Novel solutions for a model of wound healing angiogenesis

We prove the existence of novel, shock-fronted travelling wave solutions to a model of wound healing angiogenesis studied in Pettet et al (2000 IMA J. Math. App. Med. 17 395-413) assuming two conjectures hold. In the previous work, the authors showed that for certain parameter values, a heteroclinic...

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Bibliographic Details
Published in:Nonlinearity 2014-12, Vol.27 (12), p.2975-3003
Main Authors: Harley, K, van Heijster, P, Marangell, R, Pettet, G J, Wechselberger, M
Format: Article
Language:English
Subjects:
advection-reaction-diffusion systems
canards
singularly perturbed systems
travelling wave solutions
wound healing angiogenesis
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Summary:We prove the existence of novel, shock-fronted travelling wave solutions to a model of wound healing angiogenesis studied in Pettet et al (2000 IMA J. Math. App. Med. 17 395-413) assuming two conjectures hold. In the previous work, the authors showed that for certain parameter values, a heteroclinic orbit in the phase plane representing a smooth travelling wave solution exists. However, upon varying one of the parameters, the heteroclinic orbit was destroyed, or rather cut-off, by a wall of singularities in the phase plane. As a result, they concluded that under this parameter regime no travelling wave solutions existed. Using techniques from geometric singular perturbation theory and canard theory, we show that a travelling wave solution actually still exists for this parameter regime. We construct a heteroclinic orbit passing through the wall of singularities via a folded saddle canard point onto a repelling slow manifold. The orbit leaves this manifold via the fast dynamics and lands on the attracting slow manifold, finally connecting to its end state. This new travelling wave is no longer smooth but exhibits a sharp front or shock. Finally, we identify regions in parameter space where we expect that similar solutions exist. Moreover, we discuss the possibility of more exotic solutions.
ISSN:0951-7715
1361-6544
DOI:10.1088/0951-7715/27/12/2975