Bogdan Kaźmierczak: Difference between revisions

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<div align="center">'''Ph.D., D.Sc., IPPT Professor'''<!--Associate Professor--></div>
<div align="center">'''Ph.D., D.Sc. (habilitation), Professor'''<!--Associate Professor--></div>


===Contact===
===Contact===
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===Recent publications===
===Recent publications===


* <span class="pmbm">Białecki S</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Lipniacki T</span>. '''Polarization of concave domains by traveling wave pinning''', ''PLOS One'' <u>12</u>:e0190372 (2017) [http://www.ncbi.nlm.nih.gov/pubmed/29284045 PubMed] [http://dx.doi.org/10.1371/journal.pone.0190372 CrossRef]
* <span class="author">Kazmierczak&nbsp;B</span>, <span class="author">Sneyd&nbsp;J</span>, <span class="author">Tsai&nbsp;J-C</span>. '''Effect of buffers with multiple binding sites on calcium waves''', ''Bull&nbsp;Math&nbsp;Biol'' <u>85</u>(1):10 (2023) [https://doi.org/10.1007/s11538-022-01109-0 CrossRef]


* <span class="pmbm">Tudelska K</span>, <span class="pmbm">Markiewicz J</span>, <span class="pmbm">Kochańczyk M</span>, <span class="pmbm">Czerkies M</span>, <span class="pmbm">Prus W</span>, <span class="pmbm">Korwek Z</span>, <span class="nopmbm">Abdi A</span>, <span class="pmbm">Błoński S</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Lipniacki T</span>. '''Information processing in the NF-κB pathway''', ''Scientific&nbsp;Reports'' <u>7</u>:15926 (2017) [http://www.ncbi.nlm.nih.gov/pubmed/29162874 PubMed] [http://doi.org/10.1038/s41598-017-16166-y CrossRef] | [http://www.nature.com/articles/s41598-017-16166-y.pdf PDF] [http://pmbm.ippt.pan.pl/publications/supplementary/Tudelska-2017-SciRep-SuppInfo.pdf SuppInfo-PDF] [http://pmbm.ippt.pan.pl/publications/supplementary/Tudelska-2017-SciRep-SuppDataset1.zip SuppCode-BNGL] [http://pmbm.ippt.pan.pl/publications/supplementary/Tudelska-2017-SciRep-SuppDataset2.zip SuppCode-Py]
* <span class="author">Mahiout&nbsp;LA</span>, <span class="author">Bessonov&nbsp;N</span>, <span class="author">Kazmierczak&nbsp;B</span>,<span class="author"> Volpert&nbsp;V</span>. '''Mathematical modeling of respiratory viral infection and applications to SARS-CoV-2 progression''', ''Math&nbsp;Meth&nbsp;Appl&nbsp;Sci'' <u>46</u>(2):1740–1751 (2023) [https://doi.org/10.1002/mma.8606 CrossRef]


* <span class="pmbm">Bialecki S</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Nowicka D</span>, <span class="nopmbm">Tsai J-C</span>. '''Regularity of solutions to a reaction–diffusion equation on the sphere: the Legendre series approach''', ''Math&nbsp;Meth Appl Sci'' <u>40</u>(14):5349–5369 (2017) [http://dx.doi.org/10.1002/mma.4390 CrossRef]
* <span class="author">Mahiout&nbsp;AL</span>, <span class="author">Bessonov&nbsp;N</span>, <span class="author">Kazmierczak&nbsp;B</span>, <span class="author">Sadaka&nbsp;G</span>, <span class="author">Volpert&nbsp;V</span>. '''Infection spreading in cell culture as a reaction-diffusion wave''', ''ESAIM: Math Model Numer Anal'' 56(3):791–814 (2022) [https://doi.org/10.1051/m2an/2022019 CrossRef]


* <span class="nopmbm">Bobrowski A</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="nopmbm">Kunze M</span>. '''An averaging principle for fast diffusions in&nbsp;domains separated by semi-permeable membranes''', ''Math Model Meth Appl Sci'' <u>27</u>(4):663–706 (2017) [http://dx.doi.org/10.1142/S0218202517500130 CrossRef] [http://arxiv.org/abs/1603.00494 arXiv]
* <span class="author">Adimy&nbsp;M</span>, <span class="author">Chekroun&nbsp;A</span>, <span class="author">Kazmierczak&nbsp;B</span>. '''Traveling waves for reaction-diffusion PDE coupled to difference equation with nonlocal dispersal term and time delay''', ''Math Model Nath Phenom'' <u>17</u>:2022021 (2022) [https://doi.org/10.1051/mmnp/2022021 CrossRef]


