Reaction–diffusion modelling for microphysiometry on cellular specimens

Using modeling and simulation, we quantify the influence of spatiotemporal dynamics on the accuracy of data obtained from sensors placed in microscaled reaction volumes. The model refers to cellular reaction (i.e. proton extrusion and oxygen consumption) in complex, buffering solutions. Whole cells...

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Bibliographic Details
Published in:Medical & biological engineering & computing 2013-04, Vol.51 (4), p.387-395
Main Authors: Grundl, Daniel, Zhang, Xiaorui, Messaoud, Safa, Pfister, Cornelia, Demmel, Franz, Mommer, Mario S., Wolf, Bernhard, Brischwein, Martin
Format: Article
Language:English
Subjects:
Biomedical and Life Sciences
Biomedical Engineering and Bioengineering
Biomedicine
Computer Applications
Computer Simulation
Cytological Techniques - instrumentation
Cytological Techniques - methods
Diffusion
Finite Element Analysis
Human Physiology
Hydrogen-Ion Concentration
Imaging
Kinetics
Metabolism
Models, Biological
Original Article
Oxygen - metabolism
Radiology
Reproducibility of Results
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Summary:Using modeling and simulation, we quantify the influence of spatiotemporal dynamics on the accuracy of data obtained from sensors placed in microscaled reaction volumes. The model refers to cellular reaction (i.e. proton extrusion and oxygen consumption) in complex, buffering solutions. Whole cells or viable tissues cultured in such devices are monitored in real time with integrated sensors for pH and dissolved oxygen. A 3D finite element model of diffusion and metabolic reaction was set up. With respect to pH, the effect of buffering species on proton diffusion is analysed in detail. To account for the delayed time response of real sensors, the sensor impulse response time was implemented by linear convolution. A validation of the model has been achieved by an electrochemical approach. The model reveals significant deviations of measured pH and O 2 , and values of these parameters actually occurring at different sites of the cell culture volume. It is applicable to any setting of (bio-) sensors involving reaction and diffusion of dissolved gases and particularly H + ions in buffered solutions.
ISSN:0140-0118
1741-0444
DOI:10.1007/s11517-012-1007-4