COMPARISON OF PARTICLE SWARM OPTIMIZATION AND RESPONSE SURFACE METHODOLOGY IN FERMENTATION MEDIA OPTIMIZATION OF FLEXIRUBIN PRODUCTION
DOI:
https://doi.org/10.11113/jt.v81.10766Keywords:
Optimization, response surface methodology, particle swarm optimization, flexirubinAbstract
At present, response surface methodology (RSM) is the most preferred method for fermentation media optimization. However, in the last two decades, artificial intelligence algorithm has become one of the most efficient methods for empirical modelling and optimization. One of the popular developed approaches is Particle Swarm Optimization (PSO), which is used in optimizing a problem. This paper focuses on comparative studies between RSM and PSO in fermentation media optimization for the production of flexirubin production using Chryseobacterium artocarpi CECT 8497T. Two methodologies were compared for in terms of their modeling, sensitivity analysis, and optimization abilities. All experiments were performed accordingly to box-behnken design (BBD), and the generated data was analyzed using RSM and PSO. The sensitivity analysis performed by both methods has given comparative results. Based on the correlation coefficient, the model developed with PSO was found to be superior to the model developed with RSM. The result shows that PSO gives a better pigmentation yield with optimal fermentation concentration.
References
Ahmad, W. A., Yusof, N. Z., Nordin, N., Zakaria, Z. A. and Rezali, M. F. 2012. Production and Characterization of Violacein by Locally Isolated Chromobacterium Violaceum Grown in Agricultural Wastes. Applied biochemistry and biotechnology. 167(5): 1220-1234.
Tuli, H. S., Chaudhary, P., Beniwal, V. and Sharma, A. K. 2015. Microbial Pigments as Natural Color Sources: Current Trends and Future Perspectives. Journal of Food Science and Technology. 52(8): 4669-4678.
Reyes, F. G. R., Valim, M. F. C. F. A. and Vercesi, A. E. 1996. Effect of Organic Synthetic Food Colours on Mitochondrial Respiration. Food Additives & Contaminants. 13(1): 5-11.
Venil, C. K., Zakaria, Z. A., & Ahmad, W. A. 2013. Bacterial Pigments and Their Applications. Process Biochemistry. 48(7): 1065-1079.
Venil, C. K., Aruldass, C. A., Dufossé, L., Zakaria, Z. A. and Ahmad, W. A. 2014. Current perspective on Bacterial Pigments: Emerging Sustainable Compounds with Coloring and Biological Properties for the Industry–An Incisive Evaluation. RSC Advances. 4(74): 39523-39529.
Pal, M. P., Vaidya, B. K., Desai, K. M., Joshi, R. M., Nene, S. N. and Kulkarni, B. D. 2009. Media Optimization for Biosurfactant Production by Rhodococcus Erythropolis MTCC 2794: Artificial Intelligence Versus a Statistical Approach. Journal of Industrial Microbiology & Biotechnology. 36(5): 747-756.
Wang, S. L., Yang, C. H., Liang, T. W. and Yen, Y. H. 2008. Optimization of Conditions for Protease Production by Chryseobacterium Taeanense TKU001. Bioresource Technology. 99(9): 3700-3707.
Abdel-Fattah, Y. R., Saeed, H. M., Gohar, Y. M. and El-Baz, M. A. 2005. Improved Production of Pseudomonas Aeruginosa Uricase by Optimization of Process Parameters through Statistical Experimental Designs. Process Biochemistry. 40(5): 1707-1714.
Eberhart, R. C., Shi, Y. and Kennedy, J. 2001. Swarm intelligence. Elsevier.
Kennedy J. and Eberhart R. 1995. Particle Swarm Optimization. Proceedings of the IEEE International Conference on Neural Networks. 1942-1945.
Du K. L. and Swamy M. N. S. 2016. Particle Swarm Optimization. Search and Optimization by Metaheuristics. Springer International Publishing. 153-173.
Jamali, S., Alizadeh, F. and Sadeqi, S. 2016. Task Scheduling in Cloud Computing Using Particle Swarm Optimization. The Book of Extended Abstracts. 192.
Prathibha, S., Latha, B. and Suamthi, G. 2017. Particle Swarm Optimization based Workflow Scheduling for Medical Applications in Cloud. Biomedical Research. 1-1.
Ryalat, M. H., Emmens, D., Hulse, M., Bell, D., Al-Rahamneh, Z., Laycock, S. and Fisher, M. 2016. Evaluation of Particle Swarm Optimisation for Medical Image Segmentation. International Conference on Systems Science. Springer International Publishing. 61-72.
Jothi, N. 2016, December. Prediction of Generalized Anxiety Disorder Using Particle Swarm Optimization. Advances in Information and Communication Technology: Proceedings of the International Conference, ICTA 2016. Springer. 538: 480.
Salehi, M. and Goorkani, M. M. 2017. Optimum Allocation of Iranian Oil and Gas Resources Using Multi-objective Linear Programming and Particle Swarm Optimization in Resistive Economy Conditions. Journal of Industrial and Systems Engineering. 10(4): 0-0.
Siavashi, M. and Doranehgard, M. H. 2017. Particle Swarm Optimization of Thermal Enhanced Oil Recovery from Oilfields with Temperature Control. Applied Thermal Engineering. 123: 658-669.
