Synthesis of Silver Nanoparticles Using Aqueous Extract of Medicinal Plants' (Impatiens balsamina and Lantana camara) Fresh Leaves and Analysis of Antimicrobial Activity

Plant-mediated synthesis of nanomaterials has been increasingly gaining popularity due to its eco-friendly nature and cost-effectiveness. In the present study, we synthesized silver (Ag) nanoparticles using aqueous extracts of fresh leaves of Impatiens balsamina and Lantana camara medicinal plants as bioreducing agents. This method allowed the synthesis of nanoparticles, which was confirmed by ultraviolet-visible (UV-Vis) spectrophotometry and transmission electron microscopy (TEM). UV-Vis spectra and visual observation showed that the color of the fresh leaf extracts of L. camara and I. balsamina turned into grayish brown and brownish yellow, respectively, after treatment with Ag precursors. In addition, TEM analysis confirmed that AgNO3 solutions for all concentrations produced Ag nanoparticles and their average size was less than 24 nm. Moreover, aqueous leaf extracts of I. balsamina and L. camara were separately tested for their antimicrobial activity against Gram-positive Staphylococcus aureus and Gram-negative Escherichia coli bacteria. The results showed that the bacterial growth was inhibited by the extracts containing Ag nanoparticles. Statistical calculation performed using the Tukey test showed that zones of inhibition for the two bacteria produced by the aqueous leaf extracts of L. camara containing 3 mM and 5 mM Ag precursors were not significantly different from that by ciprofloxacin as positive control. On the contrary, there was significant difference between the zone of inhibition for E. coli by ciprofloxacin and that by the extracts of I. balsamina leaves containing 3 mM and 5 mM Ag precursors. A similar result was observed on the zone of inhibition for S. aureus by the extracts of I. balsamina leaves containing 3 mM Ag precursor. It was shown that the aqueous extracts of fresh L. camara leaves containing Ag nanoparticles were comparable to ciprofloxacin in inhibiting bacterial growth.


Introduction
Nanoparticles represent a particle with a nanometer size of 1-100 nm.
e nanoscale material has new, unique, and superior physical and chemical properties compared to its bulk structure, due to an increase in the ratio of the surface area per volume of the material/particle [1]. e most widely studied nanoparticle materials are metal nanoparticles because they are easier to synthesize. Moreover, these materials have a wide range of applications: detectors, catalysts, surface coating agents, and antibacterial/antimicrobials, among many others. Some of the most studied metallic nanoparticles include silver (Ag) [2,3], gold (Au) [4], platinum (Pt) [5][6][7], and palladium (Pd) [8].
Ag nanoparticle is an interesting metal to be studied, especially in the field of health and medicine. Ag is a strong antibacterial and also toxic to cells. Ag has the ability to damage bacterial cell walls, inhibits bacterial cell growth, and disrupts cell metabolism because of the interaction between Ag ions with macromolecules in cells, such as proteins and deoxyribonucleic acid (DNA). e ion Ag that interacts with the cell prevents protein synthesis, further decreases the membrane permeability, and eventually leads to cell death.
e Ag nanoparticles are chemically more reactive than Ag in their bulk. erefore, Ag nanoparticles are indicated to have stronger antibacterial capabilities [9][10][11]. Ag nanoparticles can be synthesized through several methods, including chemical reduction. Chemical reduction methods are often used because they are easier and economical [12]. is method is done by reducing Ag salts by reducing agents, such as sodium citrate or sodium borohydride [13]. However, the use of chemicals in the synthesis of Ag nanoparticles results in the adsorption of toxic chemicals (reducing agents and organic solvents) on the surface of the material so that it will have adverse and harmful effects on its application [14]. erefore, the use of environmentally friendly methods is desirable.
Green synthesis methods for synthesizing nanoparticles using natural products can be used to address the problem by utilizing plants or microorganisms [15]. e utilization of plants in the biosynthesis of nanoparticles involves the content of secondary metabolites as reducing agents [16]. Allegedly, biological agents act as reducers, stabilizers, or both in the process of forming nanoparticles [17]. e biosynthesis of Ag nanoparticles has been carried out by utilizing a number of plants and evaluating the antimicrobial activity, such as ethanol extracts from Cardiospermum halicacabum L. leaves [18], Impatiens balsamina L. leaves [19], and Lantana camara L. fruits [20]. e ethanol extract of I. balsamina and L. camara was obtained from the leaves which were first dried for further analysis of its antimicrobial activity.
I. balsamina and L. camara are one of the most common medicinal plants in Indonesia, especially for wound dressing [19,21]. According to Meenu et al. [22], the dry I. balsamina ethanol extract contains chemical compounds such as essential oils, phenols, flavonoids, carbohydrates, proteins, alkaloids, glycosides, iridoid glycosides, phenylethanoids, oligosaccharides, quinine, saponins, steroids, triterpenoids, sesquiterpenoids, and tannins and has antibacterial activity against Staphylococcus epidermidis. e aqueous extract of fresh leaves of I. balsamina and L. camara to synthesize Ag nanoparticles (extract Ag nanoparticles) is important to be investigated mainly because it can be used as a wound medicine that can be packaged in the form of infusions/ fluids. Liquids that use water solvents are much safer for health and the environment than using chemical solvents [23]. erefore, in this study, we used water as a solvent in medicinal plant extracts. e present study synthesized Ag nanoparticles using aqueous extracts of fresh leaves of I. balsamina and L. camara and then evaluated its antimicrobial activity, particularly against the growth of Staphylococcus aureus (S. aureus) and Escherichia coli (E. coli) bacteria.

