“Scientific Research and Innovation in Nigeria”

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Presentation transcript:

“Scientific Research and Innovation in Nigeria” Characterization of Bioflocculant Produced by Streptomyces sp. Ap4 Presented By Gboyega E. Adebami @ Faculty of Science 2nd International Conference, University of Ibadan Titled “Scientific Research and Innovation in Nigeria” (16th – 20th March, 2015). Venue – Faculty of Science Auditorium, University of Ibadan, Ibadan, Nigeria Characterization of Bioflocculant Produced by Streptomyces sp. Ap4 by ADEBAMI Gboyega E. is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

Introduction Flocculation refers to the process by which destabilized particles conglomerate into larger aggregates so that they can be separated from the wastewater (Droste, 1997). In general, flocculants are classified into three groups: inorganic flocculants, such as aluminum sulfate and polyaluminum chloride; organic synthetic flocculants, such as polyacrylamide derivatives and polyethylene amine; and naturally occurring flocculants (Lee et al., 2014)

Introduction cont’d A bioflocculant on the other hand, is a kind of biodegradable polymeric flocculants produced by many microorganisms during their growth (Gao et al., 2006; Defang et al., 2008; Mabinya et al., 2012) Compared with conventional synthetic organic flocculants, bioflocculant have special advantages such as safety for ecosystems, potential flocculating effects, biodegradability and harmlessness to humans and the environment, and as a consequence may potentially be applied in drinking and wastewater treatment, downstream processing, food, pharmaceutical and fermentation processing (Salehizadeh and Shojaosadati, 2001; Ntsaluba et al., 2013; Ozcan and Oner, 2015

Methodology Culture Preparation 16SrDNA Sequence Determination and Phylogenetic Analysis of the Bioflocculant-Producing A. aquatilis AP4 Bioflocculant Production by A. aquatilis AP4 Determination of Flocculating Activity Effects of Carbon Source on Bioflocculant Production by A. aquatilis AP4 Effects of pH, Incubation Temperature and Static/ Agitation on Bioflocculant Production by A. aquatilis AP4 Characterization of the Bioflocculant Produced by A. aquatilis AP4 Statistical Analysis

Results and Discussions Fig. 1. Molecular Phylogenetic analysis by Maximum Likelihood method of the isolate

Fig. 2. Effect of different carbon source (wastewater) on bioflocculant production by A. aquatilis AP4 Fig. 3. Effect of pH on bioflocculant production by A. aquatilis AP4

Fig. 4. Effect of incubation temperature on bioflocculant production by A. aquatilis AP4 Fig. 5. Effect of static/agitation on bioflocculant production by A. aquatilis AP4

Fig. 6. Effect of speed (rpm) on bioflocculant production Fig. 7. FT-IR spectroscopy performed on purified bioflocculant produced by the isolate

Conclusion In conclusion, cultural conditions such as carbon source, pH, incubation temperature and agitation have significant effect on the bioflocculant production. Glucose, 30°C, pH 9.0, agitation and shaking speed of 140 rpm were the best for maximum production of bioflocculant by the isolate. The bioflocculant is a glycoprotein consisting of hydroxyl, amide and carboxyl as its functional groups. Isolate AP4 is a good agent with high flocculating activity (89.58%), it therefore has the potential to be used on a large scale for bioflocculant production, which could serve as a possible substitute for non-biodegradable, carcinogenic and harmful chemical flocculants which is often used in the treatment of water today. Further studies on the biotechnological application of the bioflocculant and the genes responsible for flocculation are in progress.

Selected References Droste RL. Theory and practice of water and wastewater treatment. John Wiley and Sons, New York. 1997;384-415. Lee S, John R, Mei F, Chong C. A review on application of flocculants in wastewater treatment. Proc Safety Environl Protec. 2014;92:489–508. Gao J, Bao HY, Xin MX, Liu YX, Li Q, Zhang YF. Characterization of a bioflocculant from a newly isolated Vagococcus sp. W31. J Zhejiang Univ Sci B. 2006;7:186–192. Defang Z, Juanjuan W, John FK. Application of a chitosan flocculant to water treatment. Carbohydr Polym. 2008; 71:135–139. Mabinya LV, Cosa S, Nwodo U, Okoh AI. Studies on bioflocculant production by Arthrobacter sp. Raats, freshwater bacteria isolated from Tyume River. South Africa. Int J Molecul Sci. 2012;13:1054–1065. Seo H. Bioflocculant production from Bacillus sp. A56. Sanop Misaengmul Hakhoechi. 1993;21:486-493. Zhang T, Lin Z, Zhu HL. Microbial flocculant and its application in environmental protection. J Environ Sci China. 1999;11:1-12. Salehizadeh H, Shojaosadati SA. Extracellular biopolymeric flocculants: recent trends and biotechnological importance. Biotechnol Adv. 2001;19:371-385. Ntsaluba L, Nwodo UU, Mabinya LV, Okoh AI. Studies on bioflocculant production by a mixed culture of ethylobacterium sp. Obi and Actinobacterium sp. Mayor. BMC Biotechnol. 2013;3:1–7. Ozcan E, Oner ET. Microbial production of extracellular polysaccharides from biomass sources. Springer International Publishing Switzerland. Springer International Publishing Switzerland, Polysaccharides. 2015;161-184. Characterization of Bioflocculant Produced by Streptomyces sp. Ap4 by ADEBAMI Gboyega E. is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.