Research Article - (2016) Volume 7, Issue 4
Development of rapid, efficient, eco-friendly processes for synthesis of metal nanoparticles is one of the most significant thrust areas of nanobiotechnology. Medicinal plants are rich source of bioactive principles of diverse therapeutic importance. However, this unique phytochemistry can play a critical role not only in reduction of metal ions to their corresponding nanoparticles but also help to stabilize the same. Herein we report for the first time the synthesis of silver and gold nanoparticles using a medicinal plant, Barleria prionitis leaf extract. The synthesis was complete within 5 h and UV-vis spectra exhibited signature peaks at 420 nm and 540 nm for silver and gold nanoparticles, respectively. 3 mM AgNO3 and 2 mM HAuCl4 showed maximum synthesis of silver nanoparticles and gold nanoparticles, respectively at 50°C. High resolution transmission electron microscopy revealed that majority of the silver nanoparticles was spherical in a size range between 10 to 20 nm while gold, between 10 to 25 nm. Various exotic shapes were seen in case of gold nanoparticles like spheres, triangles and pentagons. The bioreduced nanoparticles were further characterized and confirmed using energy dispersive spectra, dynamic light scattering, X-ray diffraction spectrometry. Reducing sugars, ascorbic acid, starch, citric acid along with phenolics were found to be present in the extract that might play a major role in bioreduction and stabilization. GCMS/MS analysis further confirmed the diverse phytochemistry confirming tetradecane, 1-dodecanol, 3,7,11-trimethyl- and tert-hexadecanethiol as most predominant. Both silver and gold nanoparticles exhibited efficient catalytic reduction of o-nitrophenol.
Keywords: Barleria prionitis leaf extract, Gold nanoparticles, Silver nanoparticles, Gas chromatography mass spectrometry, catalysis
Nanosized metal particles have got prime attention in past decades as their therapeutic properties are based on their size and shape. Thus fabrication, characterization and modification of their functional properties are critical for their applications in diagnostics and biomedical applications [1-3]. Nanomedicine bridges the gap between physics of the nanostructures and the biology behind their medicinal significance. Rationally designed nanomaterials have exhibited extensive applications in drug delivery, nanobiotechnology, targeted delivery, microfluidics, biosensors and microarrays to tissue micro-engineering [4,5]. Amongst diverse metal, organic, polymeric nanoparticles and liposomes, gold nanoparticles (AuNPs) and silver nanoparticles (AgNPs) have got wide applications in targeted, site-specific drug delivery thereby showing anticancer activity by eliminating tumorous outgrowth without any collateral damage [6]. Similarly, various efforts to design functionalized nanoparticles have helped in delivery of vaccines and anticancer drugs. Such nanomaterials serve the dual purpose as nano-carriers and enhancement of drug bio-distribution. Spectacular success is achieved towards delivery of drugs through the blood brain barrier for targeting brain tumors. As more and more applications of nanomedicine in therapy are being explored, the need to develop more biocompatible nontoxic nanoparticles is gaining importance. Various biological methods for synthesis of nanoparticles using bacteria, fungi, algae are reported recently [7-14]. However, medicinal plants used in traditional, complementary and alternative therapy are considered as most promising biological route for synthesis of biocompatible metal nanoparticles. Recently we have reported nanobiotechnological applications about various medicinal plants like Gloriosa superba,Gnidia glauca, Dioscorea bulbifera, Plumbago zeylanica, Adiantum philippense L., Pterocarpus santalinus and Aloe vera [15-22].
Barleria prionitis, commonly known as Vajradanti is used for treating fever, respiratory diseases, toothache, joint pains, glandular swellings, boils, piles, ulcers and enlargement of scrotum [23,24]. Various parts of B. prionitis like leaf, stem, root, bark and flowers are utilized for treatment of catarrhal affections, whooping cough, inflammations, urinary infection, jaundice and gastrointestinal disorders. Diverse phytochemicals like balarenone, pipataline prionisides, barlerinoside, verbascoside, shanzhiside methyl ester, barlerin, acetylbarlerin, lupulinoside, scutellare, isolated from B. prionitis extracts exhibit antimicrobial, anthelmintic, antifertility, antioxidant, antidiabetic, antiinflammatory, anti-arthritic, cytoprotective, hepatoprotective, diuretic, antidiarrhoeal, enzyme inhibitory and anti-nociceptive activities without any toxic effects [25]. However, there are no detailed reports on its applications in nanobiotechnology.
