Abstract
Copper and nickel adsorption onto calcium alginate, sodium alginate with an extracellular polysaccharide (EPS) produced by the activated sludge bacterium Chryseomonas luteola TEM05 and the immobilized C. luteola TEM05 from aqueous solutions were studied. After that, the multi metal ions containing these ions together were prepared and partial competitive adsorptions of these mixtures were also investigated. The metal adsorption of gel beads were carried out at pH 6.0, 25 °C. The maximum adsorption capacities in Langmuir isotherm for calcium alginate, calcium alginate + EPS, calcium alginate + C. luteola TEM05 and calcium alginate + EPS + C. luteola TEM05 were 1.505, 1.989, 1.976, 1.937 mmol/g dry weight for Cu(II) and 0.996, 1.224, 1.078, 1.219 mol/g dry weight for Ni(II), respectively.
The competitive biosorption capacities of the carrier for all metal ions were lower than single conditions.
Article PDF
Similar content being viewed by others
Avoid common mistakes on your manuscript.
References
M.Y. Arica C. Arpa A. Ergene G. Bayramoglu O. Genc (2003) ArticleTitleCa-alginate as a support for Pb(II) and Zn(II) biosorption with immobilized Phanerochaete chrysosporium Carbohydrate Polymers 52 167–174
A. Blanco B. Sanz M.J. Llama J.L. Serra (1999) ArticleTitleBiosorption of heavy metals to immobilised Phormidium laminosum biomass Journal of Biotechnology 69 227–240
Bolling, D.W. & Edelstein, S.J. 1991 Protein Methods. New York, pp. 50–55.
R.H. Christ J.R. Martin D. Carr J.R. Watson H.J. Clarke (1994) ArticleTitleInteraction of metals and protons with algae. 4. Ion-exchange vs adsorption models and a reassessment of scatchard plots–ion–exchange rates and equilibria compared with calcium alginate Environmental Science and Technology 28 1859–1866
M. Dubois A.K. Gilles J.K. Hamilton P.A. Rebers F. Smith (1956) ArticleTitleColorometric method for determination of sugars and related substances Analytical Chemistry 28 350–356
C.R. Ferguson M.R. Peterson T.H. Jeffers (1989) Removal of metal contaminants from waste waters using biomass immobilized in polysulfone beads B.J. Scheiner F.M. Doyle S.K. Kawatras (Eds) Biotechnology in Minerals and Metal Processing Society of Mining Engineers Littleton, CO 193–199
E. Fourest B. Volesky (1997) ArticleTitleAlginate properties and heavy metal biosorption by marine algae Applied Biochemistry and Biotechnology 67 215–226
D.L. Gutnick H. Bach (2000) ArticleTitleEngineering bacterial biopolymers for the biosorption of heavy metals; new products and novel formulations Applied Microbiology and Biotechnology 54 451–460
A. Hugerth N. Caram-Lelham L.O. Sundelof (1997) ArticleTitleThe effect of charge density and conformation on the polyelectrolyte complex formation between carageenan and chitosan Carbohydrate Polymers 34 149–156
W. Jianlong N. Horan E. Stentiford Q. Yi (2000) ArticleTitleThe radial distribution and bioactivity of Pseudomonas sp immobilized in calcium alginate gel beads Process Biochemistry 35 465–469
D. Kratochvil B. Volesky (1998) ArticleTitleAdvances in biosorption of heavy metals Trends In Biotechnology 16 291–300
N. Lazaro A.L. Sevilla S. Morales A.M. Marques (2003) ArticleTitleHeavy metal biosorption by gellan gum gel beads Water Research 37 2118–2126
M. Nourbakhsh Y. Sag D. Ozer Z. Aksu T. Kutsal A. Caglar (1994) ArticleTitleA Comparative study of various biosorbents for removal of chromium(VI) ions from industrial waste waters Process Biochemistry 29 1–5
G. Ozdemir S.H. Baysal (2004) ArticleTitleChromium and aluminum biosorption on Chryseomonas luteola TEM05 Applied Microbiology and Biotechnology 64 599–603
G. Ozdemir T. Ozturk N. Ceyhan R. Isler T. Cosar (2003) ArticleTitleHeavy metal biosorption by biomass ofOchrobactrum anthropi producing exopolysaccharide in activated sludge Bioresource Technology 90 71–74
Y. Sag M. Nourbakhsh Z. Aksu T. Kutsal (1995) ArticleTitleComparasion of Ca-alginate and immobilized Z. ramigera as sorbents for copper(II) removal Process Biochemistry 30 175–181
N. Saglam R. Say A. Denizli S. Patir M.Y. Arica (1999) ArticleTitleBiosorption of inorganic mercury and alkylmercury species on to by Phanerochaete chrysosporium mycellium Process Biochemistry 34 725–730
R. Say A. Denizli M.Y. Arica (2001) ArticleTitleBiosorption of cadmium(II), lead(II) and Copper(II) with the filamentous fungus P. Chrysosporium Bioresource Technology 76 67–70
Y. Tago K. Aida (1977) ArticleTitleExocellular mucopolysaccharide closely related to bacteria floc formation Applied and Environmental Microbiolology 34 308–314
M. Tsezos R.G.L. McCready J.P. Bell (1989) ArticleTitleThe continuous recovery of uranium from biologically leached solutions using immobilized biomass Biotechnology and Bioengineering 34 10–17
F. Veglio A. Esposito A.P. Reverberi (2002) ArticleTitleCopper adsorption on calcium alginate beads: equilibrium pH-related models Hydrometallurgy 65 43–57
B. Volesky (2001) ArticleTitleDetoxification of metal-bearing effluents; biosorption for the next century Hydrometallurgy 59 203–216
G. Yan T. Viraraghavan (2001) ArticleTitleHeavy metal removal in a biosorption column by immobilized M. rouxii biomass Bioresource Technology 78 243–249
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Ozdemir, G., Ceyhan, N. & Manav, E. Utilization in alginate beads for Cu(II) and Ni(II) adsorption of an exopolysaccharide produced by Chryseomonas luteola TEM05. World J Microbiol Biotechnol 21, 163–167 (2005). https://doi.org/10.1007/s11274-004-1563-3
Received:
Issue Date:
DOI: https://doi.org/10.1007/s11274-004-1563-3