Chemicals and Plant Material Collection.
All the reagents purchased were of analytical grade and used without any further purification. Silver nitrate (AgNO 3 ) was purchased from Sigma-Aldrich with a ≥99.5% purity. Fresh leaves of I. balsamina and L. camara were collected from the surroundings of the Bitung region, North Sulawesi, Indonesia ( Figure 1). Distilled water was used for preparing aqueous solutions all over the experiments.

Preparation of Leaf Extract.
Aqueous leave extracts were prepared by the following procedure: fresh leaves of I. balsamina were collected and washed with tap water at first, and then the surface was washed under running water with distilled water until no impurities remained. en, the fresh leaves were cut into small pieces, and 10 g was weighed and put into a beaker with 100 ml of distilled water. e mixture was heated for 20 minutes at 60°C while stirring occasionally and then allowed to cool at room temperature [24]. e mixture was filtered using the Whatman 42 filter paper and then centrifuged at 81 G-force for 20 minutes. e extract was stored in the refrigerator for further use to synthesize Ag nanoparticles from AgNO 3 precursor solution.
e same process was also done on fresh leaves of L. camara.

Synthesis of Ag Nanoparticles.
AgNO 3 powder was dissolved in distilled water to prepare 10 mM AgNO 3 stock solution from which a series of 1 mM, 2 mM, 3 mM, 4 mM, and 5 mM AgNO 3 solutions were prepared. e AgNO 3 solutions were mixed with the aqueous extract of I. balsamina fresh leaves at a ratio of 1 : 1 (v/v) to a volume of 50 mL in a flask. e flask was wrapped with an aluminum foil and was then heated in a waterbath at 60°C for 5 hours. Furthermore, the mixture was stored in the refrigerator for the antibacterial activity test and further analyzed by using UV-Vis spectrophotometer and TEM. e same procedure was also carried out on the aqueous extract of L. camara fresh leaves.

