Effects of temperature and pH on the biokinetic properties of thiocyanate biodegradation under autotrophic conditions

Water Research

Volumn 47, Issue 1, 2013, Pages 251-258

  Kim, Jaai ^a   Cho, Kyung Jin ^b   Han, Gyuseong ^b   Lee, Changsoo ^a   Hwang, Seokhwan ^b  

^a Ulsan National Institute of Science and Technology   (South Korea)

^b Pohang University of Science and Technology (POSTECH)   (South Korea)

Author keywords

Biokinetic modeling; PH; Response surface analysis; Temperature; Thiocyanate biodegradation

Indexed keywords

BIODEGRADATION; DEGRADATION; GROWTH RATE; PH EFFECTS; SURFACE ANALYSIS;

AUTOTROPHICS; BIOKINETIC MODELS; BIOKINETICS; EFFECT OF PH; EFFECTS OF TEMPERATURE; PH; PROPERTY; RESPONSE SURFACE ANALYSIS; RESPONSE SURFACE MODELLING; THIOCYANATE BIODEGRADATION;

TEMPERATURE;

THIOCYANATE;

AUTOTROPHY; BIOACTIVITY; BIODEGRADATION; CONCENTRATION (COMPOSITION); GROWTH RATE; NUMERICAL MODEL; ORGANIC POLLUTANT; ORGANIC SULFUR COMPOUND; PH; REACTION KINETICS; REACTION RATE; SUBSTRATE; TEMPERATURE EFFECT;

ACTIVATED SLUDGE; ARTICLE; AUTOTROPHY; BIODEGRADATION; BIOKINETICS; CONTROLLED STUDY; CORRELATION COEFFICIENT; CULTURAL ANTHROPOLOGY; GROWTH RATE; INHIBITION KINETICS; PH; PRIORITY JOURNAL; RESPONSE SURFACE METHOD; SIMULATION; STATISTICAL ANALYSIS; TEMPERATURE DEPENDENCE; WASTE COMPONENT REMOVAL; WASTE WATER MANAGEMENT; WATER POLLUTANT;

EID: 84870066171     PISSN: 00431354     EISSN: 18792448     Source Type: Journal    
DOI: 10.1016/j.watres.2012.10.003     Document Type: Article

References (25)

1. Ahn J.-H., Kim J., Lim J., Hwang S. Biokinetic evaluation and modeling of continuous thiocyanate biodegradation by Klebsiella sp. Biotechnology Progress 2004, 20:1069-1075.
2. Bezsudnova E.Y., Sorokin D.Y., Tikhonova T.V., Popov V.O. Thiocyanate hydrolase, the primary enzyme initiating thiocyanate degradation in the novel obligately chemolithoautotrophic halophilic sulfur-oxidizing bacterium Thiohalophilus thiocyanoxidans. Biochimica et Biophysica Acta (BBA) - Proteins & Proteomics 2007, 1774:1563-1570.
3. Button D.K. Nutrient-limited microbial growth kinetics: overview and recent advances. Antonie van Leeuwenhoek 1993, 63:225-235.
4. Ebbs S. Biological degradation of cyanide compounds. Current Opinion in Biotechnology 2004, 15:231-236.
5. Felföldi T., Székely A.J., Gorál R., Barkács K., Scheirich G., András J., Rácz A., Márialigeti K. Polyphasic bacterial community analysis of an aerobic activated sludge removing phenols and thiocyanate from coke plant effluent. Bioresource Technology 2010, 101:3406-3414.
6. Hung C.-H., Pavlostathis S.G. Aerobic biodegradation of thiocyanate. Water Research 1997, 31:2761-2770.
7. Hung C.-H., Pavlostathis S.G. Kinetics and modeling of autotrophic thiocyanate biodegradation. Biotechnology and Bioengineering 1999, 62:1-11.
8. Kim S.-J., Katayama Y. Effect of growth conditions on thiocyanate degradation and emission of carbonyl sulfide by Thiobacillus thioparus THI115. Water Research 2000, 34:2887-2894.
9. Laidler K.J. The development of the Arrhenius equation. Journal of Chemical Education 1984, 61:494-498.
10. Lay-Son M., Drakides C. New approach to optimize operational conditions for the biological treatment of a high-strength thiocyanate and ammonium waste: pH as key factor. Water Research 2008, 42:774-780.
11. Lee C., Kim J., Chang J., Hwang S. Isolation and identification of thiocyanate utilizing chemolithotrophs from gold mine soils. Biodegradation 2003, 14:183-188.
12. Lee C., Kim J., Hwang K., Hwang S. Fermentation and growth kinetic study of Aeromonas caviae under anaerobic conditions. Applied Microbiology and Biotechnology 2009, 83:767-773.
13. Lee C., Lee S., Cho K.-J., Hwang S. Mycelial cultivation of Phellinus linteus using cheese-processing waste and optimization of bioconversion conditions. Biodegradation 2011, 22:103-110.
14. Lewis R.J. Sax's Dangerous Properties of Industrial Materials 1992, Van Nostrand Reinhold Co., New York.
15. Madigan M.T., Martinko J.M., Dunlap P.V., Clack D.P. Brock Biology of Microorganisms 2009, Pearson Education, Inc., San Francisco, CA.
16. Montgomery D.C. Design and Analysis of Experiments 1997, John Wiley and Sons, Inc, New York, NY. fourth ed.
17. Murthy M.S.R.C., Swaminathan T., Rakshit S.K., Kosugi Y. Statistical optimization of lipase catalyzed hydrolysis of methyloleate by response surface methodology. Bioprocess Engineering 2000, 22:35-39.
18. Nedwell D.B. Effect of low temperature on microbial growth: lowered affinity for substrates limits growth at low temperature. FEMS Microbiology Ecology 1999, 30:101-111.
19. Olson G.J., Brierley J.A., Brierley C.L. Bioleaching review part B. Applied Microbiology and Biotechnology 2003, 63:249-257.
20. Rosso L., Lobry J., Bajard S., Flandrois J. Convenient model to describe the combined effects of temperature and pH on microbial growth. Applied and Environmental Microbiology 1995, 61:610-616.
21. Shuler M.L., Kargi F. Bioprocess Engineering: Basic Concepts 2002, Prentice Hall PTR, Upper Saddle River.
22. Tan Y., Wang Z.-X., Marshall K.C. Modeling pH effects on microbial growth: a statistical thermodynamic approach. Biotechnology and Bioengineering 1998, 59:724-731.
23. Vazquez I., Rodriguez J., Maranon E., Castrill L., Fernandez Y. Simultaneous removal of phenol, ammonium and thiocyanate from coke wastewater by aerobic biodegradation. Journal of Hazardous Materials 2006, 137:1773-1780.
24. Westermann P., Ahring B.K., Mah R.A. Temperature compensation in Methanosarcina barkeri by modulation of hydrogen and acetate affinity. Applied and Environmental Microbiology 1989, 55:1262-1266.
25. Wood P.A., Kelly P.D., McDonald R.I., Jordan L.S., Morgan D.T., Khan S., Murrell J.C., Borodina E. A novel pink-pigmented facultative methylotroph, Methylobacterium thiocyanatum sp. nov., capable of growth of thiocyanate or cyanate as sole nitrogen sources. Archives of Microbiology 1998, 169:148-158.