* <span class="nopmbm">Adimy M</span>, <span class="nopmbm">Chekroun A</span>, <span class="pmbm">Kaźmierczak B</span>. '''Traveling waves in a coupled reaction–diffusion and difference model of hematopoiesis''', ''J&nbsp;Differ Equ'' <u>262</u>(7):4085–4128 (2017) [http://dx.doi.org/10.1016/j.jde.2016.12.009 CrossRef]
* <span class="author">Mahiout&nbsp;LA</span>, <span class="pmbm">Kaźmierczak&nbsp;B</span>, <span class="author">Volpert&nbsp;V</span>. '''Viral infection spreading and mutation in cell culture''', ''Mathematics'' <u>10</u>(2):256 (2022) [https://doi.org/10.3390/math10020256 CrossRef]
 
* <span class="author">Bialecki S</span>, <span class="author">Nalecz-Jawecki P</span>, <span class="author">Kazmierczak B</span>, <span class="author">Lipniacki</span>. '''Traveling and standing fronts on&nbsp;curved surfaces''', ''Physica D'' <u>401</u>:132215 (2020) [https://doi.org/10.1016/j.physd.2019.132215 CrossRef]
 
* <span class="author">Kaźmierczak&nbsp;B</span> &amp; <span class="author">Sneyd&nbsp;J</span>. '''Speed of traveling waves for monotone reaction–diffusion systems as a function of diffusion coefficients''', ''Physica D: Nonlin Phenom'' <u>424</u>:132940 (2021) [https://doi.org/10.1016/j.physd.2021.132940 CrossRef]
 
* <span class="author">Chen&nbsp;WC</span>, <span class="author">Kaźmierczak&nbsp;B</span>. '''Traveling waves in quadratic autocatalytic systems with complexing agent''', ''Discrete Contin Dyn Syst–Ser&nbsp;B'' <u>26</u>(4):1827–1842 (2021) [http://dx.doi.org/10.3934/dcdsb.2020364 CrossRef]
 
* <span class="author">Chatterjee&nbsp;P</span>, <span class="author">Glimm&nbsp;T</span>, <span class="author">Kaźmierczak&nbsp;B</span>. '''Mathematical modeling of chondrogenic pattern formation during limb development: Recent advances in continuous models''', ''Math&nbsp;Biosci'' <u>322</u>:108319 (2020) [https://pubmed.ncbi.nlm.nih.gov/32001201 PubMed] [https://doi.org/10.1016/j.mbs.2020.108319 CrossRef]
 
* <span class="author">Kazmierczak B</span>, <span class="author">Tsai J-C</span>, <span class="author">Bialecki S</span>. '''The propagation phenomenon of solutions of a&nbsp;parabolic problem on the sphere''', ''Math Model Meth Appl Sci'' <u>28</u>(10):2001–2067 (2018) [http://doi.org/10.1142/S0218202518500483 CrossRef]
 
* <span class="author">Białecki S</span>, <span class="author">Kaźmierczak B</span>, <span class="author">Lipniacki T</span>. '''Polarization of concave domains by traveling wave pinning''', ''PLOS One'' <u>12</u>:e0190372 (2017) [http://www.ncbi.nlm.nih.gov/pubmed/29284045 PubMed] [http://dx.doi.org/10.1371/journal.pone.0190372 CrossRef]
 
* <span class="pmbm">Tudelska K</span>, <span class="pmbm">Markiewicz J</span>, <span class="pmbm">Kochańczyk M</span>, <span class="pmbm">Czerkies M</span>, <span class="pmbm">Prus W</span>, <span class="pmbm">Korwek Z</span>, <span class="pmbm">Abdi A</span>, <span class="pmbm">Błoński&nbsp;S</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Lipniacki T</span>. '''Information processing in the NF-κB pathway''', ''Scientific&nbsp;Reports'' <u>7</u>:15926 (2017) [http://www.ncbi.nlm.nih.gov/pubmed/29162874 PubMed] [http://doi.org/10.1038/s41598-017-16166-y CrossRef] | [http://www.nature.com/articles/s41598-017-16166-y.pdf PDF] [http://pmbm.ippt.pan.pl/publications/supplementary/Tudelska-2017-SciRep-SuppInfo.pdf SuppInfo-PDF] [http://pmbm.ippt.pan.pl/publications/supplementary/Tudelska-2017-SciRep-SuppDataset1.zip SuppCode-BNGL] [http://pmbm.ippt.pan.pl/publications/supplementary/Tudelska-2017-SciRep-SuppDataset2.zip SuppCode-Py]
 
