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Melanoidin İçeren Atık Suların Renginin Mikroorganizmalarla Giderilmesi

Microbial Decolorization Of Melanoidin-Containing Wastewaters

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Abstract (2. Language): 
Melanoidin pigment is a complex biopolymer that gives the dark brown color to waste waters from alcohol distillers and from yeast production plants. The color is generated through maillard reactions between the amino and carbonyl groups of the organic materials. Since these colored substances are persistent chemicals, they are hardly decolorized. In this review, the properties of melanoidin and its decolorization by various microorganisms and chemical substances are summarized.
Abstract (Original Language): 
Melanoidin pigmenti alkol damıtma ve maya üretim fabrikalarından çıkan atıklara koyu kahverengi renk veren biyopolimer kompleksidir. Organik maddelerde amino ve karbonil grupları arasında oluşan maillard reaksiyonları sonucunda meydana gelir. Bu renkli maddeler zor parçalanır ve verdikleri rengin giderimi zordur. Bu çalışmada melanoidinin özellikleri, çeşitli mikroorganizmalar ve kimyasal maddelerle suya verdiği rengin giderilmesine yönelik çalışmalar özetlenmiştir.
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REFERENCES

References: 

Agarwal, C.S.ve Pandey, G.S. 1994. Soil pollution by spent wash discharge: depletion of manganese
(ıı) and impairment of its oxidation. Journal of Environmental Biology, 15: 49-53.
Ames, J.M., Defaye, A.B., Bailey, R.G. ve Bates, I. 1998. Analysis of the non-volatile Maillard
reaction products in an extrusion-cooked model food system. Food Chem, 61: 521-524.
Asada, K., Takahashi, M. 1987. Production and scavenging of acive oxygen in photosynthesis. In:
Kyle, DJ, Osmund CB, Arntzen CJ, editors, Photoinhibition. Amsterdam. Elsevier Science
Publications, 27-228.
Benzing,P.L., Ripmeester, J.A. ve Preston, C.M. 1983. Elucidation of the nitrogen forms in
melanoidins and humic acids by N15 cross polarization- magic angle spinning nuclear
magnetic resonance spectroscopy. J.Agric. Food. Chem. 31: 913-915.
Cammerer , B., Jalyschkov, V. ve Kroh, L. W. 2002. Carbohydrate structures as part of the
melanoidin skeleton. Int. Congr. Ser, 1245: 269-273.
Chandra,R., Bharagava, R.N ve Rai, V. 2008. Melanoidins as major colourant in sugarcane molasses
based distillery effluent and its degradation. Bioresource Technology. 99: 4648-4660.
Chaturvedi, S., Chandra, R. ve Rai, V. 2006. İsolation and characterization of Phragmittes australis(L.)
rhizosphere bacteria from contaminated site for bioremediation of colored distillery effluent.
Ecological Engineering, 27: 202-207.
Dahiya, J., Singh, D. ve Nigam, P. 2001. Decolorization of synthetic and spentwash melanoidins
using the white-rot fungus Phanerochaete chrysosporium JAG-40. Bioresource
Technology,78:95-98.
Hayase, F., Kim, S.B. ve Kato, H. 1984. Decolorization and degradation products of the melanoidin
by hydrogen peroxide. Agric. Biol. Chem, 48: 2711-2717.
Hayase, F., Kim, S.B. ve Kato, H. 1986. Analysis of the chemical structures of melanoidins by 13
CNMR, 13 C and 15 N CP-MAS NMR spectrometry. Agric. Biol. Chem, 50: 1951-1957.
Hedges, J.I. 1978. The formation and clay mineral reactions of melanoidins. Geochim.
Cosmochim.Acta 42: 69-76.
Ikan, R., Dorsey, T. ve Kaplan, I.R. 1990. Characterization of natural and synthetic humic substances
(melanoidins) by stable carbon and nitrogen isotope measurements and elemental
compositions. Anal. Chim. Acta, 232: 11-18.
Ikan, R., Ioselis, P., Rubinsztain, Y., Aizenshtat, Z., Miloslavsky, I., Yariv, S., Pugmire, R.,
Anderson, L.L., Woolfenden, W.R., Kaplan, I.R., Dorsey, T., Peters, K.E., Boon, J.J., Leeuw,
J.W.D., Ishiwatari, R., Morinaga, S., Yamamoto, S., Macihara, T., Vonmoos, M.M., ve Rub,
A. 1992. Chemical, isotopic, spectroscopic and geological aspects of natural and synthetic
humic substances. Sci. Total Environ, 117/118: 1-12.
Jones, A. D., Tier, C.M. ve Wilkins, J.P.G . 1998. Analysis of the Maillard reaction products of Betalactolglobulin
and lactose in skimmed milk powder by capillary electrophoresis and
electrospray mass spectrometry. J. Chromatogr.A, 822:147-154.
Kalavathi,D.F., Uma,L.ve Subramanian.G. 2001. Degradation and metabolization of pigmentmelanoidin
in distillery effluent by the marine cyanobacterium Oscillatoria boryana BDU
92181. Enzyme and Microbial Technology , 29: 246-251.
Kim, S.B., Hayase, F. ve Kato, H. 1985. Decolorization and degradation products of melanoidins on
