Abstract
We consider a mathematical model for the evolutionary dynamics of tumour
cells in vascularised tumours under chemotherapy. The model comprises a
system of coupled partial integro-differential equations for the
phenotypic distribution of tumour cells, the concentration of oxygen and
the concentration of a chemotherapeutic agent. In order to disentangle
the impact of different evolutionary parameters on the emergence of
intra-tumour phenotypic heterogeneity and the development of resistance
to chemotherapy, we construct explicit solutions to the equation for the
phenotypic distribution of tumour cells and provide a detailed
quantitative characterisation of the long-time asymptotic behaviour of
such solutions. Analytical results are integrated with numerical
simulations of a calibrated version of the model based on biologically
consistent parameter values. The results obtained provide a theoretical
explanation for the observation that the phenotypic properties of tumour
cells in vascularised tumours vary with the distance from the blood
vessels. Moreover, we demonstrate that lower oxygen levels may correlate
with higher levels of phenotypic variability, which suggests that the
presence of hypoxic regions supports intra-tumour phenotypic
heterogeneity. Finally, the results of our analysis put on a rigorous
mathematical basis the idea, previously suggested by formal asymptotic
results and numerical simulations, that hypoxia favours the selection
for chemoresistant phenotypic variants prior to treatment. Consequently,
this facilitates the development of resistance following chemotherapy.
Original language | English |
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Journal | Vietnam Journal of Mathematics |
Volume | First Online |
Early online date | 6 Oct 2020 |
DOIs | |
Publication status | E-pub ahead of print - 6 Oct 2020 |
Keywords
- Vascularised tumours
- Evolutionary dynamics
- Intra-tumour heterogeneity
- Resistance to chemotherapy
- Mathematical oncology
- Non-local partial differential equations