* <span class="pmbm">Bialecki S</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Nowicka D</span>, <span class="pmbm">Tsai J-C</span>. '''Regularity of solutions to a reaction–diffusion equation on the sphere: the Legendre series approach''', ''Math&nbsp;Meth Appl Sci'' <u>40</u>(14):5349–5369 (2017) [http://dx.doi.org/10.1002/mma.4390 CrossRef]
 
* <span class="pmbm">Bobrowski A</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Kunze M</span>. '''An averaging principle for fast diffusions in&nbsp;domains separated by semi-permeable membranes''', ''Math Model Meth Appl Sci'' <u>27</u>(4):663–706 (2017) [http://dx.doi.org/10.1142/S0218202517500130 CrossRef] [http://arxiv.org/abs/1603.00494 arXiv]
 
* <span class="pmbm">Adimy M</span>, <span class="pmbm">Chekroun A</span>, <span class="pmbm">Kaźmierczak B</span>. '''Traveling waves in a coupled reaction–diffusion and difference model of hematopoiesis''', ''J&nbsp;Differ Equ'' <u>262</u>(7):4085–4128 (2017) [http://dx.doi.org/10.1016/j.jde.2016.12.009 CrossRef]


* <span class="pmbm">Chatterjee P</span>, <span class="pmbm">Kaźmierczak B</span>. '''Eigenfunction approach to transient patterns in a&nbsp;model of chemotaxis''', ''Math Model Nat Phenom'' <u>11</u>(2):44–62 (2016) [http://dx.doi.org/10.1051/mmnp/201611204 CrossRef]
* <span class="pmbm">Chatterjee P</span>, <span class="pmbm">Kaźmierczak B</span>. '''Eigenfunction approach to transient patterns in a&nbsp;model of chemotaxis''', ''Math Model Nat Phenom'' <u>11</u>(2):44–62 (2016) [http://dx.doi.org/10.1051/mmnp/201611204 CrossRef]


* <span class="pmbm">Białecki S</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="nopmbm">Tsai J-C</span>. '''Stationary waves on the sphere''', ''SIAM J Appl Math'' <u>75</u>(4):1761–1788 (2015) [http://dx.doi.org/10.1137/140999384 CrossRef]
* <span class="pmbm">Białecki S</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Tsai J-C</span>. '''Stationary waves on the sphere''', ''SIAM J Appl Math'' <u>75</u>(4):1761–1788 (2015) [http://dx.doi.org/10.1137/140999384 CrossRef]


* <span class="pmbm">Szopa P</span>, <span class="pmbm">Dyzma M</span>, <span class="pmbm">Kaźmierczak B</span>. '''Membrane associated complexes in calcium dynamics modelling''', ''Phys&nbsp;Biol'' <u>10</u>(3):035004 (2013) [http://www.ncbi.nlm.nih.gov/pubmed/23735591 PubMed] [http://dx.doi.org/10.1088/1478-3975/10/3/035004 CrossRef]  
* <span class="pmbm">Szopa P</span>, <span class="pmbm">Dyzma M</span>, <span class="pmbm">Kaźmierczak B</span>. '''Membrane associated complexes in calcium dynamics modelling''', ''Phys&nbsp;Biol'' <u>10</u>(3):035004 (2013) [http://www.ncbi.nlm.nih.gov/pubmed/23735591 PubMed] [http://dx.doi.org/10.1088/1478-3975/10/3/035004 CrossRef]  


* <span class="nopmbm">Crooks E</span>, <span class="pmbm">Kazmierczak B</span>, <span class="pmbm">Lipniacki T</span>. '''A spatially extended model of kinase&ndash;receptor interaction''', ''SIAM&nbsp;J&nbsp;Appl Math'' <u>73</u>(1):374–400 (2013) [http://dx.doi.org/10.1137/110860926 CrossRef]
* <span class="pmbm">Crooks E</span>, <span class="pmbm">Kazmierczak B</span>, <span class="pmbm">Lipniacki T</span>. '''A spatially extended model of kinase&ndash;receptor interaction''', ''SIAM&nbsp;J&nbsp;Appl Math'' <u>73</u>(1):374–400 (2013) [http://dx.doi.org/10.1137/110860926 CrossRef]


