Analysis of Fluid Flow and Wall Shear Stress Patterns Inside Partially Filled Agitated Culture Well Plates

The appearance of highly resistant bacterial biofilms in both community and hospitals environments is a major challenge in modern clinical medicine. The biofilm structural morphology, believed to be an important factor affecting the behavioral properties of these “super bugs”, is strongly influenced...

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Bibliographic Details
Published in:Annals of biomedical engineering 2012-03, Vol.40 (3), p.707-728
Main Authors: Salek, M. Mehdi, Sattari, Pooria, Martinuzzi, Robert J.
Format: Article
Language:English
Subjects:
Bacteria
Biochemistry
Biofilms
Biofilms - growth & development
Biological and Medical Physics
Biomedical and Life Sciences
Biomedical Engineering
Biomedical Engineering and Bioengineering
Biomedicine
Biophysics
Cell Culture Techniques - instrumentation
Cell Culture Techniques - methods
Classical Mechanics
Computational fluid dynamics
Culture
Endothelial Cells - cytology
Endothelial Cells - physiology
Flow characteristics
Flow pattern
Fluid dynamics
Fluid flow
Fluids
Free surfaces
Humans
Hydrodynamics
Mathematical models
Methicillin-Resistant Staphylococcus aureus - physiology
Models, Biological
Plates
Rotation
Shear Strength
Shear stress
Stress, Mechanical
Topology
Wall shear stresses
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Summary:The appearance of highly resistant bacterial biofilms in both community and hospitals environments is a major challenge in modern clinical medicine. The biofilm structural morphology, believed to be an important factor affecting the behavioral properties of these “super bugs”, is strongly influenced by the local hydrodynamics over the microcolonies. Despite the common use of agitated well plates in the biology community, they have been used rather blindly without knowing the flow characteristics and influence of the rotational speed and fluid volume in these containers. The main purpose of this study is to characterize the flow in these high-throughput devices to link local hydrodynamics to observed behavior in cell cultures. In this work, the flow and wall shear stress distribution in six-well culture plates under planar orbital translation is simulated using Computational Fluid Dynamics (CFD). Free surface, flow pattern and wall shear stress for two shaker speeds (100 and 200 rpm) and two volumes of fluid (2 and 4 mL) were investigated. Measurements with a non-intrusive optical shear stress sensor and High Frame-rate Particle Imaging Velocimetry (HFPIV) are used to validate CFD predictions. An analytical model to predict the free surface shape is proposed. Results show a complex three-dimensional flow pattern, varying in both time and space. The distribution of wall shear stress in these culture plates has been related to the topology of flow. This understanding helps explain observed endothelial cell orientation and bacterial biofilm distributions observed in culture dishes. The results suggest that the mean surface stress field is insufficient to capture the underlying dynamics mitigating biological processes.
ISSN:0090-6964
1573-9686
DOI:10.1007/s10439-011-0444-9