Abstract

Present work reports exceptionally high reducing capacity of Trapa bispinosa to synthesize monodispersed silver nanoparticles (SNPs) within 120 seconds at 30°C which is the shortest tenure reported for SNP synthesis using plants. Moreover, we also instigated impact of different pH values on fabrication of SNPs using visible spectroscopy with respect to time. Percentage conversion of Ag+ ions into Ag° was calculated using ICP-AES analysis and was found to be 97% at pH = 7. To investigate the reduction of Ag+ ions to SNPs, cyclic voltammetry (CV) and open circuit potential (OCP) using 0.1 M KNO3 were performed. There was prompt reduction in cathodic and anodic currents after addition of the peel extract which indicates the reducing power of T. bispinosa peel. Stability of the SNPs was studied using flocculation parameter (FP) which was found to be least at all the pH values. FP was found to be indirectly proportional to stability of the nanoparticles.

1. Introduction

Marriage of biology with nanotechnology was one of the most fruitful outcomes in material research, particularly in synthesis of metallic nanoparticles such as gold and silver. Living systems have learned over the tenure of millions of years of evolution to combat metal toxicity. In order to deplete the toxic effects of the metal ions, organisms release enzymes and other reducing agents to lower the oxidation states [1]. Recently, the molecular capacity of plants [2], bacteria [2, 3], and algae [4] to convert metal ions into well-dispersed nanoparticles has been explored. Tuning the parameters for the synthesis of nanoparticles of desired optical properties offers an intelligent and economical solution to avoid the toxicity as well as cost factor for biological applications like targeted drug delivery unlike chemical methods such as molecular beam epitaxy [5] and chemical vapour deposition [6] which involves toxic materials as precursors and expensive sophisticated techniques.

The most challenging endeavours in exploiting these living systems for commercial production of nanoparticles are as follows.(1)Living organisms require very stringent parameters to produce nanoparticles of desired size and shape. (2)Due to complex physiological circuits found in living systems, it becomes a daunting task to predict the modus operandi for nanoparticle synthesis so that a chemical reaction can be established. (3)Time required for the synthesis can vary from few minutes to few days.(4)Purification of the nanoparticles sometimes becomes difficult, particularly in case of intracellular production of nanoparticles [7, 8].

On the other hand advantages offered by living systems are manifold. (1)Exceptional biocompatibility of the nanoparticles offers widespread avenues for biological application of metal nanoparticles.(2)Water soluble metal nanoparticles can be obtained which can be used for biological proposes without stringent surface modifications.(3)Materials and energy consumption by living systems for the production of nanoparticles are extremely less making it a green alternative.(4)The process is thermodynamically efficient due to involvement of enzymes and short peptides [9].(5)Easy availability and low cost are involved in processing of the precursors.

Amongst most of the organisms which are used for the production of nanoparticles, plants are the most celebrated systems due to their inherent capacity to accumulate metals [10]. This capacity can acclimatize plants to withstand higher concentrations of metal ions and hence more production of nanoparticles unlike bacteria and algae which are very sensitive to metal ion concentrations. To name some plants which have been exploited for the production of silver as well as gold nanoparticles there are Alfalfa [11], Neem (Azadirachta indica) [12], Geranium [13], Rose [14], Nelumbo nucifera [15], and Cinnamomum camphora [16]. With a novel aim to use plants as ideal catalysts for commercial production of SNPs having desired properties, we have explored the peel of T. bispinosa (commonly known as Singhara in India) for ultrafast reduction of silver ions (Ag+). Few reports on plant-mediated green synthesis claim rapid synthesis time [1719]. However, the time required for SNPs synthesis in current report using T. bispinosa peel extract was found to be within 120 sec at room temperature (28 ± 2°C) which is one of the very rare reports for SNP synthesis. This is one of the major factors which might be useful commercially for scaling-up SNP production since the formation was very rapid with no surplus addition of heat energy. Impact of different pH values of the peel extract on the optical as well as morphological properties of SNPs is investigated in detail. Moreover, stability of the respective nanoparticles is studied using a physical quantity called “flocculation parameter” originally given by Weisbecker et al. [20].