* <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Peradzyński Z</span>. '''Calcium waves with mechano-chemical couplings''', ''Math&nbsp;Biosci Eng'' <u>10</u>(3):743-759 (2013) [http://dx.doi.org/10.3934/mbe.2013.10.743 CrossRef]
* <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Peradzyński Z</span>. '''Calcium waves with mechano-chemical couplings''', ''Math&nbsp;Biosci Eng'' <u>10</u>(3):743-759 (2013) [http://dx.doi.org/10.3934/mbe.2013.10.743 CrossRef]


* <span class="nopmbm">El Khatib N</span>, <span class="nopmbm">Genieys S</span>, <span class="pmbm">Kazmierczak B</span>, <span class="nopmbm">Volpert V</span>. '''Reaction&ndash;diffusion model of artherosclerosis development''', ''J&nbsp;Math&nbsp;Biol'' <u>65</u>(2):349-374 (2012) [http://www.ncbi.nlm.nih.gov/pubmed/21858687 PubMed] [http://dx.doi.org/10.1007/s00285-011-0461-1 CrossRef]
* <span class="pmbm">El Khatib N</span>, <span class="pmbm">Genieys S</span>, <span class="pmbm">Kazmierczak B</span>, <span class="pmbm">Volpert V</span>. '''Reaction&ndash;diffusion model of artherosclerosis development''', ''J&nbsp;Math&nbsp;Biol'' <u>65</u>(2):349-374 (2012) [http://www.ncbi.nlm.nih.gov/pubmed/21858687 PubMed] [http://dx.doi.org/10.1007/s00285-011-0461-1 CrossRef]


* <span class="nopmbm">Gejji R</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="nopmbm">Alber M</span>. '''Classification and stability of global inhomogeneous solutions of a macroscopic model of cell motion''', ''Math&nbsp;Biosci'' (2012) [http://www.ncbi.nlm.nih.gov/pubmed/22504124 PubMed] [http://dx.doi.org/10.1016/j.mbs.2012.03.009 CrossRef]
* <span class="pmbm">Gejji R</span>, <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Alber M</span>. '''Classification and stability of global inhomogeneous solutions of a macroscopic model of cell motion''', ''Math&nbsp;Biosci'' (2012) [http://www.ncbi.nlm.nih.gov/pubmed/22504124 PubMed] [http://dx.doi.org/10.1016/j.mbs.2012.03.009 CrossRef]


* <span class="pmbm">Dyzma M</span>, <span class="pmbm">Szopa P</span>, <span class="pmbm">Kaźmierczak B</span>. '''Membrane associated complexes: new approach to calcium dynamics modeling''', ''Math&nbsp;Model Nat Phenom'' <u>7</u>(2):32-50 (2012) [http://dx.doi.org/10.1051/mmnp/20127608 CrossRef]
* <span class="pmbm">Dyzma M</span>, <span class="pmbm">Szopa P</span>, <span class="pmbm">Kaźmierczak B</span>. '''Membrane associated complexes: new approach to calcium dynamics modeling''', ''Math&nbsp;Model Nat Phenom'' <u>7</u>(2):32-50 (2012) [http://dx.doi.org/10.1051/mmnp/20127608 CrossRef]
Line 52: Line 72:
* <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Lipniacki T</span>. '''Spatial gradients in kinase cascade regulation''', ''IET&nbsp;Syst&nbsp;Biol'' <u>4</u>:348-355 (2010) [http://www.ncbi.nlm.nih.gov/pubmed/21073234 PubMed] [http://dx.doi.org/10.1049/iet-syb.2010.0002 CrossRef] | [http://pmbm.ippt.pan.pl/publications/Kazmierczak-2010-IETSystBiol-MS.pdf PDF-ms]
* <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Lipniacki T</span>. '''Spatial gradients in kinase cascade regulation''', ''IET&nbsp;Syst&nbsp;Biol'' <u>4</u>:348-355 (2010) [http://www.ncbi.nlm.nih.gov/pubmed/21073234 PubMed] [http://dx.doi.org/10.1049/iet-syb.2010.0002 CrossRef] | [http://pmbm.ippt.pan.pl/publications/Kazmierczak-2010-IETSystBiol-MS.pdf PDF-ms]