In view of the background, it is of utmost scientific rationale to explore the potential of B. prionitis in nanotechnology. Thus, herein we report for the first time the detailed optimization and characterization studies of the AgNPs and AuNPs synthesized by B. prionitis (BPLE). Further, the bioreduced nanoparticles were checked for their chemocatalytic property.
Plant material and preparation of extract
B. prionitis leaves were collected from Western Ghats of Maharashtra, India which were dried in shade for 2-3 days at room temperature. The dried leaves were pulverised in an electric blender into fine powder. B. prionitis leaf extract (BPLE) was prepared by boiling 5 g of leaf powder in 100 mL distilled water for 5 min. After decantation the extract was centrifuged at 3000 rpm for 10 min and filtered through Whatman No.1 filter paper. The filtrate was collected and stored at 4°C for further use [18].
Synthesis and characterization of silver and gold nanoparticles
In 95 mL of 1 mM AgNO3 solution 5 mL of BPLE was added to initiate the synthesis of AgNPs. The reaction mixture was shaken at 40°C for 5 h in a shaker incubator. Reduction of Ag+ ions to AgNPs was confirmed by visible colour change and by using UV-visible spectrometry at regular intervals. Similarly, synthesis of AuNPs was achieved by addition of 5 mL of BPLE into 95 mL of 1 mM HAuCl4 solution. Temperature optimization was carried out in a water bath at 4°C–50°C with reflux. Concentration optimization was performed by varying the respective salt concentration from 0.3 to 5 mM. Characterization of the bioreduced nanoparticles was carried out employing high resolution transmission electron microscopy (HRTEM), energy dispersive spectroscopy (EDS), X-ray diffraction (XRD) and fourier transform infrared spectroscopy (FTIR) as per our earlier reports [18].
Phytochemicals analysis
Various components in BPLE such as total phenolic, flavonoid, starch, reducing sugar, ascorbic acid and citric acid were estimated using biochemical assays reported earlier [Ghosh IJN, 2012]. Similarly, identification of the principle phytochemicals was carried out using GC-MS/MS analysis [26].
Catalytic activity
A standard catalytic test reaction was carried out in 4.5 mL quartz cuvettes. Aqueous solution of 0.1 mM o-nitrophenol (2 mL) was mixed with 1 mL of 0.1 M sodium borohydride solution. The reaction was started by addition of 15 μL of 10 mM AuNPs and AgNPs separately. Immediately after catalyst addition, time dependent absorption spectra were collected at 5 min intervals for 30 min at room temperature in the range of 250-550 nm. The background subtraction was done using deionized water as the reference [20].
UV-visible spectroscopy
Colour of the AgNO3 aqueous solution turned to light brown initially after 1 h on addition of BPLE which gradually developed into intense brown confirming the synthesis of AgNPs. UV-visible spectra taken at regular intervals further showed a gradual development of peak at 420 nm from 0 to 5 h (Figure 1A). Similarly, faint yellow colour of HAuCl4 solution initially turned into purple and finally changed into intense ruby red colour indicating the synthesis of AuNPs on addition of BPLE. Although at 0 h and 0.5 h no significant peak was observed in UV-visible spectra, from 1 h onwards a peak was observed at 540 nm which sharply increased in 2 h (Figure 1B). With further incubation, the peak at the same wavelength increased till 5 h. Optimization studies revealed that higher temperature facilitated the synthesis of both AgNPs and AuNPs (Figure 2A and 2B). Least reduction was achieved with 4°C, while maximum bioreduction by BPLE was observed at a higher temperature of 50°C. Concentration optimization studies showed that for AgNPs synthesis the concentration of AgNO3 played a critical role. Higher salt concentration showed greater bioreduction of AgNPs as observed by recording absorbance at 420 nm. Although till 2 h, much significant difference was not observed, from 3 h onwards 4 mM and 5 mM showed higher rate of AgNPs synthesis. However, between 4 h to 5 h, 3 mM AgNO3 showed maximum synthesis (Figure 3A). In case of AuNPs higher rate of synthesis was achieved by increasing the concentration till 2 mM HAuCl4 (Figure 3B). Thereafter, on increasing the salt concentration, a drop in the rate of synthesis was observed.
