Synthesis of Silver Nanoparticles from the Aqueous Extract of Leaves ofOcimum sanctum for Enhanced Antibacterial Activity

e �eld of nanotechnology is the most active area of research in modern materials science. ough there are many chemical as well as physical methods, green synthesis of nanomaterials is the most emerging method of synthesis. We report the synthesis of antibacterial silver nanoparticles (AgNPs) using leaf broth of medicinal herb, Ocimum sanctum (Tulsi). e synthesized AgNPs have been characterized by UV-Vis spectroscopy, transmission electron microscopy (TEM), and X-ray diffractometry. e mean particle of synthesized NPs was found to be 18 nm, as con�rmed by TEM. e qualitative assessment of reducing potential of leaf extract has also been carried out which indicated presence of signi�cant amount of reducing entities. FTIR analysis revealed that the AgNPs were stabilized by eugenols, terpenes, and other aromatic compounds present in the extract. Such AgNPs stabilized by Tulsi leaf extract were found to have enhanced antimicrobial activity against well-known pathogenic strains, namely Staphylococcus aureus and E. coli.


Introduction
In recent years, researchers in the �eld of nanotechnology are �nding that metal nanoparticles have all kinds of previously unexpected bene�ts. ey are mostly prepared from noble metals, that is, silver, gold, platinum and palladium, silver nanoparticles (AgNPs) being most exploited [1]. ey �nd applications in various �elds like medicine, electronics, energy saving, environment, textile, cosmetics, and so forth. Owing to their applicability in such wide sectors, their demand is increasing at an overwhelming rate. e increased demand has consequently resulted in increased production. Researchers are continuously developing newer methods for synthesis of highly monodisperse AgNPs which are efficient in terms of synthesis rate as well as energy usage.
Conventionally, nanomaterials are synthesized using either chemical or physical methods which include sol process, micelle, chemical precipitation, hydrothermal method, pyrolysis, and chemical vapour deposition [2]. Some of these methods are easy and provide control over crystallite size by restoring the reaction environment. But problem still exists with the general stability of the product and in achieving monodisperse nanosize using these methods [3]. Moreover, many of the conventional techniques have been found to be capital intensive and inefficient in materials and energy use [4].
Biological methods have emerged as an alternative to the conventional methods for synthesis of NPs. Synthesis of inorganic nanoparticles by biological systems makes nanoparticles more biocompatible and environmentally benign [5]. Moreover, the process is cost effective too [1]. Many bacterial as well as fungal species have been used for silver nanoparticles synthesis [6]. But most of them have been reported to accumulate AgNPs intracellularly. Intracellular synthesis always takes longer reaction times and also demands subsequent extraction and recovery steps. On the contrary, plant extract mediated synthesis always takes place extracellularly, and the reaction times have also been reported to be very short compared to that of microbial synthesis. Most importantly, the process can be suitably scaled up for large scale synthesis of NPs [7].
Ocimum sanctum (Tulsi) is a medicinal herb abundantly found and cultured in India, Malaysia, Australia, West Africa, and some of the Arab countries [21]. Tulsi leaves have been traditionally used for treatment of many infections. e antibacterial activity has been reported to be the upshot of essential oil components, mostly eugenols found in it. e present study aims at the synthesis of silver nanoparticles from the aqueous extract of Tulsi leaves. We also attempt to combine the inherent antimicrobial activities of silver metal and Tulsi extract for enhanced antimicrobial activity.

Experimental
2.1. Chemicals. Silver nitrate was purchased from Sigma-Aldrich, Bangalore, India. e bacteriological media were purchased from HiMedia Laboratories, India. All media and solutions were prepared in double-distilled Milli Q water. e experiments were performed in triplicates, and mean values are presented in results.

Microorganisms and Media.
Common human pathogenic bacterial strains of Escherichia coli ATCC 25922 and Staphylococcus aureus ATCC 25923 were used for assessment of antibacterial activity of lab-synthesized AgNPs. e strains were obtained from National Collection of Industrial Microorganisms (NCIM), Pune (India). ey were clinical isolates and are used as international reference standards for disc susceptibility assessment of many antibiotics. Nutrient agar was used for growth and maintenance of bacterial strains. Nutrient broth was used for preparation of suspension cultures. Mueller Hinton Agar (MHA) was used to assess antibacterial activities.

Preparation of Plant
Extract. 20 gm of fresh leaves of Tulsi were washed thoroughly with double-distilled water and were then cut into small pieces. ese �nely cut pieces were then mixed with 100 mL doubled-distilled water, and this mixture was kept for boiling for a period of 5 minutes. Aer cooling, it was �ltered through Whatman Filter paper no. 1.

