro antioxidant effects. Life Sci 77:2166-2178.

[30] Nath SS, Chakdar D, Gope G (2007) Synthesis of CdS and ZnS quantum dots and their applications in electronics. Nanotrends 2:1-5.

[31] Noginov MA, Zhu G, Bahoura M, Adegoke J, Small C (2007) The effect of gain and absorption on surface plasmos in metal nanoparticles. Applied Physics B-Lasers and Optics 86:455-460.

[32] Qi L, Xu Z, Jiang X, Hu C, Zou X (2004) Preparation and antibacterial activity of chitosan nanoparticles. Carbohydr Res 339:2693-2700.

[33] Quelemes PV, Araruna FB, de Faria BE, Kuckelhaus SA, da Silva DA, Mendonça RZ, Eiras C, Dos S Soares MJ, Leite JR (2013) Development and antibacterial activity of cashew gum-based silver nanoparticles. Int J Mol Sci14:4969-4981.

[34] Raffi M, Hussain F, Bhatti TM, Akhter JI, Hameed A, Hasan MM (2008) Antibacterial characterization of silver nanoparticles against E coli ATCC-15224. J Mater Sci Technol 24:192-196.

[35] Rios JL, Recio MC, Villar A (1988) Screening methods for natural products with antimicrobial activity: a review of the literature. J Ethnopharmacol 23:127-149.

[36] Ruparelia JP, Chatterjee AK, Duttagupta SP, Mukherji S (2008) Strain specificity in antimicrobial activity of silver and copper nanoparticles. Acta Biomaterialia 4:707-716.

[37] Saxena A, Tripathi RM, Singh RP (2010) Biological synthesis of silver nanoparticles by using onion (Allium cepa) extract and their antibacterial activity. Digest J Nanomater Biostructures 5:427-432.

[38] Schultz S, Smith DR, Mock JJ, Schultz DA, (2000) Single-target molecule detection with no bleaching multicolor optical immunolabels. Proc Natl Acad Sci 97:996-1001.

[39] Shahverdi AR, Minaeian S, Shahverdi HR, Jamalifar H, Nohi AA (2007) Rapid synthesis of silver nanoparticles using culture supernatants of Enterobacteria: A novel biological approach. Process Biochemistry 42:919-923.

[40] Singh A, Jain D, Upadhyay MK, Khandelwal N, Verma HN (2010) Green synthesis of silver nanoparticles using argimone mexicana leaf extract and evaluation of their antimicrobial activities. Digest Journal of Nanomaterials & Biostructures (DJNB) 5:483-489.

[41] Sondi I, Salopek-Sondi B (2004) Silver nanoparticles as antimicrobial agent: a case study on E coli as a model for Gram-negative bacteria. J Colloid Interface Sci 275:177-182.

[42] Soundarrajan C, Sankari A, Dhandapani P, Maruthamuthu S, Ravichandran S, Sozhan G, Palaniswamy N (2012) Rapid biological synthesis of platinum nanoparticles using Ocimum sanctum for water electrolysis applications. Bioprocess Biosyst Eng 35:827-833.

[43] Stevanovic M, Savanovic I, Uskokovic V, Skapin SD, Bracko I, Jovanovic U, Uskokovic D (2012) A new, simple, green and one-pot four-component synthesis of bare and poly(α,γ,l-glutamic acid)-capped silver nanoparticles. Colloid Polym Sci 290:221-231.

[44] Taleb A, Petit C, Pileni MP (1998) Optical Properties of self assembled 2D and 3D superlattices of silver nanoparticles. J Phys Chem B 102:2214-2220.

[45] Thiel J, Pakstis L, Buzby S, Raffi M, Ni C, Pochan DJ, Shah SI (2007) Antibacterial properties of silver-doped titania. Small 3:799-803.

[46] Umashankari J, Inbakandan D, Ajithkumar TT, Balasubramanian T (2012) Mangrove plant, Rhizophora mucronata (Lamk, 1804) mediated one pot green synthesis of silver nanoparticles and its antibacterial activity against aquatic pathogens. Aquat Biosyst 8:11.

[47] Van Elswijk DA, Schobel UP, Lansky EP, Irth H, van de Greef J (2004) Rapid dereplication of estrogenic compounds in pomegranate (Punica granatum) using on-line biochemical detection coupled to mass spectrometry. Phytochemistry 65:233-241.

[48] Vasireddy R, Paul R, Mitra AK (2012) Green synthesis of silver nanoparticles and the study of optical properties. Nanomater Nanotechnol 2:1-6.

[49] Vijayakumar M, Priya K, Nancy FT, Noorlidaha A, Ahmed ABA (2013) Biosynthesis, characterisation and anti-bacterial effect of plant-mediated silver nanoparticles using Artemisia nilagirica. Ind Crops Prod 41:235-240.

[50] Vivek M, Kumar PS, Steffi S, Sudha S (2011) Biogenic silver nanoparticles by Gelidiella acerosa extract and their antifungal effects. Avicenna J Med Biotechnol 3:143-148.

[51] Wang W, Chen Q, Jiang C, Yang D, Liu X, Xu S (2007) One step synthesis of biocompatible gold nanoparticles using gallic acid in the presence of poly-(N-vinyl-2-pyrrolidone). Colloids Surf A 301:73-79.

[52] White GV, Kerscher P, Brown RM, Morella JD, McAllister W, Dean D, Kitchens CL (2012) Green synthesis of robust, biocompatible silver nanoparticles using garlic extract. J Nanomater 730746:1-12.

[53] Wiley BJ, Im SH, Li ZY, McLellan J, Siekkkinen A, Xia Y (2006) Maneuvering the Surface Plasmon Resonance of Silver Nanoparticles through Shape- Controlled Synthesis. J Phys Chem B 110:15666-15675.

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Green Synthesis of AgNPs Stabilized with biowaste and their antimicrobial activities

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