HRTEM, EDS and DLS analysis
Majority of the AgNPs synthesized by BPLE were found to be spherical ranging from 10 to 20 nm (Figure 4A). Particles were fairly dispersed and rarely found to be in agglomeration. Smaller AgNPs combined to form particles with larger dimensions which were oval in shape (Figure 4B). AuNPs showed anisotropy where although spherical particles were major, particles of other exotic shapes were also visualized. Most of the AuNPs synthesized by BPLE were found to be spherical ranging from 10 nm to 25 nm (Figure 4C). Particles were free and agglomeration was not observed. Blunt ended nanopentagons were also seen along with nanotriangles (Figure 4D). EDS analysis exhibiting the signature peaks for elemental Ag and Au in the bioreduced nanoparticles confirmed the synthesis of AgNPs and AuNPs, respectively by BPLE (Figure 5A and 5B). Size distribution of bioreduced nanoparticles observed in DLS was also found to be in close agreement with the HRTEM results (Figure 6A and 6B).
Figure 4: High-resolution transmission electron micrographs of nanoparticles synthesized by BPLE. (A) AgNPs bioreduced by BPLE, inset bar representing of 200 nm; (B) Magnified image of very small spherical AgNPs bioreduced by BPLE, inset bar representing of 20 nm; (C) AuNPs synthesized by BPLE, inset bar representing of 200 nm; (D) Magnified truncated nano-triangles, pentagons and spheres synthesized by BPLE, inset bar representing of 20 nm.
XRD analysis
The Figure 7A shows the diffraction peaks of AgNPs synthesized using BPLE as a reducing agent, which shows the characteristic diffraction peaks at (111), (200), (220), and (311) usually observed for face-centered cubic silver crystals (JCPDS card No. 04-0783). Similarly, the crystal phase of AgNPs and AuNPs, bioreduced by BPLE was confirmed using XRD, as shown in the Figure 7B. The observed characteristic diffraction peaks at (111), (200), (220), and (311) matches well with JCPDS card No. 04–0784, confirming the cubic phase of AuNPs. A broadening of the diffraction peaks can be observed for Figure 7A and 7B, possibly due to surface strain and reduced particle size as observed in the HRTEM images.
FTIR analysis
The bending vibrations associated to amine (N-H) can be observed in the FTIR for BPLE before reduction (Figure 8A) as well as after synthesis of AgNPs (Figure 8B) and AuNPs (Figure 8C). However, the BPLE showed a shift of peaks to lower wavenumber (1631.61 cm-1 →1579.63 cm-1) region. An increase in the transmittance was observed for bending vibrations related to alkane at 1397.71 cm-1 after bioreduction of AgNPs and AuNPs. Similarly, vibrational stretching of ether group (C-O) also showed the same trend of increase in the transmittance after bioreducton. Additional vibration associated with alkene (=C-H) was also observed after synthesis of AgNPs and AuNPs which could be attributed due to the bond formation with the organic moieties of BPLE, thereby giving it stability.
Phytochemical analysis
Various phytochemicals were observed to be present in BPLE, major being reducing sugars. Presence of high amount of ascorbic acid was also observed followed by starch (Table 1). BPLE showed presence of phenolics and citric acid as well. GCMS/MS analysis confirmed the diverse phytochemistry of BPLE as well, the predominant being, tetradecane, 1-dodecanol, 3,7,11-trimethyl- and tert-hexadecanethiol.
Sample | Phytochemicals (µg/mL) | |||||
---|---|---|---|---|---|---|
Phenolic content | Starch content | Reducing sugars | Ascorbic acid | Citric acid | ||
BPLE | 7.77 | 55.44 | 384.40 | 100 | 10.03 |
Table 1: Phytochemical composition of BPLE.
Catalytic activity
The catalytic model reaction of o-nitrophenol to o-aminophenol by sodium borohydride with AgNPs and AuNPs was investigated using UV-Vis spectroscopy. Clear solution of o-nitrophenol turns pale yellow upon adding sodium borohydride. After the addition of gold nanoparticles, the pale yellow colour slowly changes to colourless solution indicating conversion of nitro-group to amine group. As shown in Figure 9A and 9B, during time intervals of 5 to 30 min, the intensity of the characteristic absorption band of o-nitrophenol at 400 nm disappeared, whereas a new peak at 290 nm (due to o-aminophenol) appeared. This demonstrated the capability of the bioreduced AgNPs and AuNPs to act as biocompatible chemocatalysts. However, in case of AgNPs no conversion was observed after 10 min (Table 2).