* <span class="nopmbm">Alber M</span>, <span class="nopmbm">Gejji R</span>, <span class="pmbm">Kaźmierczak B</span>. '''Existence of global solutions of a macroscopic model of cellular motion in a chemotactic field''', ''Appl&nbsp;Math&nbsp;Lett'' <u>22</u>:1645-1648  (2009) [http://dx.doi.org/10.1016/j.aml.2009.05.013 CrossRef]
* <span class="pmbm">Alber M</span>, <span class="pmbm">Gejji R</span>, <span class="pmbm">Kaźmierczak B</span>. '''Existence of global solutions of a macroscopic model of cellular motion in a chemotactic field''', ''Appl&nbsp;Math&nbsp;Lett'' <u>22</u>:1645-1648  (2009) [http://dx.doi.org/10.1016/j.aml.2009.05.013 CrossRef]


* <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Lipniacki T</span>. '''Regulation of kinase activity by diffusion and feedback''', ''J&nbsp;Theor&nbsp;Biol'' <u>259</u>:291-296 (2009) [http://www.ncbi.nlm.nih.gov/pubmed/19306885 PubMed] [http://dx.doi.org/10.1016/j.jtbi.2009.03.016 CrossRef]
* <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Lipniacki T</span>. '''Regulation of kinase activity by diffusion and feedback''', ''J&nbsp;Theor&nbsp;Biol'' <u>259</u>:291-296 (2009) [http://www.ncbi.nlm.nih.gov/pubmed/19306885 PubMed] [http://dx.doi.org/10.1016/j.jtbi.2009.03.016 CrossRef]


* <span class="nopmbm">El Khatib N</span>, <span class="nopmbm">Génieys S</span>, <span class="pmbm">Kazmierczak B</span>, <span class="nopmbm">Volpert V</span>. '''Mathematical modelling of atherosclerosis as an inflammatory disease''', ''Philos Transact&nbsp;A Math Phys Eng Sci'' <u>367</u>(1908):4877-86 (2008) [http://www.ncbi.nlm.nih.gov/pubmed/19884184 PubMed] [http://dx.doi.org/10.1098/rsta.2009.0142 CrossRef]
* <span class="pmbm">El Khatib N</span>, <span class="pmbm">Génieys S</span>, <span class="pmbm">Kazmierczak B</span>, <span class="pmbm">Volpert V</span>. '''Mathematical modelling of atherosclerosis as an inflammatory disease''', ''Philos Transact&nbsp;A Math Phys Eng Sci'' <u>367</u>(1908):4877-86 (2008) [http://www.ncbi.nlm.nih.gov/pubmed/19884184 PubMed] [http://dx.doi.org/10.1098/rsta.2009.0142 CrossRef]


* <span class="pmbm">Kaźmierczak B</span>. '''Existence of global solutions to a&nbsp;model of chondrogenesis''', ''Math&nbsp;Meth&nbsp;Appl&nbsp;Sci'' <u>32</u>(3):264-283 (2008) [http://dx.doi.org/10.1002/mma.1034 CrossRef]
* <span class="pmbm">Kaźmierczak B</span>. '''Existence of global solutions to a&nbsp;model of chondrogenesis''', ''Math&nbsp;Meth&nbsp;Appl&nbsp;Sci'' <u>32</u>(3):264-283 (2008) [http://dx.doi.org/10.1002/mma.1034 CrossRef]


* <span class="pmbm">Kaźmierczak B</span>, <span class="nopmbm">Volpert V</span>. '''Calcium waves in systems with immobile buffers as a&nbsp;limit of waves for systems with non zero diffusion''', ''Nonlinearity'' <u>21</u>:71 (2008) [http://dx.doi.org/10.1088/0951-7715/21/1/004 CrossRef]
* <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Volpert V</span>. '''Calcium waves in systems with immobile buffers as a&nbsp;limit of waves for systems with non zero diffusion''', ''Nonlinearity'' <u>21</u>:71 (2008) [http://dx.doi.org/10.1088/0951-7715/21/1/004 CrossRef]


