Document Type : Research Paper
Authors
1 Department of Chemistry, Faculty of Science, University of Zabol, Zabol, Iran
2 Department of Science, Arak University of Technology, Arak, Iran
Abstract
Keywords
INTRODUCTION
Chitosan is a linear biomedical polysaccharide and it is made by treating the chitin shells of crustaceans with an alkaline substance in excess as a reagent and water as a solvent. It can be used inagriculture as a seed treatment, bio-pesticide that helps plants to fight off fungal infections, wine making, self-healing polyurethane paint coating, antibacterial bandages and deliver drugs through the skin.. Chitosan is hypoallergenic antibacterial and biodegradable and its derivatives have been used in nonviral gene delivery, transfect breast cancer cells, cytotoxicity; hemostatic agents, pain reducing, transport of polar drugs and treat burn wounds. Chitosan has a positive charge under acidic conditions that comes from protonation of its free amino groups which leads to an increase in solubility [1-7].
Silver nanoparticles have been the subject of extensive research in the frame of nanotechnology, mainly owing to their unique optical properties. Indeed, the free electron gas of Ag such nanoparticles features a resonant oscillation upon illumination in the visible part of the spectrum. The spectral properties of this resonance depend on the constitutive material, the shape of the nanoparticles and its environment. This resonant electronic oscillation is called localized surface plasmon (LSP), and the field of research that studies the fundamentals and applications of LSP is known as nanoplasmonics. Plasmonic nanoparticles can behave as efficient nanosources of heat, light or energetic electrons, remotely controllable by light [8-11].
Nanostructured silver compounds have achieved great attention, due to their potential applications in different areas of technology such as electronic, sensor, solar cells and photo-catalysts. Nano particles with smaller sizes and larger specific surface areas can shorten the diffusion distance of photo generated carriers transferring to the surface of photo catalysts, and increase the surface catalytic active sites [12-15]. In this work Ag and Chitosan-Ag nanocomposites were made by a fast chemical procedure by three applicable hydrothermal, sonochemical and microwaves methods in water as a green solvent.
MATERIALS AND METHODS
XRD patterns were recorded by a Philips, X-ray diffractometer using Ni-filtered CuKα radiation. SEM images were obtained using a KYKY instrument model EM3200. Prior to taking images, the samples were coated by a very thin layer of Pt (using a BAL-TEC SCD 005 sputter coater) to make the sample surface conductor and prevent charge accumulation, and obtaining a better contrast. A multiwave ultrasonic generator (BandelineMS 73), equipped with a converter/transducer and titanium oscillator, operating at 20 kHz with a maximum power output of 150 W. AgNO3, NaBH4, starch, glucose, gelatin, poly vinyl pyrrolidone and acetone were purchased from Merck or Aldrich and all the chemicals were used as received without further purifications.
Synthesis of silver nanoparticles by hydrothermal, microwave and sonochemical methods
1 g of AgNO3 was dissolved in 200 ml ofdeionized water. 10 ml of NaBH4 solution (1M) was then slowly added to the solution. For hydrothermal method the solution was added to autoclave reaction and it was maintained at 180 º C for 5h. For microwave procedure the solution was irradiated at 600 W for 5 min. for sonochemical preparation the solution was maintained at 150 W for 30 min until a brown precipitate was then centrifuged and rinsed with distilled water. The obtained precipitate was calcinated at 80ºC and its colour goes brown.
Synthesis of Chitosan-Ag nanocomposite
1 g of Chitosan was dissolved in 10 ml of deionized water (with addition of 1 ml of acetic acid). Then 1g of AgNO3 deionized water was added to the mixture containing Chitosan. After 30 minutes the NaBH4 solution was slowly added to the aqueous solution and was stirred for 5 hour. The obtained precipitate was dried at 50ºC for 2 hour (Fig. 1).
RESULTS AND DISCUSSION
The composition of the Chitosan-Ag nanocomposite was investigated. Presence of face centred cubic phase (JCPDS No.:891010, space group: Fm-3m, strong Bragg reflection peaks can be seen which correspond to the (111), (200), (220) and (311) reflections) was confirmed and is illustrated in Fig. 2. The crystalline sizes from Scherrer equation, Dc=Kλ/βCosθ, was estimated, β is the width of the observed diffraction peak at its half maximum intensity, K is the shape factor, which takes a value of about 0.9, and λ is the X-ray wavelength (CuKα radiation, equals to 0.154 nm). The average crystalline size for Ag nanoparticles was found to be about 30 nm respectively.
Scanning electron microscopy was employed for estimation of morphology and particle size of the products. Fig. 3. illustrate SEM images of the Ag nanoparticles synthesized by hydrothermal (180 ºC, 5h) without using any surfactant and capping that confirm nanostructures were synthesized. The mediocre size was approved about 40 nm. These conditions were chosen as a basic reaction in this work and effect of various parameters was investigated on the blank reaction.
The influence of microwave waves (600W, 5 min) on the size and shape was also examined, outcomes illustrate by applying microwave at lower reaction times uniform nanoparticles with lower diameter size were prepared (Fig. 4). The average particle size is about 50 nm, results confirm bigger product was prepared in comparison to other products.
Fig. 5 illustrate SEM images of silver nanoparticles prepared by sonochemical (150W, 30 min) the results confirm that also mono-disperse nanostructure with average size less than 70 nm were synthesized.
Fig. 6. shows the FT-IR spectrum of the as-prepared Chitosan-Ag nanocomposite by applying lemon extract, the absorptions bands at 400-600cm-1 are assigned to the stretching mode of Ag-O. The spectrum exhibits broad absorption peak around 3300-3400 cm−1, corresponding to the stretching mode of O-H and N-H bonds. The band near 2900 cm−1 is assigned to C-H vibration mode. Absorption around 1100 cm -1 is related to C-O bonds.
UV-Vis absorption of Ag nanoparticle is shown in Fig. 7. With agreement to previous published works silver nanoparticles show an absorption around 440 nm. The as-prepared nanocomposite has the potential to be applied to improve environmental problems associated with organic and toxic water pollutants. Antibacterial effect of Chitosan-Ag nanocomposite on the degradation of E Coli bacteria is shown in Fig 8. As time increase; more bacteria are degraded on the nanoparticles catalyst, until obvious circle was observed around antibacterial chitosan-Ag disk.
CONCLUSIONS
In conclusion, synthesis, characterization and antibacterial activity of Ag and Chitosan-Ag nanocomposites were reported. SEM confirmed that by using three hydrothermal, sonochemical and microwave methods mono-disperse products with bigger sizes were prepared. The antibacterial behaviour of Chitosan-Ag nanocomposite was evaluated using the degradation of E coli bacteria. Maximum absorption peak (λmax) of silver was observed from UV-vis absorption spectra and has agreement to previous scientific literatures. The results show that these three methods is facile and cost effective method for preparation of Chitosan-Ag nanocomposites as a suitable candidate for antibacterial applications.
CONFLICT OF INTEREST
The authors declare that there are no conflicts of interest regarding the publication of this manuscript.
ACKNOWLEDGMENT
This work was funded by University of Zabol Grant No. UOZ-GR-95-7.