Synthesis of AgNPs and Evaluation of Reducing
Potential of the Extract. 10 mL of aqueous extract of Tulsi leaves was added to 90 mL of silver nitrate solution so as to make its �nal concentration to 10 −3 M. e solution was allowed to react at room temperature. Periodic sampling aer 30 minutes was carried out to monitor the formation of AgNPs. e qualitative evaluation of reducing potential of aqueous extract of Tulsi leaves was carried out as per the method reported by Saifuddin et al. [22].

UV-Vis
Spectroscopy. UV-Vis spectroscopic analysis was carried out on Shimadzu UV 1800. Cuvette of path length 10 mm was used. e measurements were carried out as a function of reaction time at room temperature.

Transmission Electron
Microscopy. e TEM images of synthesized AgNPs were obtained for size and shape determination using JEOL 200 TEM operated at an accelerating voltage of 300 kV. Prior to analysis, AgNPs were sonicated for 5 minutes, and a drop of appropriately diluted sample was placed onto carbon-coated copper grid. e liquid fraction was allowed to evaporate at room temperature.

X-Ray
Diffractometry. XRD measurements were recorded on Rigaku Mini�ex II X-ray di�ractometer. For XRD measurements, the AgNPs were dried in oven at 60 ∘ C, and such dried powder was further analyzed on XRD for  their phase structure and exact material identi�cation. e Cu radiation ( Å) was selected and the diffractogram was obtained in the 2 range of 10-60 degree.

Fourier Transform Infrared (FTIR)
Spectroscopy. e binding properties of AgNPs synthesized by Tulsi leaf extract were investigated by FTIR analysis. FTIR measurements were taken on Bruker vertex 70. Dried and powdered AgNPs were palleted with potassium bromide (KBr) (1 : 10 proportion). e spectra were recorded in the wavenumber range of 450-2500 cm − and analyzed by subtracting the spectrum of pure KBr.
2.6. Assessment of Antibacterial Activity. In order to examine the antibacterial activity of the AgNPs on selected bacteria, the Kirby-Bauer disc diffusion method [23] was used. For disc diffusion method, log phase bacterial inoculums ( 0 cfu/mL) were standardized against MacFarland's standard [24] and were swabbed onto petriplates containing 4 mm thick MHA. Filter paper discs saturated with AgNPs, Tulsi extract and silver nitrate solution were placed onto these plates with the help of sterile forceps and incubated at 37 ∘ C. A disc soaked in sterile distilled water acted as controls for the experiment. Negative growth zone results were read only aer 24 hours, as longer or shorter incubation periods may give misleading results.

Results and Discussion
Formation of AgNPs by reduction of silver nitrate during exposure to Tulsi leaf extract can be easily monitored from the change in colour of the reaction mixture. Silver nanoparticles bear a characteristic yellow brown colour due to the excitation of surface plasmon vibrations. e change in colour of the reaction mixture aer 2 hours is presented in Figure 1 which indicated the formation of AgNPs. is formation indicates that silver ions in reaction medium have been converted to elemental silver having the size of nanometric range. ere is always an essential need for reducing entities in the reaction medium to bring such conversions. To ensure the presence of reducing entities in the reaction medium, reducing assay was carried out, and the results are shown in Figure 2. It shows the change in colour of the reaction medium as an effect of presence of any type of reducing substance. As per this qualitative assessment of reducing potential of Tulsi extract, presence of signi�cant amount of reducing entities was attested therein. In case of bacteria and fungi mediated synthesis of AgNPs, reduction of silver nitrate to elemental silver has been attributed to the presence of reductive enzymes [22,25]. But there is controversy regarding the plant extract components involved in reduction of silver nitrate to elemental silver. Shankar et al., (2005) have speculated the role of reducing sugars for the reduction of silver nitrate to silver nanoparticles [10].
In another recent study, it has been suggested that different compounds such as caffeine and theophylline bring out the reduction processes and thus silver nanoparticles synthesis [26]. Natural antioxidants have been reported to have strong reducing ability [27]. As Tulsi possess a potent antioxidant activity [21], we attribute the reduction process to their presence of high quantity of antioxidants in the leaves extract Figure 3 shows UV-Vis absorption spectrum of silver nanoparticles. ough the plasmon band is broad due to the presence of components in Tulsi extract which are also being read in the spectrophotometric range, it is observed that the silver surface plasmon resonance (SPR) occurs at 450 nm and steadily increases in intensity as a function reaction time. ere is no change in peak position, suggesting that nucleation of silver nanoparticles starts with initiation of reaction time only, and the size remains unchanged throughout the course of reaction. According to Mie theory, only a single SPR band is expected in the absorption spectra of spherical nanoparticles whereas, the number of peaks increases as anisotropy increases [28]. In the present study, SPR band reveals spherical shape of silver nanoparticles, which was further con�rmed by TEM. Inset of Figure 3 represents the plot of absorbance at max versus reaction time. e reduction of silver ions was quite rapid. More than 90% of the reaction is complete within 60 minutes of the reaction time. Generally, biosynthetic methods are considered as time consuming when compared with chemical methods. To the best of our knowledge, reaction time of at least 12 hours is required in plant-mediated nanomaterials synthesis. However, the time consumed in the present study for the reaction to complete is severalfold lesser than reported. Such alacrity in reaction time can be the outcome of potent antioxidant activity of the Tulsi extract, which makes the reaction much more efficient than others. e efficiency of this method was tested for stability also. e solution of AgNPs was stored for two months, and no precipitation in the content of the solution was observed. is was also assured by regular observation of UV-Vis absorption properties of the solution. ere was no shi in the absorbance intensity as well as absorption maxima indicating the particle size to be same as recorded earlier. Figure 4 shows TEM images of AgNPs at different mag-ni�cations. Images reveal that the AgNPs are predominantly spherical in shape and are not in physical contact with each other. �ower magni�cation image reveals the nanoparticles are embedded in a dense matrix which may be the organic stabilizing components of Tulsi leaf extract. e presence of organic content associated with AgNPs can be further con�rmed by observing the sharp Braggs re�ection in �R� spectrum. Figure 5(a) shows the histogram of particles size versus number of particles observed on TEM grid. It is clear from the histogram that the mean particle size of AgNPs is 18 nm. e HRTEM image of synthesized AgNPs is shown in Figure 5(b). It reveals that the particles exhibit the dspacing of 2.39 Å which correspond to the (111) plane of silver.