2. Materials and Methods

2.1. Preparation of the Peel Extracts and Biosynthesis of Silver Nanoparticles

T. bispinosa was procured from the local market and soaked in cold water for 30 min. 10 g of the peel was crushed in 50 mL of distilled water and centrifuged to obtain clear light pink coloured extract. The extract was ultrafiltered using 0.22 μ nylon filter (Sartorius, Germany) in millipore apparatus under vacuum. And thus obtained ultraclear extract was used to perform all the experiments. It can be stored for more than a month at 4°C. Peel extract was diluted (1 : 100) using distilled water (18 MΩ). 10 mL of the diluted extract was adjusted to pH 2.8, 4.5, 5.5, 7, and 10 using 1 N NaOH and 1 N acetic acid to avoid chloride induced flocculation of the SNPs. Under stirring condition at 28 ± 2°C, 10 μL from a stock of 50,000 ppm silver nitrate (AgNO3) was added in 990 μL of diluted T. bispinosa plant extract. The procedure was repeated for all the pH values. Optimised pH value (pH 10) was used to study the time dependent synthesis of SNPs using UV-Vis spectroscopy.

2.2. Characterization

As formed SNPs were studied using UV-Vis spectrophotometer (Lambda-25 Perkin Elmer, USA), SNPs synthesized at different pH values were analysed using Field Emission Gun-Scanning Electron Microscope (Carl Zeiss, Germany) operating at 10 KV. Particle size distribution (PSD) was performed using Nano Sight LM20 (Amesbury, UK). Concentration of Ag+ ions before and after addition of plant extract was analysed using Inductively Coupled Plasma Atomic Emission Spectroscopy (ICP-AES) using ARCOS, Germany. Equation (1) is used to calculate percentage yield ( ) using initial concentration (IC) and final concentration (FC) of Ag+ ions:

Surface charge of SNPs with respect to pH was determined using Zetasizer (Malvern, UK). Cyclic voltammetry (CV) studies to comprehend the reduction of SNPs in the solution triggered by the T. bispinosa peel extract were performed by using Reference 3000 Potentiostat (Gamry, USA) by scanning in the potential range from 0.1 to 0.7 V at a scan rate of 1000 mV S−1. Electrochemical studies were performed using platinum wire as working electrode and counterelectrode against Ag/AgCl as reference electrode. All the measurements were performed at pH 7 ± 2 at 28 ± 2°C. Under stirring condition, in 25 mL of 0.1 M KNO3 solution, 25 μL of 50,000 ppm AgNO3 solution was added. After few initial scans to standardize peaks for silver ions, 0.5 mL of the T. bispinosa peel extract was added. Extremely fast depletion of the peaks for silver ions was observed immediately after addition of the extract. Thermogravimetric analysis (TGA) was done using Seiko Instruments, Japan, at heating rate of 10°C min−1.

2.3. Stability and Flocculation Parameter

SNPs synthesized at the above-mentioned pH values were centrifuged to remove excess reducing agents before performing stability test. Three mL of the SNPs synthesised at respective pH was taken in a quartz cuvette, and initial spectrum was recorded between 400 and 800 nm. 100 μL of 5 M NaCl salt was added to the same cuvette, and spectrum was recorded to see effect of salt in the form of red or blue shift of the maximum absorbance peak in the spectrum. This procedure was repeated till the peak became flat or stable.

Flocculation parameters were calculated by measuring the integrated absorbance between 450 and 750 nm in case of SNPs [21]. Equation (2) was used to calculate the integrated absorbance:

3. Results and Discussion

3.1. Synthesis of SNPs

One of the key requirements for efficient production of the metal nanoparticles is their rapidity of formation as well as monodispersity after addition of the reducing agents. In our work, reduction of the silver ions into SNPs was catalysed within 120 sec at 28 ± 2°C after addition of the peel extract. This is a very short time for synthesis of SNPs using plant extract unlike earlier observations using biological systems which report formation of the SNPs after 24 h at 30°C [2224].

