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http://dx.doi.org/10.12989/mwt.2015.6.3.225

Effect of growth phase of cyanobacterium on release of intracellular geosmin from cells during microfiltration process  

Matsushita, Taku (Division of Environmental Engineering, Hokkaido University)
Nakamura, Keisuke (Division of Environmental Engineering, Hokkaido University)
Matsui, Yoshihiko (Division of Environmental Engineering, Hokkaido University)
Shirasaki, Nobutaka (Division of Environmental Engineering, Hokkaido University)
Publication Information
Membrane and Water Treatment / v.6, no.3, 2015 , pp. 225-235 More about this Journal
Abstract
During low-pressure membrane treatments of cyanobacterial cells, including microfiltration (MF) and ultrafiltration (UF), there have reportedly been releases of intracellular compounds including cyanotoxins and compounds with an earthy-musty odor into the water, probably owing to cyanobacterial cell breakage retained on the membrane. However, to our knowledge, no information was reported regarding the effect of growth phase of cyanobacterial cells on the release of the intracellular compounds. In the present study, we used a geosmin-producing cyanobacterium, Anabaena smithii, to investigate the effect of the growth phase of the cyanobacterium on the release of intracellular geosmin during laboratory-scale MF experiments with the cells in either the logarithmic growth or stationary phase. Separate detection of damaged and intact cells revealed that the extent of cell breakage on the MF membrane was almost the same for logarithmic growth and stationary phase cells. However, whereas the geosmin concentration in the MF permeate increased after 3 h of filtration with cells in the logarithmic growth phase, it did not increase during filtration with cells in the stationary phase: the trend in the geosmin concentration in the MF permeate with time was much different between the logarithmic growth and stationary phases. Adsorption of geosmin to algogenic organic matter (AOM) retained on the MF membrane and/or pore blocking with the AOM were greater when the cells were in the stationary phase versus the logarithmic growth phase, the result being a decrease in the apparent release of intracellular geosmin from the stationary phase cells. In actual drinking water treatment plants employing membrane processes, more attention should be paid to the cyanobacterial cells in logarithmic growth phase than in stationary phase from a viewpoint of preventing the leakage of intracellular earthy-musty odor compounds to finished water.
Keywords
algogenic organic matters; Anabaena; earthy-musty odor; logarithmic growth phase; stationary phase;
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1 Ando, A., Miwa, M., Kajino, M. and Tatsumi, S. (1995), "Removal of musty-odorous compounds in water and retained in algal cells through water purification process", Water Sci. Technol., 25(2), 299-306.
2 Campinas, M. and Rosa, M.J. (2010), "Evaluation of cyanobacterial cells removal and lysis by ultrafiltration", Separ. Purif. Technol., 70(3), 345-353.   DOI
3 Chow, C.W.K., Panglisch, S., House, J., Drikas, M., Burch, M.D. and Gimbel, R. (1997), "A study of membrane filtration for the removal of cyanobacterial cells", J. Water Suppl.: Res. Technol. - AQUA, 46(6), 324-334.
4 Chow, C.W.K., Drikas, M., House, J., Burch, M.D. and Velzeboer, R.M.A. (1999), "The impact of conventional water treatment processes on cells of the cyanobacterium Microcystis aeruginosa", Water Res., 33(15), 3253-3262.   DOI
5 Daly, R.I., Ho, L. and Brookes, J.D. (2007), "Effect of chlorination on Microcystis aeruginosa cell integrity and subsequent microcystin release and degradation", Environ. Sci. Technol., 41(12), 4447-4453.   DOI
6 Dixon, M.B., Richard, Y., Ho, L., Chow, C.W.K., O'Neill, B.K. and Newcombe, G. (2011), "A coagulation-powdered activated carbon-ultrafiltration - multiple barrier approach for removing toxins from two Australian cyanobacterial blooms", J. Hazard. Mater., 186(2-3), 1553-1559.   DOI
7 Gijsbertsen-Abrahamse, A.J., Schmidt, W., Chorus, I. and Heijman, S.G.J. (2006), "Removal of cyanotoxins by ultrafiltration and nanofiltration", J. Membr. Sci., 276(1-2), 252-259.   DOI   ScienceOn
8 Hawkins, P.R., Putt, E., Falconer, I. and Humpage, A. (2001), "Phenotypical variation in a toxic strain of the phytoplankter, cylindrospermopsis raciborskii (nostocales, cyanophyceae) during batch culture", Environ. Toxicol., 16(6), 460-467.   DOI
9 Henderson, R., Parsons, S.A. and Jefferson, B. (2008), "The impact of algal properties and pre-oxidation on solid-liquid separation of algae", Water Res., 42(8-9), 1827-1845.   DOI
10 Huang, W.-J., Lai, C.-H. and Cheng, Y.-L. (2007), "Evaluation of extracellular products and mutagenicity in cyanobacteria cultures separated from a eutrophic reservoir", Sci. Total Environ., 377(2-3), 214-223.   DOI
11 ISO (1992), ISO 10260, water quality - measurement of biochemical parameters - spectrometric determination of the chlorophyll-a concentration; ISO, Geneva, Switzerland.