Sr. No | Name of compounds | RTS | Formula | Molecular weight |
---|---|---|---|---|
1 | 1-Octen-3-ol | 8.7 | C8H16O | 128 |
2 | Decane, 2,3,5,8-tetramethyl- | 9.55 | C14H30 | 198 |
3 | 2-Undecanethiol, 2-methyl- | 11.83 | C12H26S | 202 |
4 | Heptadecane, 2,6,10,15-tetramethyl- | 16.26 | C12H44 | 296 |
5 | Tetradecane, 2,6,10-trimethyl- | 17.65 | C17H36 | 240 |
6 | 2-Isopropyl-5-methyl-1-heptanol | 19.72 | C11H24O | 172 |
7 | Hexadecane, 1,1-bis(dodecyloxy)- | 22.78 | C40H82O2 | 594 |
8 | Tetradecane | 23.04 | C14H30 | 198 |
9 | Disulfide, di-tert-dodecyl | 25 | C24H50S2 | 402 |
10 | 1-Hexadecanol, 2-methyl- | 25.61 | C17H36O | 256 |
11 | Phenol, 2,4-bis(1,1-dimethylethyl)- | 26.56 | C14H22O | 206 |
12 | 1-Dodecanol, 3,7,11-trimethyl- | 26.88 | C15H32O | 228 |
13 | tert-Hexadecanethiol | 27.11 | C16H34S | 258 |
14 | cis-1-Chloro-9-octadecene | 28.88 | C18H35Cl | 286 |
15 | 3-Chloropropionic acid, heptadecyl ester | 31.69 | C20H39ClO2 | 346 |
16 | 2-Hexadecanol | 34.38 | C16H34O | 242 |
17 | Heptacosane | 34.56 | C27H56 | 380 |
18 | 17-Pentatriacontene | 35.5 | C35H70 | 490 |
19 | 2-Pentadecanone, 6,10,14-trimethyl- | 35.61 | C18H36O | 268 |
Table 2: Main compounds detected by GCMS/MS.
The present study demonstrated a rapid, efficient and environmentally benign route for synthesis of AgNPs and AuNPs using medicinally important plant B. prionitis. UV-visible spectrum showing a characteristic absorption peak at 420 nm that further confirmed the formation of AgNPs which corresponds to surface plasmon resonance of AgNPs as reported earlier using Acalypha indicai leaf extract [27]. UV–visible spectra of AuNPs synthesized using BPLE with surface plasmon resonance band around 540 nm was found to be in close agreement with previous report on synthesis of AuNPs using flower extract of Achillea wilhelmsii [28]. Development of red color was due to the excitation of surface plasmon vibrations in the AuNPs which is absent in bulk metallic gold [29]. The synthesis was completed within 5 h which was found to be rapid compared to other plants like Aloe vera which took 24 h for complete reduction [30]. Optimization studies indicated that both reaction temperature and metal salt concentrations play a major role in the rate of bioreduction which was similar to earlier reports on Plumbago zeylanica [22]. AgNPs synthesized by BPLE were mostly found to be spherical in shape which was even reported in case of AgNPs synthesized by Azadirachta indica (Neem) leaves [31]. AuNPs were found to be of exotic shapes and of varied sizes which was found as well in case of synthesis using other medicinal plants like D. bulbifera [19]. Phytochemical diversity of BPLE included phenolics, reducing sugars, ascorbic acid, citric acid along with many others as evident from GCMS/MS analysis that might play a critical role in both reduction and stabilization of the nanoparticles [32]. AuNPs synthesized by BPLE were found to have efficient catalytic activity as compared to AgNPs. Slow rate of catalytic activity AgNPs might be attributed to their relative larger size and the formation of surface oxide layer as reported in case of Breynia rhamnoides [33]. Our results are in close agreement with the earlier reports on AuNPs synthesized from medicinal plants like Gnidia glauca and Acacia nilotica [1,20,34-36].
A rapid, efficient and environmentally benign synthesis of AgNPs and AuNPs is demonstrated using B. prionitis leaf which is considered as a very significant complementary and alternative medicine against various ailments. Rate of synthesis was found to be a function of time, temperature and concentrations of the salt solution. Diverse groups of phytochemicals like polyphenols, starch, reducing sugars, ascorbic acid and citric acid play critical role in both bioreduction and stabilization of AgNPs and AuNPs that were found to be in a size range between 10 to 25 nm. Exotic shapes of AuNPs were observed. The bioreduced AuNPs and AgNPs show chemocatalytic potential in conversion of o-nitrophenol to o-aminophenol.
The authors acknowledge the help extended for the use of TEM and HRTEM facilities in Chemical Engineering and CRNTS funded by the DST through Nanomission and IRPHA schemes.