Figure 1(a) explains the time dependent ripening of SNPs formation at pH 7 (inherent pH of the peel extract). A slight hump at 427 nm can be seen in the initial spectrum (0 min) which was recorded immediately after addition of the silver salt. There was considerable enhancement of peak intensity after 5 min followed by a slight red shift (11 nm) and decrease in full width half maxima (FWHM) as 30.03 nm as shown in the of Figure 1(b). FWHM determines the size and shape dispersity of nanoparticles; for calculations see Supplementary Information Scheme available online at http://dx.doi.org/10.1155/2013/516357. Inset of Figure 1(a) shows increase in the absorbance of the SNPs with increase in time which in turn shows the rapid formation of SNPs in the solution. There were more red shifts and increase in FWHM after 10 min of the reaction between silver salt and peel extract. Red shift indicates the ripening of the nanoparticles [25] whereas increase in FWHM explains the increase in the polydispersity of SNPs as per Mie theory [26]. There was consistent growth in the peak intensity accompanied with the red shift from 427 nm to 446 nm indicating the increase in the concentration of nanoparticles.

Any agglomeration of the nanoparticles in the solution can be ruled out due to sharpness of the peaks. This was also speculated due to the absence of turbidity in the SNP solution. A detailed study of agglomeration is presented in later part of the discussion. Abruptness in FWHMs with respect to time may be caused due to size and shape distributions of the nanoparticles during the rapid reduction process of silver ions to SNPs.

Exceptionally high reducing property of T. bispinosa extract may be attributed due to its inherent antioxidant property [27]. Presence of high quantity of flavonoids [28], polyphenols [29], and starch [30] can be the cause for such high reducing capacity at ambient temperature.

3.2. Characterization of SNPs

Time dependent appearance of colour at respective pH values (2.8, 4.5, 5.5, 7, and 10) is shown in Figure 2(a). Appearance of the peaks at different pH values between 400 and 500 nm wavelength is due to size related phenomenon called surface plasmon resonance [31] as displayed in Figure 2(b) along with the colours of SNPs after complete reduction of Ag+ (inset of Figure 2(b)).

At pH 2.8, slightly pink colour appeared after addition of the peel extract which became slightly blue after 120 sec (Figure 2(a)). Feeble spectral property (Figure 2(b)) shows formation of roughly spherical nanoparticles of size range ca. 9–70 nm (Figure 3( )) due to unfavourable redox states of reducing agents present in the peel extract as well as Ag+ ions. It may also be due to unstable proteins or short peptides at lower pH which play cardinal role in formation as well stability of the nanoparticles.

At pH 4.5 rapid formations can be seen, in stark contrast to acidic pH 2.8. As presented in Figure 2(a), colour of the solution appeared within 15 seconds after addition of the extract which became darker with increase in time, and finally greenish colour was exhibited after 120 sec (inset of Figure 2(b)). Synthesis of SNPs was confirmed by increase in the intensity of the peak at 426 nm (Figure 2(b)).

SEM results show SNPs of roughly spherical morphology (Figure 3( )). These results are consistent with PSD results (Figure 3( ), right panel) which display particle size 20–100 nm. Moreover, some larger nanoparticles (>120 nm) can also be seen. This variation of results (in comparison to SEM) may be due to different fields selected for the examination. Very little amount of nonspherical nanoparticles can be seen making the process efficient for the production of spherical nanoparticles.

At pH 5.5, comparatively faster reduction of Ag+ ions and hence appearance of colour can be seen in Figure 2(a). There was slight red shift of 3 nm at pH 5.5 as compared to 4.5. A comparatively sharper peak at 419 nm indicates the monodispersity of the nanoparticles (Figure 2(b)). Also, increase in the intensity shows enhanced ripening of SNPs. SEM image displays highly monodispersed spherical nanoparticles on an average ranging from 10 to 80 nm (Figure 3(C)). No evidence of flocculation can be seen in the image. With increase in the pH value better size control can be seen as evident from the SEM images. This may be due to the presence of capping proteins in their thermodynamically efficient state when the pH approaches alkalinity. Role of these capping proteins is to navigate the growth of the crystal in the solution based on their surface energies. These short peptides or other surfactants present in plant extract mimic nano-templates to assist nucleation to initiate ripening as well as shape of the nanoparticles depending on the surface energies. Additionally, capping proteins provide surface charge to nanoparticles in order to resist their agglomeration in the solution [32, 33].

