Michal Přibyl
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Fields of interest:
- Microfluidics
- Electrokinetic Phenomena
- Applied Immunoassay
- Reaction Engineering and Bioengineering
Recent publications:
Schrott, W., M. Pribyl, J. Stepanek, and D. Snita:
Electro-osmotic Characteristics of Polystyrene Microchips – Experiments and Modeling,
Microelectronic Engineering, Vol. 85(5-6), (2008), pp. 1100-1103.
Postler, T., Z. Slouka, M. Svoboda, M. Pribyl, and D. Snita:
Parametrical studies of electroosmotic transport characteristics in submicrometer channels,
Journal of Colloid and Interface Science, Vol. 320(1), (2008), pp. 321-332.
Slouka, Z., M. Pribyl, D. Snita, and T. Postler:
Transient behavior of an electrolytic diode,
Physical Chemistry Chemical Physics, Vol. 9(39), (2007), pp. 5374-5381.
Stepanek, J., M. Pribyl, D. Snita, and M. Marek:
Microfluidic chip for fast bioassays - evaluation of binding parameters,
Biomicrofluidics, Vol. 1(2), (2007), p. 024101.
Slouka, Z., M. Pribyl, J. Lindner, D. Šnita, and M. Marek :
Dynamical and stationary analysis of an electrolyte diode and comparison with experiments,
Computer-Aided Chemical Engineering, Vol. 21(A), (2006), pp. 291-296.
Pribyl, M., D. Snita, and M. Kubicek:
Adaptive mesh simulations of ionic systems in microcapillaries based on the estimation of transport times,
Computers & Chemical Engineering, Vol. 30(4), (2006), pp. 674-685.
Pribyl, M., V. Knapkova, D. Snita, and M. Marek:
Modeling reaction-transport processes in a microcapillary biosensor for detection of human IgG,
Microelectronic Engineering, Vol. 83(4-9), (2006), pp. 1660-1663.
Pribyl, M., V. Knapkova, D. Snita, and M. Marek:
Analysis of reaction-transport phenomena in a microfluidic system for the detection of IgG,
Chemical Papers-Chemicke Zvesti, Vol. 59(6A), (2005), pp. 434-440.
Pribyl, M., D. Snita, and M. Marek:
Nonlinear phenomena and qualitative evaluation of risk of clogging in a capillary microreactor under, imposed electric field,
Chemical Engineering Journal, Vol. 105(3), (2005), pp. 99-109.
Pribyl, M., D. Snita, P. Hasal, and M. Marek:
Modeling of electric-field driven transport processes in microdevices for immunoassay,
Chemical Engineering Journal, Vol. 101(1-3), (2004), pp. 303-314.