12 Matsushita, T., Kobayashi, Y., Nakamura, K., Matsui, Y. and Ohno, K. (2010), "Effect of transmembrane pressure on geosmin release from cyanobacterial cell during microfiltration", Water Practice Technol., 5(3), DOI: 10.2166/wpt.2010.049
13 Lalezary, S., Pirbazari, M. and McGuire, M.J. (1986), "Oxidation of five earthy-musty taste and odor compounds", J. Am. Water Works Assoc., 78(3), 62-69.
14 Lam, A.K.Y., Prepas, E.E., Spink, D. and Hrudey, S.E. (1995), "Chemical control of hepatotoxic phytoplankton blooms: Implications for human health", Water Res., 29(8), 1845-1854.   DOI
15 Li, L., Gao, N., Deng, Y., Yao, J. and Zhang, K. (2012), "Characterization of intracellular & extracellular algae organic matters (AOM) of Microcystis aeruginosa and formation of AOM-associated disinfection byproducts and odor & taste compounds", Water Res., 46(4), 1233-1240.   DOI
16 Naes, H. and Post, A. (1988), "Transient states of geosmin, pigments, carbohydrates and proteins in continuous cultures of Oscillatoria brevis induced by changes in nitrogen supply", Arch. Microbiol., 150(4), 333-337.   DOI
17 Peterson, H.G., Hrudey, S.E., Cantin, I.A., Perley, T.R. and Kenefick, S.L. (1995), "Physiological toxicity, cell membrane damage and the release of dissolved organic carbon and geosmin by Aphanizomenon flos-aquae after exposure to water treatment chemicals", Water Res., 29(6), 1515-1523.   DOI
18 Pietsch, J., Bornmann, K. and Schmidt, W. (2002), "Relevance of intra- and extracellular cyanotoxins for drinking water treatment", Acta Hydroch. et Hydrobiol., 30(1), 7-15.   DOI
19 Pivokonsky, M., Kloucek, O. and Pivokonska, L. (2006), "Evaluation of the production, composition and aluminum and iron complexation of algogenic organic matter", Water Res., 40(16), 3045-3052.   DOI
20 Qu, F., Liang, H., He, J., Ma, J., Wang, Z., Yu, H. and Li, G. (2012), "Characterization of dissolved extracellular organic matter (DEOM) and bound extracellular organic matter (BEOM) of Microcystis aeruginosa and their impacts on UF membrane fouling", Water Res., 46(9), 2881-2890.   DOI
21 Saadoun, I.M.K., Schrader, K.K. and Blevins, W.T. (2001), "Environmental and nutritional factors affecting geosmin synthesis by Anabaena SP.", Water Research, 35(5), 1209-1218.   DOI
22 Saker, M.L., Neilan, B.A. and Griffiths, D.J. (1999), "Two morphological forms of Cylindrospermopsis raciborskii (cyanobacteria) isolated from Solomon dam, Palm island, Queensland", J. Phycol., 35(3), 599-606.   DOI
23 Sano, D., Ishifuji, S., Sato, Y., Imae, Y., Takaara, T., Masago, Y. and Omura, T. (2011), "Identification and characterization of coagulation inhibitor proteins derived from cyanobacterium Microcystis aeruginosa", Chemosphere, 82(8), 1096-1102.   DOI
24 Sato, M., Murata, Y., Mizusawa, M., Iwahashi, H. and Oka, S. (2004), "A simple and rapid dual-fluorescence viability assay for microalgae", Microbiol. Culture Collect., 20(2), 53-59.
25 Sorlini, S., Gialdini, F. and Collivignarelli, C. (2013), "Removal of cyanobacterial cells and microcystin-LR from drinking water using a hollow fiber microfiltration pilot plant", Desalination, 309, 106-112.   DOI
26 Srinivasan, R. and Sorial, G.A. (2011), "Treatment of taste and odor causing compounds 2-methyl isoborneol and geosmin in drinking water: A critical review", J. Environ. Sci., 23(1), 1-13.   DOI
27 Sun, F., Pei, H.-Y., Hu, W.-R. and Ma, C.-X. (2012), "The lysis of Microcystis aeruginosa in $AlCl_3$ coagulation and sedimentation processes", Chem. Eng. J., 193-194, 196-202.   DOI
28 Widrig, D.L., Gray, K.A. and McAuliffe, K.S. (1996), "Removal of algal-derived organic material by preozonation and coagulation: Monitoring changes in organic quality by pyrolysis-GC-MS", Water Res., 30(11), 2621-2632.   DOI
29 Waer, M.A. (2006), "Removal of musty-odorous compounds in water and retained in algal cells through water purification process", Opflow, 32(6), 3-6.
30 Watanabe, M.M. and Ichimura, T. (1977), "Fresh- and salt-water forms of Spirulina platensis in axenic cultures", The Bulletin of Japanese Society of Phycology, 25(suppl.), pp. 371-377.
31 Zamyadi, A., Ho, L., Newcombe, G., Bustamante, H. and Prevost, M. (2012) "Fate of toxic cyanobacterial cells and disinfection by-products formation after chlorination", Water Res., 46(5), 1524-1535.   DOI
32 Zhang, X., Fan, L. and Roddick, F.A. (2013), "Influence of the characteristics of soluble algal organic matter released from Microcystis aeruginosa on the fouling of a ceramic microfiltration membrane", J. Membr. Sci., 425-426, 23-29.   DOI