At pH 7, a peak became less intense and broader at 413 nm. In this case, a blue shift of 6 nm was observed (from 419 to 413 nm). Blue shift is an indicative of decrease in the diameter of the nanoparticles as well as its stabilization in the solution. The observation can also be verified from the SEM image (Figure 3(D)). Nanoparticles were in the range of 6–100 nm. Diameter of the particles got decreased to less than 20 nm along with some larger nanoparticles. This may be due to the repulsion between the nanoparticles by virtue of negative charge of the surfaces. Also, at inherent pH of the peel extract capping proteins must be in their most efficient state in terms of thermodynamics; hence a better size tuning can be seen.

Extremely alkaline pH (pH 10) had profound influence on the formation of SNPs. Exceptionally fast reduction of the nanoparticles can be seen in Figure 2(a). After complete reduction, sharp peak at 408 nm and wine red colour of the SNPs (Figure 2(b) and its inset, resp.) can be seen. Blue shift of 5 nm indicates the further decrease in the particle diameter below 10 nm. As per the PSD analysis (Figure 3(E), right panel), particles were found to range from ca. 5 to 80 nm. Evidence of more stabilization can be seen in electron micrograph (Figure 3(E)). The energy dispersive X-ray (EDAX) spectroscopy presented in Figure S2 shows presence of pure silver. The percentage weight by weight of Ag as obtained from EDAX spectra was found to be ca. 8.24%.

Reduction of silver ions to form SNPs in solution was also verified by CV by assessing the change in the oxidation states of silver ions (Figure 4(a)). CV is a simple technique to record the redox potential of the species which are under experimental consideration. To comprehend the reduction potential of T. bispinosa peel extract, voltage range was selected to be 0.1–1 V [34].

Peaks observed at 0.46 and 0.28 V are assigned to reduction and oxidation potentials of AgNO3, respectively. In 25 mL 0.1 M KNO3 containing 25 μL of 50,000 ppm AgNO3 a prominent peak at 0.46 was observed at a scan rate of 1000 mV S−1. Immediately after the addition of 0.5 mL T. bispinosa peel extract, there was drastic shift in the potential towards negativity followed by reduction in the current density. This was clear indication of formation of SNPs in the solution which was also accompanied by change in colour from pale yellow to yellowish brown. Another pivotal observation was prompt decrease in the cathodic current density within few seconds after the addition of the extract implying the rapid reduction efficiency of peel extract.

Open circuit potential (OCP) under the above experimental conditions was performed to check time required for the reduction of the silver ions against potential. As shown in Figure 4(b), potential of pure KNO3 (A-B) increased due to addition of the AgNO3 till C. There was abrupt drop in the potential immediately after the addition of the peel extract which became constant after few seconds. This indicates the ultrafast reduction of AgNO3 to form SNPs mediated by peel extract.

Powder X-ray diffraction shows the crystalline nature of biosynthesised SNPs (Figure S3). Arrangement of atomic arrangement within the crystal and size of SNP were calculated. Comparison with the standard (joint committee in powder diffraction standards file no. 04-0783) confirmed that the particles were SNPs as depicted by the peaks at values of 38.40°, 44.32°, and 65.11° corresponding to (111), (200), and (220) planes for SNPs, respectively. This XRD pattern confirms the crystallinity of SNPs. The mean particle size of SNPs was calculated from the XRD data which can be derived from Debye Scherrer Equation

This equation exploits the reference peak width at angle , where is the X-ray wavelength (1.5418), is the FWHM of the XRD peak, and is the shape factor. The calculated average particle size of SNP was ca. 10–15 nm.

ICP-AES analysis of Ag+ content after reduction of AgNO3 by plant extract was found to be 1500 ppm at pH 7. Using (1), the percentage conversion or percent yield (% Y) was calculated as 97%. Comparative FTIR spectra of peel extract and SNPs synthesized from it show presence of proteins/organic capping of the nanoparticles (Figure S4).

TGA explains the surface protection of SNPs by some unique molecules, most probably short peptides (Figure S5). To remove organic peptide and protein capping of SNPs, peptidases and proteinases, respectively, could be used to degrade them into individual amino acids, and hence the nanoparticles can be used for further functionalization.