ozonolysis. Agric. Biol. Chem. 49: 785-792.
Kumar, V., Wati,L., Nigam, P., Banat, I.M., Macmullan, G., Singh, D. ve Marchant, R. 1997.
Microbial decolorization and bioremediation of anaerobically digested molasses spent wash
effluent by aerobic bacterial culture. Microbios, 89: 81-89.
Kumar,P., Chandra,R. 2006; Decolorization and detoxification of synthetic molasses melanoidins by
individual and mixed cultures of Bacillus spp. Bioresource Technology, 97 (16):2096-2102.
Larter, S.R., Douglas, A.G. 1980. Melanoidins-kerogen precursors and geocheical lipid sink: Astudy
using pyrolysis gas chromatography (PGC). Geochim. Cosmochim.Acta, 44: 2087-2095.
94
Metcalf., Eddy Inc. 2004. Wastewater Engineering Treatment Disposal and Reuse, 4th ed.
( International Edition), McGraw-Hill, New York, NY10020, USA, 545-1026.
Migo, V.P., Del Rosario, E.J.ve Matsumura, M. 1997. Flocculation of melanoidins induced by
inorganic ions. J.Ferment.Bioeng, 83(3): 550-555.
Miranda, P.M., Benito, G.G., Cristobal, N.S.ve Nieto, C.H. 1996. Colour elimination from molasses
wastewater by Aspergillus niger. Biores. Technol, 57: 229-235.
Miyata,N., Mori, T., Iwahori, K. ve Fujita, M. 2000. Microbial decolorization of melanoidin
containing wastewaters: Combined use of activated sludge and the fungus Coriolus hirsutus.
J.Biosci. Bioeng, 89: 145-150.
Mohana , S., Desai, C. ve Madamwar, D. 2007. Biodegradation and decolorization of anaerobically
treated distillery spent wash by a novel bacterial consortium. Biores.Technol, 98: 333-339.
Nakajima-Kame,T., Shimomura, M., Nomra, N., Chanpornpong, T. ve Nakahava, T. 1999.
Decolorization of molasses wastewater by Bacillus sp. Under thermphilic and anaerobic
conditions. Journal of Bioscience and Bioengineering , 87:119-121.
Ohmomo, S., Itoh, N., Wantanabe, Y., Kaneko, Y., Tozawa, Y. ve Udea, K. 1985 b. Continuous
decolorization of molasses wastewater with mycelia of Coriolus versicolor Ps4a. Agric. Biol.
Chem, 49: 2047-2053.
Ohmomo ,S., Daengsubha, W., Yoshikawa, H., Yui, M., Nozaki, K., Nakajima, T. ve Nakamura, I.
1988a. Screening of anaerobic bacteria with the ability to decolorize molasses melanoidin.
Agricultural and Biological Chemistry, 52: 2437-2441.
Ohmomo, S., Yoshikawa, H., Nozaki, K., Nakajima, A., Daengsubhar, W. ve Nakamura, I. 1988 b.
Continuous decolorization of molasses wastewater using immobilized Lactobacillus hilgardii
cell. Agricultural and Biological Chemistry, 52: 2437-2441.
Painter, T.J. 1998. Carbohydrate polymers in food preservation: an integrated view of the Maillard
reaction with special reference to discoveries of preserved foods in Sphagnum-dominated peat
bogs. Carbohyd.Polym, 36: 335-347.
Raghukumar , C., Rivonkar, G. 2001. Decolorization of molasses spent wash by white-rot fungus
Flavodon flavus, isolated from a marine habitat. Appl. Microbiol. Biotechnol, 55: 510-514.
Raghukumar, C., Mohandass, C., Kamat, S., Shailaja, M.S. 2004. Simultaneous detoxification and
decolorization of molasses spent wash by the immobilized white-rot fungus Flavodon flavus,
isolated from a marine habitat. Enzyme Microb. Technol. 35: 197-202.
Shen, S.C., Tseng, K. C. ve Wu, J.S.B. 2007. An analysis of Maillard reaction products in ethanolic
glucose-glycine solution. Food Chem, 102: 281-287.
Silvan, J.M., Lagemaat, J.V.D., Olano, A. ve Castillo, M.D.D. 2006. Analysis and biological
properties of amino acid derivates formed by Maillard reaction in foods. J.Pharma. Biomed.
Anal, 41: 1543-1551.
Sirianuntapiboon, S., Chairattanawan, K. 1998. Some properties of Coriolus sp.No.20 for removal of
colour substances from molasses wastewater. Thammasat International Journal of Science and
Technology, 3: 74-79.
Sirianuntapiboon,S., Shianonth, P., Somchai, P., Atthasumpunna, P. ve Hayashida, S. 1995. An
absorption mechanism fort he decolorization of melanoidin by Rhizoctonia sp.D-90.
Bioscience Biotechnology and Biochemistry, 59: 1185-1189.
Sirianuntabipoon, S., Phothilangka, P. ve Ohmomo, S. 2004. Decolorization of molasses wastewater
by a strain No.BP103 of acetogenic bacteria. Bioresource Technology, 92: 31-39.
Thakkar, A.P., Dhamankar, V.S. ve Kapadnis, B.P. 2006. Biocatalytic decolorization of molasses by
Phanerochaete chrysosporium. Biores. Technol, 97: 1377-1381.
Tondee , T., Sirianuntabipoon, S . 2008. Decolorization of molasses wastewater by Lactobacillus
plantarum No.PV71-1861. Bioresource Technology, 99: 6258-6265.

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