New insights into MagPI: a promising tool to determine the adhesive capacity of biofilm on the mesoscale

Sabine Ulrike Gerbersdorf; Silke Wieprecht; Moritz Thom; David M. Paterson; Marc Scheffler

doi:10.1080/08927014.2018.1476971

New insights into MagPI: a promising tool to determine the adhesive capacity of biofilm on the mesoscale

Sabine Ulrike Gerbersdorf, Silke Wieprecht, Moritz Thom, David M. Paterson, Marc Scheffler

Research output: Contribution to journal › Article › peer-review

Abstract

The adhesiveness and stability of ubiquitously distributed biofilms is a significant issue in many areas such as ecology, biotechnology and medicine. The magnetic particle induction (MagPI) system allows precise determinations of biofilm adhesiveness at high temporal and spatial resolution on the mesoscale. This paper concerns several technical aspects to further improve the performance of this powerful experimental approach and enhance the range of MagPI applications. First, several electromagnets were built to demonstrate the influence of material and geometry with special regard to core remanence and magnetic strength. Secondly, the driving force to lift up the particles was evaluated and it was shown that both the magnetic field strength and the magnetic field gradient are decisive in the physics of the MagPI approach. The intricate combination of these two quantities was demonstrated with separate experiments that add permanent magnets to the MagPI system.

Original language	English
Number of pages	12
Journal	Biofouling
Volume	Latest Articles
Early online date	27 Aug 2018
DOIs	https://doi.org/10.1080/08927014.2018.1476971
Publication status	E-pub ahead of print - 27 Aug 2018

Keywords

Biofilm
Adhesion
Stability
MagPI
Electromagnet

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10.1080/08927014.2018.1476971

BLUE-coast: Physical and biological dynamic coastal processes and their role in coastal recovery (BLUE-coast)
Paterson, D. (PI)
NERC
1/05/16 → 31/01/21
Project: Standard

Cite this

@article{6dad888170704e788f8e1c9a6d5a425a,

title = "New insights into MagPI: a promising tool to determine the adhesive capacity of biofilm on the mesoscale",

abstract = "The adhesiveness and stability of ubiquitously distributed biofilms is a significant issue in many areas such as ecology, biotechnology and medicine. The magnetic particle induction (MagPI) system allows precise determinations of biofilm adhesiveness at high temporal and spatial resolution on the mesoscale. This paper concerns several technical aspects to further improve the performance of this powerful experimental approach and enhance the range of MagPI applications. First, several electromagnets were built to demonstrate the influence of material and geometry with special regard to core remanence and magnetic strength. Secondly, the driving force to lift up the particles was evaluated and it was shown that both the magnetic field strength and the magnetic field gradient are decisive in the physics of the MagPI approach. The intricate combination of these two quantities was demonstrated with separate experiments that add permanent magnets to the MagPI system.",

keywords = "Biofilm, Adhesion, Stability, MagPI, Electromagnet",

author = "Gerbersdorf, {Sabine Ulrike} and Silke Wieprecht and Moritz Thom and Paterson, {David M.} and Marc Scheffler",

note = "Sabine U. Gerbersdorf and M. Thom received funding from the DFG (Deutsche Forschungsgemeinschaft) project {\textquoteleft}Ecosystem Engineering: Sediment entrainment and flocculation mediated by microbial produced extracellular polymeric substances (EPS){\textquoteright}, GE 1932/3–1 and GE 1932/3–2. David M. Paterson was partly supported via NERC Grant Ref: NE/N016009/1.",

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doi = "10.1080/08927014.2018.1476971",

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AU - Gerbersdorf, Sabine Ulrike

AU - Wieprecht, Silke

AU - Thom, Moritz

AU - Paterson, David M.

AU - Scheffler, Marc

N1 - Sabine U. Gerbersdorf and M. Thom received funding from the DFG (Deutsche Forschungsgemeinschaft) project ‘Ecosystem Engineering: Sediment entrainment and flocculation mediated by microbial produced extracellular polymeric substances (EPS)’, GE 1932/3–1 and GE 1932/3–2. David M. Paterson was partly supported via NERC Grant Ref: NE/N016009/1.

PY - 2018/8/27

Y1 - 2018/8/27

N2 - The adhesiveness and stability of ubiquitously distributed biofilms is a significant issue in many areas such as ecology, biotechnology and medicine. The magnetic particle induction (MagPI) system allows precise determinations of biofilm adhesiveness at high temporal and spatial resolution on the mesoscale. This paper concerns several technical aspects to further improve the performance of this powerful experimental approach and enhance the range of MagPI applications. First, several electromagnets were built to demonstrate the influence of material and geometry with special regard to core remanence and magnetic strength. Secondly, the driving force to lift up the particles was evaluated and it was shown that both the magnetic field strength and the magnetic field gradient are decisive in the physics of the MagPI approach. The intricate combination of these two quantities was demonstrated with separate experiments that add permanent magnets to the MagPI system.

AB - The adhesiveness and stability of ubiquitously distributed biofilms is a significant issue in many areas such as ecology, biotechnology and medicine. The magnetic particle induction (MagPI) system allows precise determinations of biofilm adhesiveness at high temporal and spatial resolution on the mesoscale. This paper concerns several technical aspects to further improve the performance of this powerful experimental approach and enhance the range of MagPI applications. First, several electromagnets were built to demonstrate the influence of material and geometry with special regard to core remanence and magnetic strength. Secondly, the driving force to lift up the particles was evaluated and it was shown that both the magnetic field strength and the magnetic field gradient are decisive in the physics of the MagPI approach. The intricate combination of these two quantities was demonstrated with separate experiments that add permanent magnets to the MagPI system.

KW - Biofilm

KW - Adhesion

KW - Stability

KW - MagPI

KW - Electromagnet

U2 - 10.1080/08927014.2018.1476971

DO - 10.1080/08927014.2018.1476971

M3 - Article

SN - 0892-7014

VL - Latest Articles

JO - Biofouling

JF - Biofouling

ER -

New insights into MagPI: a promising tool to determine the adhesive capacity of biofilm on the mesoscale

Abstract

Keywords

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Projects

BLUE-coast: Physical and biological dynamic coastal processes and their role in coastal recovery (BLUE-coast)

Cite this