6
Journal of Chemistry Figure 6 shows the XRD patterns obtained for silver nanoparticles synthesized by Tulsi extract. All major peaks can be indexed for the face centered cubic structure of silver. Minor but broad peaks at lower 2 theta values can be assigned to the organic content of the Tulsi extract. e XRD pattern thus clearly shows that silver nanoparticles formed by Tulsi extract are crystalline in nature. e average diameter of the silver particles was calculated from the (111) diffraction peak using Scherrer's formula: where is mean crystallite size, is the width of the peak at half maximum intensity of a speci�c phase in radians, and is the wavelength of incident rays, is the center angle of the peak in radian. e mean crystallite size for AgNPs synthesized using Tulsi extract was determined to be 16.87 nm by formula which is comparable with the results obtained by HRTEM analysis. Figure 7 shows the FTIR analysis results of the AgNPs. e prominent peaks were observed at 1012, 1080, 1614, 1654 cm −1 . ere appeared no peaks in the wavenumber range 3400-3250 cm −1 , that is, amide region (region omitted from the spectrum). is is contradictory to earlier literature reports stating that binding as well as stabilization takes place by free amide groups present in proteinaceous substance used for synthesis [28,29]. In the present study, the peaks are more characteristic of eugenols, linalools, and terpenes that are abundant in Tulsi plant extract. e peaks found at 1614 and 1654 cm −1 can be attributed to the C-C in alkene rings and C=C stretch of aromatic rings, respectively, whereas peaks at 1012 and 1080 cm −1 can be attributed to the ether linkages. Depending on above observation, it can be assumed that the stabilization is achieved by the phenolic as well as aromatic compounds present in the extract.
Antibacterial potential of silver is known for many years [28]. Tulsi extract has also been much exploited, both traditionally and commercially, for their antibacterial potential which is an upshot of essential oil components [30]. In our study, the AgNPs synthesized using Tulsi extract exerted a fairly signi�cant antibacterial action on the tested bacteria. is is evident by the values of diameter of zone of inhibition obtained during assessment of antibacterial activity (Table  1). Figure 8 shows the zones of inhibition of E. coli and Staphylococcus aureus against AgNPs, silver nitrate, Tulsi extract and distilled water as control. For both the bacterial strains, no zone of inhibition was observed for control as well as silver nitrate solution. A very small but noticeable zone of inhibition was observed for Tulsi extract. is symbolizes that the antimicrobial potential of Tulsi extract is higher than that of silver ions at their respective concentrations used in the study. Bioreduced silver nanoparticles showed considerable growth inhibition of two of the well-known pathogenic bacterial species. Zones of 11 mm and 10 mm were observed for E. coli and Staphylococcus aureus, respectively. Coupling of inherent property of Tulsi extract with that of silver nanoparticles has really proved to be bene�cial to minimize the dose that needs to be administered for total microbial reduction.

Conclusion
Highly monodisperse AgNPs silver nanoparticles are synthesized using leaf extract of a well-known medicinal herb, Tulsi. e synthesis is found to be efficient in terms of reaction time as well as stability of the synthesized AgNPs. is nanoparticulate solution exhibits excellent stability for six months from the date of synthesis. e process is truly scalable owing to lesser speci�city of reaction parameters. Investigation on the antibacterial activity of AgNPs against E. coli and Staphylococcus aureus reveals high potential of Tulsi extract stabilized AgNPs to be used as antimicrobial agent in medical �eld as well as food and cosmetic industries.