Biosynthesis Of Nanoparticles - A New Horizon In Fish Biomedicine

The biogenic nanoparticle has becoming a significant potential technology as the result of phytomining which revealed that metals are usually deposited in the form of nanoparticles. The various biological agents in the form of algae, plants and microbes have emerged as an efficient candidate for the synthesis of nanoparticles.

applications were arising for the infectious disease treatment which involves micro emulsions, vaccines and metallic, inorganic, lipid and polymeric -based nanoparticles. There were two important metal nanoparticles which were gold and silver nanoparticles [1]. The conclusion of various researches has been shown that among those different NPs; silver NPs shows strong inhibitory and microbicidal activity whereas it exhibits lower toxicity tomammalian cells. It was observed that, there has been emerging advancement in researches on nanoparticles which has lot of scope such as production of burn dressings, scaffolds, water purification systems, antimicrobial applications and medical devices. As this chemical method of nanoparticles production has been becoming the raising concernamong the environmentalists due to their adverse effect on ecology, the use of plant extracts for nanoparticles production is being recommended due its healthy nature towards the environment. Even in the industry it produces much lesstoxic waste. So this bionanotechnology, combines biological principles with physical and chemical approaches to produce nano-sized particles with specific functions. Various plant metabolites such as terpenoids, polyphenols, sugars, alkaloids, phenolic acids, and proteins, play an important role in the bio reduction of the metal ions. This article mainly focuses on this emerging green synthesis of nanoparticles with respect to fish medicine applications [2,3].

Different Approaches to Nanofabrication
For nanofabrication, there followed two common procedures which were top -down and bottom -up approach. Assembling individual atoms and molecules to form nanoparticle describes bottom up approach and top-down approach involves fragmenting material to yield a nanoparticle described below in the figure 1.

Synthesis Methods
There were 3 common methods for synthesizing nanoparticles which were described below in the figure 2.
The biogenic nanoparticle has becoming a significant potential technology as the result of phytomining which revealed that metals are usually deposited in the form of nanoparticles. The various biological agents in the form of algae, plants and microbes have emerged as an efficient candidate for the synthesis of nanoparticles. These biogenic nanoparticles involve producing biomolecules from plant extracts to reduce metal ions to nanoparticlesand it is cost efficient, simpler to synthesize. As this process use water soluble plant metabolites for nanoparticle production, this serves a perfect environmental friendly method which is an added advantage. This greener approach in nanoparticle production against fish pathogens can become an asset for the future aquaculture industry as it serves as a potential alternative to antibiotics which leads a sustained infection -free environment which is the impossible dream for many aquaculturists.  Among the above described methods, the physical method of synthesizing is time and energy consuming and this involves synthesis at high temperature and pressure. The chemical method is simple and inexpensive and lowtemperature synthesis method, use of toxic reducing and stabilizing agents makes it harmful. The most important green synthesis of nanoparticles were easy, efficient and eco-friendly and this method eliminates the use of toxic chemicals, consume lessenergy and produce safer products and by products. The NPs synthesized in plant extracts already have a functionalized surface that can contain the organic ligands, proteins, polysaccharides and polyatomic alcohols that are absent in NPs synthesized using physical and chemical methods and this proves as a new platform in developing efficient nanoparticles which is recommended more.

Green Synthesis
The formation of nanoparticles usingplant extracts has become a major head start method in terms of its interaction and effect on theenvironment; it is completely environmentally friendly and does not pose any threats even from itswaste. During the process production of metal nanoparticles, the plant extract is simply mixed with a solution of metal salt at room temperature ( Figure 3). It is a quick reaction and usually takes only minutes to complete. The developed nanoparticle properties and production time depend on various characteristics of plant extract, namely:

Antibacterial Activity against Fish Pathogens
The mechanism of nanoparticles on bacteria are not fully elucidated, the three most common mechanism of toxicity proposed up to now be as follows.
• Uptake of free silver ions followed by disruption • Formation of reactive oxygen species • Direct damage to cell membranes The applications of nanoparticles in aquaculture has promisingly seen in water quality improvement, aquatic animal nutrition, drug delivery, disease diagnosis and management but very few works has been done in the greener approach as it is forming a new horizon in the aquaculture era. Moreover, several reports are availablewhich have shown that AgNPs are effective against pathogenic organism namely B.subtilis, Vibrio cholerae, E.coli and reported that Ag NPs with larger surface area provide a better contact with microorganisms. Biogenic Ag-NP using tea leaf extract (Camellia sinensis) showed bactericidal activity against Vibrio harveyi in juvenile Feneropenaeus indicus, but only at high doses of the nanoparticles.The nanoparticles with leaves of Mangiferaindica (mango), Eucalytusterticonis, Carica Papaya and Musa paradisiacal (banana) plants has developed and tested against Aeromonahydrophila. Among them, synthetized nanoparticles with Carica papaya (papaya) show antimicrobial activity with 153.6 µg mL-1 concentration. In 2015, research on biogenic CuO NPs shows enhanced antibacterial activity against all the fish pathogens even at lower concentrations, i.e. above 20 mu g/ mL, which was tested against Aeromonas hydrophila, Pseudomonas fluorescens and Flavobacterium branchiophilum. Further research in 2016 [4], the AgNPs application, using as reductor agent Azadirachta indica were used to evaluate the immune modular effect in infected mirgal with Aeromona hydrophila. Further works on antimicrobial activity of Leucas aspera-engineered silver nanoparticles against A. hydrophilainfections were done in catla. In-vivo analysis of biochemical parameters and histological architecture provided evidence for the antibacterial effect of silver nanoparticles in catla. Moreover, broth of Aloe leaf extract was used for green synthesis of Zinc Oxide Nanoparticles (ZnO-NPs), which showed higher bactericidal activity against A.hydrophilla. Leaf bud extractfrom mangrove Rhizophora mucronata for biological synthesis of Ag-NPs, then demonstrated antimicrobial effects against Pseudomonas fluorescens, Proteus species and Flavobacterium species. The brief discussion on the recent researches on the green nanoparticle applications in fish antibacterial activity described aboveis given in the table below [5]. This green approach in the fish medication of nanoparticles is shown to be a perfect therapy in future if researches have taken seriously in aquaculture industry (Table 1).

Conclusion
Current research in biosynthesis of nanometals using plant extracts has opened a new era in fast and nontoxic methods for production of nanoparticles. Different methods (physical, chemical and biological) have beendeveloped to obtain NPs of various shapes and sizes. Among that this biological method of NPs is economically and environmentallyfriendly alternative to chemical and physical approaches. But the exact mechanism of synthesis of biogenic nanoparticles needs to be worked out.Based upon the above discussions it can be said that the synthesis of green nanoparticles may serve as a future direction in fish biomedical nanotechnology in developing antimicrobial compounds that are still to be explored.