Abstract
Flocculating agents are used as auxiliary to recover bacterial cells in downstream processes for polyhydroxyalkanoate production. However little is known about the Curpiavidus necator flocs. In this work a new procedure for floc characterization through digital image analysis is presented and validated using the batch settling test. Average diameter, particle size distribution and morphological characteristics of the microbial aggregates were obtained from the flocculation/sedimentation process of the Cupriavidus necator DSM 545 cells by the use of tannin as flocculating agent. The experimental results demonstrated that the proposed method is adequate to determine the average floc diameter with values around 150 μm in accordance with the value obtained from the batch settling test. Nevertheless a morphological characterization of Cupriavidus necator DSM 545 bioaggregates in terms of size distribution and regularity could only be performed by an image analysis procedure. The procedure allowed us to describe the regularity of bacterial flocs through the quantification of morphological parameters of Euclidean [convexity (Conv) and form factor (FF)] and fractal geometry [surface fractal dimension (D BS)], which are important factors to be considered in the settling efficiency of aggregates.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Amaral AL, Ferreira EC (2005) Activated sludge monitoring of a wastewater treatment plant using image analysis and partial least squares regression. Anal Chim Acta 544:246–253
Andreadakis AD (1993) Physical and chemical properties of activated sludge floc. Water Res 27:1707–1714
Aon MA, Cortassa S (1994) On fractal nature of cytoplasm. FEBS Lett 3344:1–4
Barbusinski K, Koscielniak H (1995) Influence of substrate loading intensity on floc size in activated sludge process. Water Res 29:1703–1710
Bellouti M, Alves MM, Novais JM, Mota M (1997) Flocs vs granules: differentiation by fractal dimension. Water Res 5:1227–1231
Chainong V, Lartiges BS, Samrani AE, Mustin C (2002) Evolution of size distribution and transfer of mineral particles between flocs in activated sludges: an insight into floc exchange dynamics. Water Res 36:676–684
Da Motta M, Pons MN, Roche N, Vivier H (2001) Characterization of activated sludge by automated image analysis. Biochem Eng J 9:165–173
Finkler L, Luna CL, Pinto JC, Alves TLM (2004) Concentração de células de Ralstonia eutropha DSM 545. Anais do XXXI Encontro sobre escoamento em meios porosos (ENEMP). Uberlândia, Brazil
Glasbey CA, Horgan GW (1995) Image analysis for the biological sciences. John Willey & Sons, Chichester. ISBN 0471937266
Grispeerdt K, Verstraete W (1996) A sensor for a secondary clarifier based on image analysis. Water Sci Technol 33:61–70
Jenkins D, Richard MG, Daigger GT (1993) Manual on the causes and control of activated sludge bulking and foaming, 2nd edn. Lewis Publisher, Michigan. ISBN 0873718739
Jenné R, Banadda EN, Philips N, Van Impe JF (2003) Image analysis as a monitoring tool for activated sludge properties in lab-scale installations. J Environ Sci Health 38:2009–2018
Jenné R, Banadda EN, Gins G, Deurinck J, Smets IY, Geeraerd AH, Van Impe JF (2006) Use of image analysis for sludge characterisation: studying the relation between floc shape and sludge settleability. Water Sci Technol 54:167–174
Jones CL, Lonergan GT, Mainwaring DE (1993) Mycelial fragment size distribution: an analysis based on fractal geometry. Appl Microbiol Biotechnol 39:242–249
Jorand F, Zartarian F, Thomas F, Bottero JY, Villemin G, Urbain V, Manem J (1995) Chemical and structural (2D) linkage between bacteria within activated sludge flocs. Water Res 29:1639–1647
Kynch GJ (1952) A theory of sedimentation. Trans Faraday Soc 48:166–176
Li DH, Ganczarczyk JJ (1987) Stroboscopic determination of settling velocity, size and porosity of activated sludge flocs. Water Res 21: 257–262
Li DH, Ganczarczyk JJ (1988) Flow through activated sludge flocs. Water Res 22:789–792.
Li DH, Ganczarczyk JJ (1991) Size distribution of activated sludge flocs. Res J Water Pollut Control Feder 63:806–814
Li DH, Ganczarczyk JJ (1989) Fractal geometry of particles aggregates generated in water and wastewater treatment process. Environ Sci Technol 23:1385–1389
Liebovitch LS, Toth T (1989) A fast algorithm to determine fractal dimensions by box counting. Phys Lett 141:386–390
Luna CL, Lopes CE, Massarani G (2003) Recovery of Bacillus sphaericus 2362 spores from growth medium by flocculation/sedimentation. Bioprocess Biosyst Eng 25:213–216
Mandelbrot B.B (1983) The Fractal Geometry of Nature W. H. Freeman and Company, New York
Námer J, Ganczarczyk JJ (1993) Settling properties of digested sludge particle aggregates. Water Res 27:1285–1294
Obert M, Pfeifer P, Sernets M (1990) Microbial Growth Patterns Described by Fractal Geometry. J Bacteriol 172: 1180–1185
Özacar M, Sengil IA (2000) Effectiveness of tannins obtained from Valonia as a coagulant aid for dewatering of sludge. Water Res 34:1407–1412
Özacar M, Sengil IA (2003) Effect of tannins on phosphate removal using alum. J Eng Environ Sci 27:227–236
Puget FP, Halasz MRT, Massarani G, Alves TLM (2000) Influence of the flocculating agent in sedimentation and performance of a non flocculent strain of Zymomonas mobilis in the ethanol production process. Bioseparation 9:119–124
Rosin L (2001) Unimodal thresholding. Pattern Recognit 34:2083–2096
Ryu HW, Cho KS, Chang YK, Chang HN (1996) Cell separation from high cell density broths of Alcaligenes eutrophus by using a coagulant. Biotechnol Tech 10:899–904
Ryu HW, Cho KS, Lee EG, Chang YK (2000) Recovery of poly(3-hydroxybutyrate) from coagulated Ralstonia eutropha using a chemical digestion method. Biotechnol Prog 16:676–679
Sadalgekar VV, Mahajan BA, Shalegram AM (1988) Evaluation of sludge settleability by floc characteristics. J Water Pollut Control Feder 60:1862–1863
Salehizadeh H, Shojaosadati SA (2001) Extracellular biopolymeric flocculants. Recent trends and biotechnological importance. Biotechnol Adv 19:371–385
StatSoft, Inc. (2001) STATISTICA (data analysis software system), version 6. www.statsoft.com
Vandame P, Coenye T (2004) Taxonomy of the genus Cupriavidus: a tale of lost and found. Int J Syst Evol Microbiol 54:2285–2289
Wilén BM, Balmér P (1999) The effect of dissolved oxygen concentration on the structure, size, and size distribution of activated sludge flocs. Water Res 33:391–400
Wilén BM, Jin B, Lant P (2003) Impacts of structural characteristics on activated sludge floc stability. Water Res 37:3632–3645
Zahid WM, Ganczarczyk JJ (1994) A technique for characterization of RBC film surface. Water Res 28:2229–2231
Zucher WV (1983) Tannins: does structure determine function? An ecological perspective. Am Nat 121:335–365
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Finkler, L., Ginoris, Y.P., Luna, C.L. et al. Morphological characterization of Cupriavidus necator DSM 545 flocs through image analysis. World J Microbiol Biotechnol 23, 801–808 (2007). https://doi.org/10.1007/s11274-006-9300-8
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s11274-006-9300-8