ANTIBACTERIAL EVALUATION OF AFANG LEAF EXTRACT AND ITS SYNTHESIZED SILVER NANOPARTICLES
CHAPTER ONE
INTRODUCTION AND LITERATURE REVIEW
1.0 INTRODUCTION
Nanoscience has been the subject of substantial research in recent years. It has been explored by researchers in various fields of science and technology (Kholoud et al. 2010). The novel properties of NPs have been exploited in a wide range of potential applications such as in medicine, cosmetics, renewable energies, environmental remediation, biomedical devices (Quang Huy, 2013), electronics, optics, organic catalysis, vector control, sensor, etc., have drawn extensive attention to this field of study (Mousavand et al. 2007). Among the metals, silver nanoparticles have shown potential applications in various fields such as the environment, bio-medicine, catalysis, optics and electronics (Rao et al., 2000). Silver nanoparticles are mostly smaller than 100 nm and consist about 20–15,000 silver atoms. In its nanoscale form, silver exhibits unique physicochemical and biological activities. This has made them useful as sensor, vector control, antimicrobial, anticancer, and antiplasmodial agents, catalysts, among others (Elemike et al. 2014; Vinod et al. 2014; Kathiravan et al. 2014; Saraschandra and Sivakumar 2014; Namita and Soam 2014).
Concerted effort has been made to synthesize diverse range of silver nanoparticles varying in size, geometry, and morphology because of their potential applications, particularly in electronics (P. V. Kamat, 2002), electrochemical sensing (L. M. Liz-Marzán, 2006), catalysis (F. Zhang, Y. Pi et al., 2007), and antimicrobial properties (T. Sakai et al., 2006). The size, geometry, dispersion and stability often determine the suitability of the nanoparticles for certain applications. Synthesis may involve physical means such as ultraviolet light, microwaves, photo-reduction, or chemical reduction using hydrazine, ascorbic acid, sodium borohydride, glucose, and organic stabilizers or biological means using plant extract, microorganism or plant sap. Several physical and chemical methods have been used to synthesize and stabilize silver nanoparticles (Senapati et al., 2005, Klaus-Joerger et al., 2001). The most popular chemical approaches, including chemical reduction using a variety of organic and inorganic reducing agents, electrochemical techniques, physicochemical reduction, and radiolysis are widely used for the synthesis of nanoparticles.
Although these means are fast and easy, they are either expensive or toxic particularly the chemical method and may lead to non eco-friendly byproducts thus the need for environmental, nontoxic synthetic protocols for nanoparticles synthesis. In the global efforts to reduce generated hazardous waste, “green” chemistry and chemical processes are progressively integrating with modern development in science and industry (Sharma et al., 2009) leading to the developing interest in biological approaches which are free from the use of toxic chemicals as by products. Biological methods can be used to synthesize nanoparticles without the use of any harsh, toxic and expensive chemical substances. The bioreduction of metal ions by combinations of biomolecules found in the extracts of certain organisms (e.g., enzymes/proteins, yeast, fungi, bacteria and plants) is environmentally benign, yet chemically complex (Ankamwar et al., 2005). It has been elucidated that biomolecules with carbonyl, hydroxyl, and amine functional groups have the potential for metal ion reduction and capping of the newly formed particles during their growth processes (Harekrishna et al., 2009, He et al., 2007). Biomolecules in plants and spices extract are essential oils (terpenes, eugenols, e.t.c.), polyphenols, carbohydrates, e.t.c. and can reduce and stabilize Ag+ to Ag0. It provides advancement over chemical and physical methods as it is cost effective and environment friendly.
1.1 LITERATURE REVIEW
Disease-causing microbes are becoming resistant to drug therapy and therefore poses great public health problem. Many researchers are now engaged in developing new effective antimicrobial reagents with the emergence and increase of microbial organisms resistant to multiple antibiotics, which will increase the cost of health care. Colloidal silver has been known for a long time to possess antimicrobial properties and also to be non-toxic and environmentally friendly. It has been used for years in the medical field for antimicrobial applications such as burn treatment (Parikh et al. 2005; Ulkur et al 2005), elimination of microorganisms on textile fabrics (Jeong et al. 2005; Lee et al. 2007; Yuranova et al. 2003), disinfection in water treatment (Russell and Hugo 1994; Chou et al. 2005), prevention of bacteria colonization on catheters (Samuel and Guggenbichler 2004; Alt et al. 2004; Rupp et al. 2004), etc. It has also been found to prevent HIV from binding to host cells (Sun et al. 2005). The mechanism of the bacterial effect of AgNP as proposed is due to the attachment of AgNPs to the surface of the cell membrane, thus disrupting permeability and respiration functions of the cell (Kevitec et al. 2008). It is also proposed that AgNPs not only interact with the surface of a membrane but can also penetrate inside the bacteria (Morones et al. 2005), but the effects of silver nanoparticles (AgNP) on microorganisms have not been developed fully. Researchers believe that the potential of colloidal silver is just beginning to be discovered (Dorjnamjin et al., 2008).