* <span class="pmbm">Kaźmierczak B</span>, <span class="nopmbm">Volpert V</span>. '''Travelling calcium waves in systems with non diffusing buffers''', ''Math&nbsp;Mod&nbsp;Meth&nbsp;Appl&nbsp;Sci'' <u>18</u>(6):883-912 (2008) [http://dx.doi.org/10.1142/S0218202508002899 CrossRef]
* <span class="pmbm">Kaźmierczak B</span>, <span class="pmbm">Volpert V</span>. '''Travelling calcium waves in systems with non diffusing buffers''', ''Math&nbsp;Mod&nbsp;Meth&nbsp;Appl&nbsp;Sci'' <u>18</u>(6):883-912 (2008) [http://dx.doi.org/10.1142/S0218202508002899 CrossRef]


* <span class="nopmbm">Alber M</span>, <span class="nopmbm">Glimm T</span>, <span class="nopmbm">Hentschel HG</span>, <span class="pmbm">Kazmierczak B</span>, <span class="nopmbm">Zhang YT</span>, <span class="nopmbm">Zhu J</span>, <span class="nopmbm">Newman SA</span>. '''The&nbsp;morphostatic limit for a model of skeletal pattern formation in the vertebrate limb''', ''Bull&nbsp;Math&nbsp;Biol'' <u>69</u>:460-483 (2007) [http://www.ncbi.nlm.nih.gov/pubmed/17965922 PubMed] [http://dx.doi.org/10.1007/s11538-007-9264-3 CrossRef]
* <span class="pmbm">Alber M</span>, <span class="pmbm">Glimm T</span>, <span class="pmbm">Hentschel HG</span>, <span class="pmbm">Kazmierczak B</span>, <span class="pmbm">Zhang YT</span>, <span class="pmbm">Zhu J</span>, <span class="pmbm">Newman SA</span>. '''The&nbsp;morphostatic limit for a model of skeletal pattern formation in the vertebrate limb''', ''Bull&nbsp;Math&nbsp;Biol'' <u>69</u>:460-483 (2007) [http://www.ncbi.nlm.nih.gov/pubmed/17965922 PubMed] [http://dx.doi.org/10.1007/s11538-007-9264-3 CrossRef]


* <span class="nopmbm">Newman SA</span>, <span class="nopmbm">Christley S</span>, <span class="nopmbm">Glimm T</span>, <span class="nopmbm">Hentschel HG</span>, <span class="pmbm">Kazmierczak B</span>, <span class="nopmbm">Zhang YT</span>, <span class="nopmbm">Zhu J</span>, <span class="nopmbm">Alber&nbsp;M</span>. '''Multiscale models for vertebrate limb development''', ''Curr&nbsp;Top&nbsp;Dev&nbsp;Biol'' <u>81</u>:311-340 (2007) [http://www.ncbi.nlm.nih.gov/pubmed/18023733 PubMed] [http://dx.doi.org/10.1016/S0070-2153(07)81011-8 CrossRef]
* <span class="pmbm">Newman SA</span>, <span class="pmbm">Christley S</span>, <span class="pmbm">Glimm T</span>, <span class="pmbm">Hentschel HG</span>, <span class="pmbm">Kazmierczak B</span>, <span class="pmbm">Zhang YT</span>, <span class="pmbm">Zhu J</span>, <span class="pmbm">Alber&nbsp;M</span>. '''Multiscale models for vertebrate limb development''', ''Curr&nbsp;Top&nbsp;Dev&nbsp;Biol'' <u>81</u>:311-340 (2007) [http://www.ncbi.nlm.nih.gov/pubmed/18023733 PubMed] [http://dx.doi.org/10.1016/S0070-2153(07)81011-8 CrossRef]


* <span class="pmbm">Kazmierczak B</span>, <span class="nopmbm">Volpert V</span>. '''Travelling waves in partially degenerated reaction-diffusion systems''', ''Mathematical Modelling of Natural Phenomena'' <u>2</u>:106-125 (2007) [http://dx.doi.org/10.1051/mmnp:2008021 CrossRef]
* <span class="pmbm">Kazmierczak B</span>, <span class="pmbm">Volpert V</span>. '''Travelling waves in partially degenerated reaction-diffusion systems''', ''Mathematical Modelling of Natural Phenomena'' <u>2</u>:106-125 (2007) [http://dx.doi.org/10.1051/mmnp:2008021 CrossRef]