Assay for Antimicrobial
Activity of Ag Nanoparticles against Microorganisms. All equipment and growing media were sterilized by autoclaving at 115°C and 15 psi for 30 minutes. e antimicrobial activity has been investigated against S. aureus as a model for Gram-positive bacteria and E. coli as a model for Gram-negative bacteria. e antimicrobial activity was evaluated by the disc diffusion method. Preparation of the bacteria stock was done to reproduce and rejuvenate bacteria. is was done by inoculating each one inoculation loop pure culture of E. coli and S. aureus into 5 ml of nutrient agar solution and then incubated at 37°C for 24 hours in the incubator. Preparation of test bacteria was carried out by inserting one inoculation loop of cultured bacteria into 5 ml of 0.19% NaCl solution. Furthermore, it was vortexed and its turbidity was adjusted to 0.5 McFarland solution turbidity of ∼10 8 CFU/mL by adding the cultured bacteria [19]. e inhibition method was used in evaluating the antibacterial activity. 20 ml of nutrient agar solution was put into a Petri dish, sterilized for 15 minutes until the nutrient agar solution became solid, and then 0.1 ml of bacterial solution was applied to the nutrient agar growing medium. ereafter, negative control (distilled water), positive control (Ciprofloxacin), and sample (2 replications) were placed. Next, it was incubated at 37°C for 24 hours before the clear zone diameter was measured using the sliding term. To see the ability of each leaf extract containing Ag nanoparticles in inhibiting bacterial growth compared to ciprofloxacin positive control, a statistical analysis was performed using the Tukey test at the 95% confidence level.

Characterization of Ag Nanoparticles.
e reduction of pure Ag + ions was monitored by measuring the UV-Vis spectrum of the reaction medium after diluting a small aliquot of the sample into distilled water. e color change in the reaction mixture (metal ion solution + I. balsamina extract) was recorded through visual observation. UV-Vis spectral analysis was done by using UV-Vis spectrophotometer UV-1800 (Shimadzu) at the wavelength of 200-800 nm. JEOL JEM-1400 Transmission Electron Microscope (TEM), operating at 120 V and an acceleration voltage of 15 kV, was used to analyze the morphology and size of Ag nanoparticles. For TEM measurements, extract samples containing Ag nanoparticles were dispersed on a copper grid and dried at room temperature. e particle sizes of the Ag nanoparticles were measured using Image J software. e histogram of the size distribution was established by Origin software.

UV-Vis Spectra Analysis.
e aqueous extract of fresh leaves of I. balsamina and L. camara change their colors when warmed. e I. balsamina extract changes color from colorless to brownish yellow, while L. camara becomes yellowish brown (Figure 2).
is warm extract solution changed color again after adding AgNO 3 solution. Color changes are possible because some of the Ag ions begin to be reduced due to the effects of heat and produces Ag + complex.
is complex was responsible for changing color from brownish yellow to grayish brown (L. camara), while the I. balsamina extract remained a brownish yellow (Figure 2 (A 2 and B 2 )). is color change indicates the formation of Ag nanoparticles [25]. e Ag nanoparticles synthesized in each extract solution was analyzed using UV-Vis spectroscopy. is was done to determine the characteristics of the peak spectrum of the Ag nanoparticle wavelength prepared for each different AgNO 3 concentrations (1 mM-5 mM) (Figure 3). e characteristics of Ag nanoparticles normally appear at a wavelength interval of 400-600 nm [26]. UV-Vis spectra of Ag nanoparticles synthesized using the I. balsamina aqueous extract evince the blue shift of the absorption band with increasing AgNO 3 concentration. For 1 mM, 2 mM, 3 mM, 4 mM, and 5 mM samples, the absorption peak is centered around 450-420 nm.
is information shows that the Ag nanoparticles have formed in the extract, where the Ag + has been reduced to Ag 0 . Proteins and all secondary metabolites of extract play a critical role in both the reducing and capping mechanism for nanoparticle formation [25]. e Ag nanoparticles contained in the aqueous extract of the L. camara also exhibit similar characteristics, where the shift of the absorption band with increasing AgNO 3 concentrations. However, the shift of the absorption peak was a little narrower than that of the Ag nanoparticles synthesized with the I. balsamina aqueous extract, where the absorption peak is centered on 450-440 nm. e peak wavelength of Ag nanoparticles in aqueous fresh leaf extracts can be seen in Table 1.