Soesanti, I. and Syahputra, R. 2016. Batik Production Process Optimization Using Particle Swarm Optimization Method. Journal of Theoretical and Applied Information Technology. 86(2): 272.
J. Liu, X. Guan, D. Zhu and J. Sun, 2008. Optimization of the Enzymatic Pretreatment in Oat Bran Protein Extraction by Particle Swarm Optimization Algorithms for Response Surface Modeling. LWT-Food Sci. Technol. 41: 1913-1918.
Hu, X., Shi, Y. and Eberhart, R. 2004. Recent Advances in Particle Swarm. IEE Congress on Evolutionary Computation. CEC2004. (1): 90-97.
Venil, C. K., Nordin, N., Zakaria, Z. A. and Ahmad, W. A. 2014. Chryseobacterium Artocarpi sp. nov., Isolated from the Rhizosphere Soil of Artocarpus Integer. International Journal of Systematic and Evolutionary Microbiology. 64(9): 3153-3159.
Ashlock, D. 2006. Evolutionary Computation for Modeling and Optimization. Springer Science & Business Media.
Angeline, P. J. 1998. March. Evolutionary Optimization versus Particle Swarm Optimization: Philosophy and Performance Differences. International Conference on Evolutionary Programming. Springer Berlin Heidelberg. 601-610.
Chauhan, M., Chauhan, R. S. and Garlapati, V. K. 2013. Modelling and Optimization Studies on a Novel Lipase Production by Staphylococcus Arlettae through Submerged Fermentation. Enzyme Research. 2013.
Beheshti, Z., Shamsuddin, S. M. H. and Hasan, S. 2013. MPSO: Median-oriented Particle Swarm Optimization. Applied Mathematics and Computation. 219(11): 5817-5836.
Hassan, R., Cohanim, B., De Weck, O. and Venter, G. 2005, April. A Comparison of Particle Swarm Optimization and the Genetic Algorithm. Proceedings of the 1st AIAA Multidisciplinary Design Optimization Specialist Conference. 18-21.
Holland, J. H. 1992. Adaptation in Natural and Artificial Systems: An Introductory Analysis with Applications to Biology, Control, and Artificial Intelligence. MIT Press.
Shi, Y. and Eberhart, R. C. 1998. March. Parameter Selection in Particle Swarm Optimization. International Conference on Evolutionary Programming. Springer Berlin Heidelberg. 591-600.
Beheshti, Z. and Shamsuddin, S. M. 2015. Non-parametric Particle Swarm Optimization for Global Optimization. Applied Soft Computing. 28: 345-359.
G. Box, W. Hunter and J. Hunter. 1958. Statistics for Experiments. New York: Wiley.
Beheshti, Z. and Shamsuddin, S. M. H. 2013. A Review of Population-based Meta-Heuristic Algorithms. Int. J. Adv. Soft Comput. Appl. 5(1): 1-35.
Nemati, K., Shamsuddin, S. M. and Darus, M. 2015. Solving Initial and Boundary Value Problems Using Learning Automata Particle Swarm Optimization. Engineering Optimization. 47(5): 656-673.
Rini, D. P., Shamsuddin, S. M. and Yuhaniz, S. S. 2011. Particle Swarm Optimization: Technique, System and Challenges. International Journal of Computer Applications. 14(1): 19-26.
Qasem, S. N., Shamsuddin, S. M., Hashim, S. Z. M., Darus, M., & Al-Shammari, E. T. 2014. Corrigendum to Memetic Multiobjective Particle Swarm Optimization-based Radial Basis Function Network for Classification Problems. Inform. Sci. 239(2013): 165-190, 279, 914.
Pathak, L., Singh, V., Niwas, R., Osama, K., Khan, S., Haque, S. and Mishra, B. N. 2005 Artificial Intelligence versus Statistical Modeling and Optimization of Cholesterol Oxidase Production by using Streptomyces Sp. PloS One. 10(9): e0137268.
Yang C. H, Cheng, K. C and Liu W-H. 2003 Optimization of Medium Composition for Production of Extracellular Amylase by Thermobifida Fusca Using a Response Surface Methodology. Food Sci Agric Chem. 5: 35-40.
Wang, J., Lu D., Zhao, H., Ling, X., Jiang, B. and Ouyang, P. 2009. Application of Response Surface Methodology Optimization for the Production of Caffeic Acid from Tobacco Waste. Afr J Biotechnol. 8: 1416-1424.
Baş D., and Boyac,ı İH. 2007. Modeling and Optimization I: Usability of Response Surface Methodology. Journal of Food Engineering. 78: 836-845.
Kim, M-J., Lim, J., Seo, J-H. and Jung, H-K. 2011 Hybrid Optimization Strategy Using Response Surface Methodology and Genetic Algorithm for Reducing Cogging Torque of SPM. Journal of Electrical Engineering & Technology. 6: 202-207.
Suhaimi, S. N., Hasan, S. and Mariyam, S. 2018. Statistical and Nature-inspired Metaheuristics Analysis on Flexirubin Production. Int. J. Advance Soft Compu. Appl. 10(2).
Downloads
Published
Issue
Section
License
Copyright of articles that appear in Jurnal Teknologi belongs exclusively to Penerbit Universiti Teknologi Malaysia (Penerbit UTM Press). This copyright covers the rights to reproduce the article, including reprints, electronic reproductions, or any other reproductions of similar nature.