* <span class="pmbm">Kazmierczak B</span>, <span class="nopmbm">Volpert V</span>. '''Calcium waves in systems with immobile buffers as a&nbsp;limit of waves for systems with nonzero diffusion''', ''Nonlinearity'' <u>21</u>:71-98 (2007) [http://dx.doi.org/10.1088/0951-7715/21/1/004 CrossRef]
* <span class="pmbm">Kazmierczak B</span>, <span class="pmbm">Volpert V</span>. '''Calcium waves in systems with immobile buffers as a&nbsp;limit of waves for systems with nonzero diffusion''', ''Nonlinearity'' <u>21</u>:71-98 (2007) [http://dx.doi.org/10.1088/0951-7715/21/1/004 CrossRef]

Latest revision as of 09:54, 2 May 2023

Ph.D., D.Sc. (habilitation), Professor

Contact

e-mail at ippt.pan.pl: bkazmier
tel.: +48 22 8261280 ext. 450
room: 310

Institute of Fundamental Technological Research
Polish Academy of Sciences
Pawińskiego 5B, 02-106 Warsaw, Poland


Recent publications

  • Kazmierczak B, Sneyd J, Tsai J-C. Effect of buffers with multiple binding sites on calcium waves, Bull Math Biol 85(1):10 (2023) CrossRef
  • Mahiout LA, Bessonov N, Kazmierczak B, Volpert V. Mathematical modeling of respiratory viral infection and applications to SARS-CoV-2 progression, Math Meth Appl Sci 46(2):1740–1751 (2023) CrossRef
  • Mahiout AL, Bessonov N, Kazmierczak B, Sadaka G, Volpert V. Infection spreading in cell culture as a reaction-diffusion wave, ESAIM: Math Model Numer Anal 56(3):791–814 (2022) CrossRef
  • Adimy M, Chekroun A, Kazmierczak B. Traveling waves for reaction-diffusion PDE coupled to difference equation with nonlocal dispersal term and time delay, Math Model Nath Phenom 17:2022021 (2022) CrossRef
  • Mahiout LA, Kaźmierczak B, Volpert V. Viral infection spreading and mutation in cell culture, Mathematics 10(2):256 (2022) CrossRef
  • Bialecki S, Nalecz-Jawecki P, Kazmierczak B, Lipniacki. Traveling and standing fronts on curved surfaces, Physica D 401:132215 (2020) CrossRef
  • Kaźmierczak B & Sneyd J. Speed of traveling waves for monotone reaction–diffusion systems as a function of diffusion coefficients, Physica D: Nonlin Phenom 424:132940 (2021) CrossRef
  • Chen WC, Kaźmierczak B. Traveling waves in quadratic autocatalytic systems with complexing agent, Discrete Contin Dyn Syst–Ser B 26(4):1827–1842 (2021) CrossRef
  • Chatterjee P, Glimm T, Kaźmierczak B. Mathematical modeling of chondrogenic pattern formation during limb development: Recent advances in continuous models, Math Biosci 322:108319 (2020) PubMed CrossRef
  • Kazmierczak B, Tsai J-C, Bialecki S. The propagation phenomenon of solutions of a parabolic problem on the sphere, Math Model Meth Appl Sci 28(10):2001–2067 (2018) CrossRef
  • Białecki S, Kaźmierczak B, Lipniacki T. Polarization of concave domains by traveling wave pinning, PLOS One 12:e0190372 (2017) PubMed CrossRef
  • Bialecki S, Kaźmierczak B, Nowicka D, Tsai J-C. Regularity of solutions to a reaction–diffusion equation on the sphere: the Legendre series approach, Math Meth Appl Sci 40(14):5349–5369 (2017) CrossRef
  • Bobrowski A, Kaźmierczak B, Kunze M. An averaging principle for fast diffusions in domains separated by semi-permeable membranes, Math Model Meth Appl Sci 27(4):663–706 (2017) CrossRef arXiv
  • Adimy M, Chekroun A, Kaźmierczak B. Traveling waves in a coupled reaction–diffusion and difference model of hematopoiesis, J Differ Equ 262(7):4085–4128 (2017) CrossRef
  • Chatterjee P, Kaźmierczak B. Eigenfunction approach to transient patterns in a model of chemotaxis, Math Model Nat Phenom 11(2):44–62 (2016) CrossRef
  • Białecki S, Kaźmierczak B, Tsai J-C. Stationary waves on the sphere, SIAM J Appl Math 75(4):1761–1788 (2015) CrossRef
