[16] with V. Vetma, L. Casarez-Perez, …, and M. Koegl, Confounding factors in targeted degradation of short-lived proteins (2024). (article, bioRxiv)
[15] with K. Fellner, P. Hofer, M. Oberer, R. Schreiber and R. Zechner, The potential roles of transacylation in intracellular lipolysis and related QSSA approximations, Bull. Math. Biol. 85(82) (2023). (article – open access)
[14] with V. A. Kovtunenko, P. Krejčí, G. A. Monteiro and J. Runcziková, Stress-controlled hysteresis and long-time dynamics of implicit differential equations arising in hypoplasticity, Archivum mathematicum 59(3) (2023), pp 275-286. (article – open access)
[13] with H. Izuhara, M. Mimura and B. Q. Tang, An aggregation model of cockroaches with fast-or-slow motion dichotomy, J. Math. Biol. 85, 22 (2022). (arxiv, article)
[12] with C. K. Macnamara, Mathematical modelling of p53 signalling during DNA damage response: A survey, Int. J. Mol. Sci. 22(19) (2021), 10590. (preprint, article – open access)
[11] with V. A. Kovtunenko, E. Bauer, P. Krejčí, G. A. Monteiro and L. Straková-Siváková, Cyclic behavior of simple models in hypoplasticity and plasticity with nonlinear kinematic hardening, J. Sib. Fed. Univ. – Math. Phys. 14(6) (2021), pp 1-12. (preprint, article – open access)
[10] with D. Hilhorst, M. Mimura and Y. Morita, Singular limit for a reaction-diffusion-ODE system in a neolithic transition model, JDE 295 (2021), pp. 39-69. (preprint, article – open access)
[9] with M. Mimura and R. Mori, Asymptotic behavior of solutions of Aoki-Shida-Shigesada model in bounded domains, DCDS-B 26(4) (2021), pp. 1917-1930. (preprint, article)
[8] with D. Hilhorst and M. Mimura, Large time behaviour of the solution of a nonlinear diffusion problem in anthropology, J. Math. Study 51 (2018), pp. 309-336. (preprint, article)
[7] with M.H. Kabir and M. Mimura, On the well-posedness of a dispersal model for farmers and hunter-gatherers in the Neolithic transition, M3AS 28(2) (2018), pp. 195-222. (preprint, article)
[6] Trend to equilibrium for a reaction-diffusion system modelling reversible enzyme reaction, Bull. Math. Biol. 80 (2017), pp. 104-129. (arxiv, preprint, article)
[5] Positive effect of Mdm2 on p53 expression explains excitability of p53 in response to DNA damage, J. Theor. Biol. 418 (2017), pp. 94-104. (preprint, article)
[4] with J. Clairambault, Diverse spatio-temporal dynamical patterns of p53 and cell fate decisions, AIP Conf. Proc. 1738, 320005 (2016). (preprint, article)
[3] with L. Dimitrio, J. Clairambault and R. Natalini, Dynamics of p53 in single cells: physiologically based ODE and reaction-diffusion PDE models, Phys. Biol. 11 (2014) 045001. (preprint, article)
[2] with J. Clairambault, Reaction-diffusion systems for spatio-temporal intracellular protein networks: a beginner’s guide with two examples, CSBJ 10(16) (2014), pp. 12-22. (preprint, article)
[1] with L. Dimitrio, J. Clairambault and R. Natalini, The p53 protein and its molecular network: modelling a missing link between DNA damage and cell fate, Biochimica et Biophysica Acta 1844(1) (2014), pp. 232-247. (preprint, article)
Thesis
Modélisation mathématique du rôle et de la dynamique temporelle de la protéine p53 après dommages à l’ADN induits par les médicaments anticancéreux (EN: Mathematical model of the role and temporal dynamics of protein p53 after drug-induced DNA damage), defended publicly on Sep 1st, 2015. (pdf)
Here is my academic and not anymore updated website.
Ján Eliaš 