Quantitative measurement and visualization of biofilm O2 consumption rates in membrane filtration systems

There is a strong need for techniques enabling direct assessment of biological activity of biofouling in membrane filtration systems. Here we present a new quantitative and non-destructive method for mapping O2 dynamics in biofilms during biofouling studies in membrane fouling simulators (MFS). Tran...

Full description

Saved in:
Bibliographic Details
Main Authors: Prest, E. I., Staal, M., van Loosdrecht, M. C. M., Vrouwenvelder, J. S., Kühl, Michael.
Format: Article
Language:English
Published: 2013
Online Access:https://hdl.handle.net/10356/99582
http://hdl.handle.net/10220/13645
Tags: Add Tag
No Tags, Be the first to tag this record!
Institution: Nanyang Technological University
Language: English
id sg-ntu-dr.10356-99582
record_format dspace
spelling sg-ntu-dr.10356-995822020-03-07T12:47:10Z Quantitative measurement and visualization of biofilm O2 consumption rates in membrane filtration systems Prest, E. I. Staal, M. van Loosdrecht, M. C. M. Vrouwenvelder, J. S. Kühl, Michael. There is a strong need for techniques enabling direct assessment of biological activity of biofouling in membrane filtration systems. Here we present a new quantitative and non-destructive method for mapping O2 dynamics in biofilms during biofouling studies in membrane fouling simulators (MFS). Transparent planar O2 optodes in combination with a luminescence lifetime imaging system were used to map the two-dimensional distribution of O2 concentrations and consumption rates inside the MFS. The O2 distribution was indicative for biofilm development. Biofilm activity was characterized by imaging of O2 consumption rates, where low and high activity areas could be clearly distinguished. The spatial development of O2 consumption rates, flow channels and stagnant areas could be determined. This can be used for studies on concentration polarization, i.e. salt accumulation at the membrane surface resulting in increased salt passage and reduced water flux. The new optode-based O2 imaging technique applied to MFS allows non-destructive and spatially resolved quantitative biological activity measurements (BAM) for on-site biofouling diagnosis and laboratory studies. The following set of complementary tools is now available to study development and control of biofouling in membrane systems: (i) MFS, (ii) sensitive pressure drop measurement, (iii) magnetic resonance imaging, (iv) numerical modelling, and (v) biological activity measurement based on O2 imaging methodology. 2013-09-24T06:54:30Z 2019-12-06T20:09:14Z 2013-09-24T06:54:30Z 2019-12-06T20:09:14Z 2011 2011 Journal Article Prest, E., Staal, M., Kühl, M., van Loosdrecht, M.,& Vrouwenvelder, J. (2012). Quantitative measurement and visualization of biofilm O2 consumption rates in membrane filtration systems. Journal of Membrane Science, 392-39366-75. https://hdl.handle.net/10356/99582 http://hdl.handle.net/10220/13645 10.1016/j.memsci.2011.12.003 en Journal of membrane science
institution Nanyang Technological University
building NTU Library
country Singapore
collection DR-NTU
language English
description There is a strong need for techniques enabling direct assessment of biological activity of biofouling in membrane filtration systems. Here we present a new quantitative and non-destructive method for mapping O2 dynamics in biofilms during biofouling studies in membrane fouling simulators (MFS). Transparent planar O2 optodes in combination with a luminescence lifetime imaging system were used to map the two-dimensional distribution of O2 concentrations and consumption rates inside the MFS. The O2 distribution was indicative for biofilm development. Biofilm activity was characterized by imaging of O2 consumption rates, where low and high activity areas could be clearly distinguished. The spatial development of O2 consumption rates, flow channels and stagnant areas could be determined. This can be used for studies on concentration polarization, i.e. salt accumulation at the membrane surface resulting in increased salt passage and reduced water flux. The new optode-based O2 imaging technique applied to MFS allows non-destructive and spatially resolved quantitative biological activity measurements (BAM) for on-site biofouling diagnosis and laboratory studies. The following set of complementary tools is now available to study development and control of biofouling in membrane systems: (i) MFS, (ii) sensitive pressure drop measurement, (iii) magnetic resonance imaging, (iv) numerical modelling, and (v) biological activity measurement based on O2 imaging methodology.
format Article
author Prest, E. I.
Staal, M.
van Loosdrecht, M. C. M.
Vrouwenvelder, J. S.
Kühl, Michael.
spellingShingle Prest, E. I.
Staal, M.
van Loosdrecht, M. C. M.
Vrouwenvelder, J. S.
Kühl, Michael.
Quantitative measurement and visualization of biofilm O2 consumption rates in membrane filtration systems
author_facet Prest, E. I.
Staal, M.
van Loosdrecht, M. C. M.
Vrouwenvelder, J. S.
Kühl, Michael.
author_sort Prest, E. I.
title Quantitative measurement and visualization of biofilm O2 consumption rates in membrane filtration systems
title_short Quantitative measurement and visualization of biofilm O2 consumption rates in membrane filtration systems
title_full Quantitative measurement and visualization of biofilm O2 consumption rates in membrane filtration systems
title_fullStr Quantitative measurement and visualization of biofilm O2 consumption rates in membrane filtration systems
title_full_unstemmed Quantitative measurement and visualization of biofilm O2 consumption rates in membrane filtration systems
title_sort quantitative measurement and visualization of biofilm o2 consumption rates in membrane filtration systems
publishDate 2013
url https://hdl.handle.net/10356/99582
http://hdl.handle.net/10220/13645
_version_ 1681042649525518336