1.2 Nanotechnology
Nanoparticles are viewed as the fundamental building blocks of nanotechnology (Mansoori et al., 2005). They are the starting points for preparing many nanostructured materials and devices and their synthesis is an important component of the rapidly growing research efforts in nanoscience and nanoengineering (Mansoori et al., 2007).
In nanotechnology, a nanoparticle is defined as a small object that behaves as a whole unit in terms of its transport and properties. Nanoparticles can equally be called ultrafine particles since their sizes range from 1 to 100 nm. Fine particles ranges from 100 to 2,500 nm, while coarse particles are sized between 2,500 and 10,000 nm (Williams, 2008). A nanometer is one billionth of a meter (10-9 m), roughly the width of three or four atoms, smaller than the wavelength of visible light and a hundred-thousand the width of human hair.
Nanoparticles can be made of materials of diverse chemical nature, the most common being metals, metal oxides, silicates, non-oxide ceramics, polymers, organics, carbon and biomolecules. Nanoparticles exist in several different morphologies such as spheres, cylinders, platelets, tubes, flowers, cubes etc. They possess unique physiochemical, optical and biological properties which can be manipulated to suit a desired application. Nanoparticles are of great interest due to their externally small size, and large surface to volume ratio. They exihibit utterly novel characteristics compared to the large particles of the bulk material and have been included in fields of science as diverse as surface science, organic chemistry molecular biology, semi conductor physics, microfabrication, material science, inorganic chemistry and so on.
The concepts that seeded nanotechnology were first discussed in 1959 by renowned physicist Richard Feynman in his talk “There’s Plenty of Room at the Bottom”, in which he described the possibility of synthesis via direct manipulation of atoms. In 1974, “Norio Taniguchi now used the word nanotechnology to describe precision manufacturing materials at the nanometer level which refers to the synthesis, manipulation, and control of matter at nano dimensions that will make most products lighter, stronger, cleaner, less expensive and more precise.
1.3 Physiochemical Properties of Nanoparticles
Nanoparticles also often possess unexpected optical properties as they are small enough confine their electrons and produce quantum effects e.g. gold nanoparticles appear deep red in dark solutions.
A unique property among nanoparticles is quantum confinement in semiconductor particles, surface plasmon resonance in some metal particles and super paramagnetism in magnetic materials. For example, ferroelectric materials smaller than 10 nm can switch their magnetization direction using room temperature thermal energy. Thus this property is not always desired in nanoparticles thus making them unsuitable for memory storage.
Suspensions of nanoparticles are possible since the interaction of the particle surface with the solvent is strong enough to overcome density differences, which otherwise usually result in a material either sinking or floating in a liquid.
The high surface area to volume ratio of nanoparticles provides a tremendous driving force for diffusion, especially at elevated temperatures. Sintering can take place at lower temperatures, over shorter time scales than for larger particles.
1.4 Methods of Nanoparticles Synthesis
Currently, many methods have been reported for the synthesis of nanoparticles which include chemical, physical, biological and photo-induced approach.
1.4.1 Chemical Approach:
The chemical approach is the most used method since it for provides an easy way to synthesize nanoparticles in solution. This consists of the chemical reduction of a metal salt in solution followed by the crystallization of zero-valence metal particles. The particle synthesis is usually conducted in the presence of a stabilizing agent that prevents excessive molecular growth and/or aggregation of the metal nanoparticles. Hence when nanoparticles are produced by chemical synthesis, three main components are needed: a salt (e.g. AgNO3), a reducing agent (e.g. ethylene glycol) and a stabilizer agent (e.g. PVP) to control the growth of the nanoparticles and prevent them from aggregating.
In one study, Oliveira and coworkers (2005) prepared dodecanethiol-capped silver NPs, according to Brust procedure (Brust et al., 2002) based on a phase transfer of an Au3+ complex from aqueous to organic phase in a two-phase liquid-liquid system, which was followed by a reduction with sodium borohydride in the presence of dodecanethiol as stabilizing agent, binding onto the NPs surfaces, avoiding their aggregation and making them soluble in certain solvents. They reported that small changes in synthetic factors lead to dramatic modifications in nanoparticle structure, average size, size distribution width, stability and self-assembly patterns.
1.4.2 Physical Approach:
In physical processes, nanoparticles are synthesized by evaporation-condensation, exploding wire technique, chemical vapour deposition, microwave irradiation, pulsed laser ablation, supercritical fluids, sonochemical reduction, and gamma radiation with evaporation-condensation and laser ablation being the most important physical approaches. The absence of solvent contamination in the prepared thin films and the uniformity of NPs distribution are the advantages of physical synthesis methods in comparison with chemical processes.