TEM Analysis.
e size and morphology of Ag nanoparticles synthesized using aqueous extracts of fresh leaves have been evaluated by TEM analysis. e obtained TEM images of the Ag nanoparticles prepared by each leaf extract from I. balsamina and L. camara are shown in Figure 4. International Journal of Microbiology e nanoparticles are quite polydispersed and a layer of the organic material surrounding the synthesized Ag nanoparticles could explain the good dispersion of these nanoparticles in solution. Generally, the Ag nanoparticles synthesized using aqueous extracts are well dispersed although some of them were noted to be agglomerated. Notably, the majority of the particles in the TEM images are not in physical contact with each other but appeared separated by the organic layer. erefore, TEM images clearly indicate the coating of Ag nanoparticles with an organic layer. e presence of several polyphenolic components including flavonoids and terpenoids facilitated the reduction of Ag ions and also stabilized the surface of the resultant Ag nanoparticles [25].
e Ag ions quantity influenced the size of the particles. When AgNO 3 concentration is increased to 5 mM, an obvious change in the size distribution of nanospheres was observed ( Table 2).

Antibacterial Activity Studies.
e present study revealed that the tested leaf extracts of I. balsamina and    Figure 5). Antibacterial activity was shown by an inhibition zone which was characterized by a clear zone between the wells (containing samples) and a certain distance. Formation of inhibition zones around the wells shows bacterial sensitivity to antibacterial and antibiotic ingredients (which are used as positive controls). e positive control used in the well was a ciprofloxacin 500 mg solution and functioned as a control of the test solution by comparing the diameter of the inhibition zone formed. On the contrary, distilled water as negative control was used to determine the effect of solvents in the test solution on the growth of S. aureus and E. coli bacteria. It was clear that it was the extracts containing Ag nanoparticles that had the antibacterial activity, not the solvent. e diameter of inhibition zones formed for each concentration of the AgNO 3 precursor added to the aqueous extracts of fresh leaves of I. balsamina and L. camara medicinal plants in synthesizing Ag nanoparticles is presented in Table 3. Table 3 shows that the antibacterial activity against S. aureus was increased, which was indicated by an increase in the inhibition zone diameter from 11.03 mm to 13.8 mm, with the increasing Ag concentration in I. balsamina extract. However, the opposite result was shown by E. coli, which was from 10.2 mm to 8.9 mm. e same was true for Ag nanoparticles in L. camara aqueous extracts which were  is information was supported by data that the average size of Ag nanoparticles synthesized using L. camara extract was relatively smaller than that using the extract of I. balsamina. e results of this study were also supported by previous studies that the small size of Ag nanoparticles makes these particles easier to penetrate the outer wall of bacteria, enter the body, destroy the respiratory chain, and thus inhibit cell respiration, causing bacterial death [27,28]. Regarding the inhibition zone, the antibacterial activity of Ag nanoparticles synthesized in this study was categorized into strong inhibitory activity (inhibition zone of 10-19 mm) according to Davis and Stout [29].

Conclusions
Medicinal plants, namely, aqueous extracts of fresh leaves of I. balsamina and L. camara, can be used as bioreduction agents to produce Ag nanoparticles. e formation of Ag nanoparticles in the extract was observed by the color change of I. balsamina extract into brownish yellow while of L. camara extract into grayish brown. Color changes that occur indicate that Ag particles have formed. e Ag particles produced had an increased size due to the increased concentration of AgNO 3 solution, but the average size is still in nanometer. Ag nanoparticles contained in the extract were able to inhibit the growth of S. aureus and E. coli bacteria, and the best antibacterial activity was exhibited by the L. camara extract containing Ag nanoparticles.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e authors declare that there are no conflicts of interest.