  • Szopa P, Dyzma M, Kaźmierczak B. Membrane associated complexes in calcium dynamics modelling, Phys Biol 10(3):035004 (2013) PubMed CrossRef
  • Crooks E, Kazmierczak B, Lipniacki T. A spatially extended model of kinase–receptor interaction, SIAM J Appl Math 73(1):374–400 (2013) CrossRef
  • Kaźmierczak B, Peradzyński Z. Calcium waves with mechano-chemical couplings, Math Biosci Eng 10(3):743-759 (2013) CrossRef
  • El Khatib N, Genieys S, Kazmierczak B, Volpert V. Reaction–diffusion model of artherosclerosis development, J Math Biol 65(2):349-374 (2012) PubMed CrossRef
  • Gejji R, Kaźmierczak B, Alber M. Classification and stability of global inhomogeneous solutions of a macroscopic model of cell motion, Math Biosci (2012) PubMed CrossRef
  • Dyzma M, Szopa P, Kaźmierczak B. Membrane associated complexes: new approach to calcium dynamics modeling, Math Model Nat Phenom 7(2):32-50 (2012) CrossRef
  • Hat B, Kaźmierczak B, Lipniacki T. B cell activation triggered by the formation of the small receptor cluster: A computational study, PLoS Comput Biol 7(10):e1000448 (2011) PubMed CrossRef | PDF
  • Szopa P, Lipniacki T, Kaźmierczak B. Exact solutions to a spatially extended model of kinase–receptor interaction, Phys Biol 8(5):055005 (2011) PubMed CrossRef
  • Kaźmierczak B, Peradzyński Z. Calcium waves with fast buffers and mechanical effects, J Math Biol 62:1-38 (2011, e-pub 2010) PubMed CrossRef
  • Kaźmierczak B, Dyzma M. Mechanical effects coupled with calcium waves, Arch Mech 62:121-133 (2010) PDF
  • Kaźmierczak B, Piechór K. Traveling wave solutions of a model of skin pattern formation in a singular case, Math Method Appl Sci 34(3):325–337 (2011; e-pub 2010) CrossRef
  • Kaźmierczak B, Lipniacki T. Spatial gradients in kinase cascade regulation, IET Syst Biol 4:348-355 (2010) PubMed CrossRef | PDF-ms
  • Alber M, Gejji R, Kaźmierczak B. Existence of global solutions of a macroscopic model of cellular motion in a chemotactic field, Appl Math Lett 22:1645-1648 (2009) CrossRef
  • Kaźmierczak B, Lipniacki T. Regulation of kinase activity by diffusion and feedback, J Theor Biol 259:291-296 (2009) PubMed CrossRef
  • El Khatib N, Génieys S, Kazmierczak B, Volpert V. Mathematical modelling of atherosclerosis as an inflammatory disease, Philos Transact A Math Phys Eng Sci 367(1908):4877-86 (2008) PubMed CrossRef
  • Kaźmierczak B. Existence of global solutions to a model of chondrogenesis, Math Meth Appl Sci 32(3):264-283 (2008) CrossRef
  • Kaźmierczak B, Volpert V. Calcium waves in systems with immobile buffers as a limit of waves for systems with non zero diffusion, Nonlinearity 21:71 (2008) CrossRef
  • Kaźmierczak B, Volpert V. Travelling calcium waves in systems with non diffusing buffers, Math Mod Meth Appl Sci 18(6):883-912 (2008) CrossRef
  • Alber M, Glimm T, Hentschel HG, Kazmierczak B, Zhang YT, Zhu J, Newman SA. The morphostatic limit for a model of skeletal pattern formation in the vertebrate limb, Bull Math Biol 69:460-483 (2007) PubMed CrossRef
  • Newman SA, Christley S, Glimm T, Hentschel HG, Kazmierczak B, Zhang YT, Zhu J, Alber M. Multiscale models for vertebrate limb development, Curr Top Dev Biol 81:311-340 (2007) PubMed CrossRef
  • Kazmierczak B, Volpert V. Travelling waves in partially degenerated reaction-diffusion systems, Mathematical Modelling of Natural Phenomena 2:106-125 (2007) CrossRef
  • Kazmierczak B, Volpert V. Calcium waves in systems with immobile buffers as a limit of waves for systems with nonzero diffusion, Nonlinearity 21:71-98 (2007) CrossRef