Siegel and colleagues (2012) demonstrated the synthesis of AgNPs by direct metal sputtering into the liquid medium. The method, combining physical deposition of metal into propane-1, 2, 3-triol (glycerol), provides an interesting alternative to time-consuming, wet-based chemical synthesis techniques. Silver NPs possess round shape with average diameter of about 3.5 nm with standard deviation 2.4 nm. It was observed that the NPs size distribution and uniform particle dispersion remains unchanged for diluted aqueous solutions up to glycerol-to-water ratio 1 : 20.
1.4.3 Biological Approach:
As stated earlier in the chemical method of synthesis, three main components are needed: a salt (e.g. AgNO3), a reducing agent (e.g. ethylene glycol) and a stabilizer agent (e.g. PVP) to control the growth of the nanoparticles and prevent them from aggregating. In biological synthesis of nanoparticles, the reducing agent and the stabilizer are replaced by molecules produced by living organisms. These reducing and/or stabilizing compounds can be utilized from bacteria, fungi, yeasts, algae or plants.
The development of efficient green chemistry methods for synthesis of nanoparticles has become a major focus of researchers. In the global effort to reduce generated waste and toxic materials, “green” chemistry and chemical processes are progressively integrating with modern developments in science and industry. They have investigated in order to find an eco-friendly technique for production of well-characterized nanoparticles. Various approaches using plant extracts have been used for the synthesis of nanoparticles. These approaches have many advantages over chemical, physical, and microbial synthesis because there is no need of the elaborate process of culturing and maintaining the cell, using hazardous chemicals, high-energy and wasteful purifications.
The first successfully reported synthesis of nanoparticles assisted by living plants appeared in 2002 when it was shown that gold nanoparticles, ranging in size from 2-20 nm, could form inside alfalfa seedlings. Subsequently it was shown that alfalfa could form silver nanoparticles when exposed to a silver rich medium. Other works on plants and plant parts that have been used for the synthesis of silver nanoparticles are Thevetia peruviana latex (Rupiasih et al. 2013), Wrightia tinctoria (Bharani et al. 2011), Solanum xanthocarpum (Muhammad et al. 2012), Opuntia ficus (Silva-de-Hoyos et al. 2012), Sphaeranthus amaranthoides (Swarnalatha et al. 2012), Punica granatum (Naheed et al. 2012) Citrullus colocynthis (Satyavani et al. 2011), Eucalyptus chapmaniana (Ghassan et al. 2013), Acacia auriculiformis (Nalawade et al. 2014), Ficus benghalensis, Azadirachta indica (Debasis et al. 2015), e.t.c.
The biomolecules present in these plants are responsible for the formation and stabilization of silver nanoparticles (Iravani et al. 2014). Nanoparticles produced by plants are more stable and the rate of synthesis is faster than in the case of microorganisms. Moreover, this method is simple, cost effective, energy-saving and reproducible. The nanoparticles are more various in shape and size in comparison with those produced by other organisms. The advantages of using plant and plant-derived materials for biosynthesis of metal nanoparticles have interested researchers to investigate mechanisms of metal ions uptake and bioreduction by plants, and to understand the possible mechanism of metal nanoparticle formation in plants.
1.4.4 Photo-induced Approach:
The photo-induced synthetic strategies can be categorized into two distinct approaches, that is the photo-physical (top down) and photochemical (bottom up) ones. The former could prepare the NPs via the subdivision of bulk metals and the latter generates the NPs from ionic precursors. The NPs are formed by the direct photo-reduction of a metal source or reduction of metal ions using photo-chemically generated intermediates, such as excited molecules and radicals which are known as photosensitization in the synthesis of NPs.
Huang and coworkers (2008) reported the synthesis of silver NPs in an alkaline aqueous solution of AgNO3/carboxymethylated chitosan (CMCTS) using UV light irradiation. CMCTS, a watersoluble and biocompatible chitosan derivative, served simultaneously as a reducing agent for silver cation and a stabilizing agent for the silver NPs. The diameter range of produced silver NPs was 2–8 nm, and they can be dispersed stably in the alkaline CMCTS solution for more than 6 months
The main advantages of the photochemical synthesis are;
It is a clean process, with high spatial resolution, and convenience of use.
It has great versatility; the photochemical synthesis enables one to fabricate the NPs in various mediums including emulsion, surfactant micelles, polymer films, glasses, cells, etc.
1.5 Applications of Nanoparticles
There is wide applicability of nanoparticles due to their interesting optical, conductive, physio-chemical, electronic, antimicrobial properties.
1.5.1 Medical and Pharmaceutical Applications
Nanoparticles can be made to control and sustain release of the drug during the transportation and as well as the location of the release since the distribution and subsequent clearance of the drug from the body can be altered. An increase in the therapeutic efficacy and reduction in the side effects can also be achieved. Targeted drugs may be developed.
The surface change of protein filled nanoparticles has been shown to affect the ability of the nanoparticles to stimulate immune responses. Researchers are thinking that these nanoparticles may be used in inhalable vaccines. Researchers are developing ways to use carbon nanoparticles called nanodiamonds in medical applications. For example, nanodiamonds with protein molecules attached can be used to increase bone growth around dental or joint implants.