3.3. Stability of the SNPs and Flocculation Parameters at Different pH Values

Stability of the SNPs was studied adding multiples of 100 μL of 5 M NaCl with respect to time and recording the spectra after each addition of salt solution. The idea behind this was to study the change in the spectral properties due to flocculation induced by increasing salt concentration. Under the influence of salt, nanoparticles start forming cluster and hence shift in the peak towards longer wavelengths (450–750 nm in case of SNPs) results [35]. This can be seen in the form of red shift. Physical relation between the origin of the red shift and aggregation of the metal nanoparticles was given originally by Quinten and Kreibig, 1986 [36]. According to their studies,when the distance between flocculating spheres is smaller than the radius of the spheres, the resonance shifts to longer wavelengths.

The more the red shift, the less stable the particle at that salt concentration. Figure 5 shows the spectral properties of SNPs after addition of the salt at pH 4.5, 5.5, 7, and 10. At pH 4.5 there was red shift of 11 nm after addition of approximately 1.5 M NaCl (Figure 5(a)). Moreover, continuous decrease in the absorbance with respect to time after addition of salt solution can be seen. A mild hump at 677 nm indicates the agglomeration of nanoparticles in the solution.  In contrast to the above observations, there was blue shift of 22, 3, and 8 nm at pH 5.5, 7, and 10, respectively (Figures 5(b)5(d)). Blue shift in this case can be either due to reduction in the size of SNPs and/or multiple coatings of surface protecting agents on SNPs. It also indicates stabilisation of the SNPs in the solution due to favourable thermodynamic interaction of capping proteins on the surface of SNPs. In agreement with spectral as well as morphological features of SNPs, decrease in the particle size as well as stabilization of the nanoparticles with respect to time can be seen in Figures 3( )–3(E).

Another important terminology to display the stability of the nanoparticles is flocculation parameter (FP) originally used by Wiesbecker et al. [20] and partially modified by Sastry et al. [21]. FP of SNPs with respect to time is shown in Figure 6(a). It can be clearly seen that, in pH value 4.5, FP was found to be increasing with respect to time indicating the agglomeration or ripening of the SNPs. This finding is also supported by heavy red shift seen at this pH value (Figure 5(a)). Moreover, presence of slight turbidity in the SNPs (inset of Figure 2(b)) shows agglomeration in agreement with the above finding. The presence of negative charge on SNPs was confirmed by zeta potential studies (Figure 6(b)) which indicates the rapid stabilisation of the nanoparticles in the solution.

At pH 5.5, FP was found to be increasing with increase in time. This indicates agglomeration of the nanoparticles as evident from the colour of the solution. However, no signs of agglomeration are seen in the SEM image. Blue shift in this case indicated the agglomeration or increase in the multiple coatings on the surface of nanoparticles which may result in agglomeration. At alkaline pH (7 and 10), FP was found to increase initially but became constant and after 15 min finally dropped to some extent. Decrease in the FP value indicates more stability of the nanoparticles [37, 38].  Consistent increase in the negative charge with respect to pH (from basic to acidic) indicates the rapid stabilisation of the nanoparticles (Figure 6(b)).

4. Conclusions

T. bispinosa can be used as a potential alternative to available chemical methods used for commercial production of SNPs due to its exceptionally high reducing potential which in turn is due to presence of high amount of antioxidants. It takes only 120 sec at 28 ± 2°C for the reduction of SNPs which makes it one of the most pivotal plant materials reported till date. SNPs formed at alkaline pH were highly stable and monodispersed proving their relevance for biological applications such as drug delivery. Cyclic voltammetry could be used as potential tool to assess the reduction potential of extracts with respect to time.

Authors’ Contribution

Sunil Pandey and Ashmi Mewada have equal contributions to the work.

Acknowledgments

The authors wish to acknowledge the financial support provided by the authorities of SICES, Ambernath, and specially Mr. K. M. S. Nair and Mr. K. M. K. Nair. They give special thanks to Mrs. Chalke, TIFR Mumbai, for carrying SEM analysis. They acknowledge IIT Bombay, SAIF department, for carrying out ICP-AES analysis. The authors are obliged to reviewers for their valuable suggestions.

Supplementary Materials

Supplementary material include calculation of FWHM and the corresponding values. Others include EDAX and XRD of synthesized SNPs. Explanation about surface functionality using FT-IR and TGA has been provided.

  1. Supplementary Material