An ESPResSo implementation of elastic objects immersed in a fluid I Cimrák, M Gusenbauer, I Jančigová Computer Physics Communications 185 (3), 900-907, 2014 | 79 | 2014 |
Computational blood cell mechanics: road towards models and biomedical applications I Cimrak, I Jancigova CRC Press, 2018 | 25 | 2018 |
Applications of machine learning for simulations of red blood cells in microfluidic devices H Bachratý, K Bachratá, M Chovanec, I Jančigová, M Smiešková, ... BMC bioinformatics 21, 1-15, 2020 | 19 | 2020 |
Simulation study of rare cell trajectories and capture rate in periodic obstacle arrays M Bušík, I Jančigová, R Tóthová, I Cimrák Journal of Computational Science 17, 370-376, 2016 | 19 | 2016 |
Calibration of elastic coefficients for spring-network model of red blood cell R Tóthová, I Jančigová, M Bušík 2015 International Conference on Information and Digital Technologies, 376-380, 2015 | 19 | 2015 |
Scalability of forces in mesh-based models of elastic objects I Jančigová, R Tóthová 2014 ELEKTRO, 562-566, 2014 | 19 | 2014 |
PyOIF: Computational tool for modelling of multi-cell flows in complex geometries I Jančigová, K Kovalčíková, R Weeber, I Cimrák PLOS Computational Biology 16 (10), e1008249, 2020 | 18 | 2020 |
Spring‐network model of red blood cell: From membrane mechanics to validation I Jančigová, K Kovalčíková, A Bohiniková, I Cimrák International Journal for Numerical Methods in Fluids 92 (10), 1368-1393, 2020 | 16 | 2020 |
Cell damage index as computational indicator for blood cell activation and damage M Gusenbauer, R Tóthová, G Mazza, M Brandl, T Schrefl, I Jančigová, ... Artificial Organs 42 (7), 746-755, 2018 | 16 | 2018 |
On elasticity of spring network models used in blood flow simulations in espresso∗ I Cimrák, I Jancigová, K Bachiratá, H Bachratý PARTICLES III: proceedings of the III International Conference on Particle …, 2013 | 11 | 2013 |
Non‐uniform force allocation for area preservation in spring network models I Jančigová, I Cimrák International journal for numerical methods in biomedical engineering 32 (10 …, 2016 | 10 | 2016 |
Energy contributions of different elastic moduli in mesh-based modeling of deformable objects R Tóthová, I Jančigová, I Cimrák 2014 ELEKTRO, 634-638, 2014 | 9 | 2014 |
Modeling Elastic Objects in Fluid Flow with Biomedical Applications. I Jančigová Information Sciences & Technologies: Bulletin of the ACM Slovakia 8 (1), 2016 | 7 | 2016 |
Object-in-fluid framework in modeling of blood flow in microfluidic channels I Cimrak, K Bachrata, H Bachraty, I Jancigova, R Tothova, M Busik, ... Communications-Scientific Letters of the University of Zilina 18 (1A), 13-20, 2016 | 7 | 2016 |
Sensing platform for computational and experimental analysis of blood cell mechanical stress and activation in microfluidics M Gusenbauer, G Mazza, M Brandl, T Schrefl, R Tóthová, I Jančigová, ... Procedia Engineering 168, 1390-1393, 2016 | 7 | 2016 |
A novel approach with non-uniform force allocation for area preservation in spring network models I Jančigová, I Cimrák AIP Conference Proceedings 1648 (1), 2015 | 6 | 2015 |
Recent advances in mesh-based modeling of individual cells in biological fluids I Cimrák, I Jančigová, R Tóthová The 10th International Conference on Digital Technologies 2014, 25-31, 2014 | 6 | 2014 |
Mesh-based modeling of individual cells and their dynamics in biological fluids I Cimrák, I Jančigová, R Tóthová, M Gusenbauer Applications of Computational Intelligence in Biomedical Technology, 1-28, 2016 | 5 | 2016 |
Modeling red blood cell viscosity contrast using inner soft particle suspension A Bohiniková, I Jančigová, I Cimrák Micromachines 12 (8), 974, 2021 | 4 | 2021 |
Computational modeling of blood flow with rare cell in a microbifurcation I Jančigová Computer Methods, Imaging and Visualization in Biomechanics and Biomedical …, 2020 | 3 | 2020 |