Using basic thermodynamical principles we derive a Cahn--Hilliard--Darcy model for tumour growth including nutrient diffusion, chemotaxis, active transport, adhesion, apoptosis and proliferation.  The model generalise earlier models and in particular include active transport mechanisms which ensures thermodynamical consistency.  We perform a formally matched asymptotic expansion and develop several sharp interface models.  Some of them are classical and some new ones which for example include a jump in the nutrient density at the interface.  A linear stability analysis for a growing nucleus is performed and in particular the role of the new active transport term is analysed.  Numerical computations are performed to study the influence of the active transport term for specific growth scenarios

Alt H. W.

Emanuel Sitka

Harald Garcke

Kei Fong Lam

Oden J. T.

Schmidt A.

Vanessa Styles

arXiv

Using basic thermodynamic principles we derive a Cahn-Hilliard-Darcy model for tumour growth including nutrient diffusion, chemotaxis, active transport, adhesion, apoptosis and proliferation. In contrast to earlier works, the model is based on a volume-averaged velocity and in particular includes active transport mechanisms which ensure thermodynamic consistency. We perform a formally matched asymptotic expansion and develop several sharp interface models. Some of them are classical and some are new which for example include a jump in the nutrient density at the interface. A linear stability analysis for a growing nucleus is performed and in particular the role of the new active transport term is analysed. Numerical computations are performed to study the influence of the active transport term for specific growth scenarios

Garcke, Harald

Lam, Kei Fong

Sitka, Emanuel

Styles, Vanessa

University of Regensburg Publication Server

A Cahn–Hilliard–Darcy model for tumour growth with chemotaxis and active transport

 We propose and investigate a model for lipid raft formation and dynamics in biological membranes. The model describes the lipid composition of the membrane and an interaction with cholesterol. To account for cholesterol exchange between cytosol and cell membrane we couple a bulk-diffusion to an evolution equation on the membrane. The latter describes the relaxation dynamics for an energy which takes lipid–phase separation and lipid–cholesterol interaction energy into account. It takes the form of an (extended) Cahn–Hilliard equation. Different laws for the exchange term represent equilibrium and nonequilibrium models. We present a thermodynamic justification, analyze the respective qualitative behavior and derive asymptotic reductions of the model. In particular we present a formal asymptotic expansion near the sharp interface limit, where the membrane is separated into two pure phases of saturated and unsaturated lipids, respectively. Finally we perform numerical simulations and investigate the long-time behavior of the model and its parameter dependence. Both the mathematical analysis and the numerical simulations show the emergence of raft-like structures in the nonequilibrium case whereas in the equilibrium case only macrodomains survive in the long-time evolution. </jats:p

Johannes Kampmann

Andreas Rätz

Matthias Röger

Crossref

Mathematical Models and Methods in Applied Sciences

A coupled surface-Cahn–Hilliard bulk-diffusion system modeling lipid raft formation in cell membranes

We propose and investigate a model for lipid raft formation and dynamics in biological
membranes. The model describes the lipid composition of the membrane and an interaction
with cholesterol. To account for cholesterol exchange between cytosol and cell membrane we couple
a bulk-diffusion to an evolution equation on the membrane. The latter describes a relaxation
dynamics for an energy taking lipid-phase separation and lipid-cholesterol interaction energy into
account. It takes the form of an (extended) Cahn{Hilliard equation. Different laws for the exchange
term represent equilibrium and non-equilibrium models. We present a thermodynamic
justification, analyze the respective qualitative behavior and derive asymptotic reductions of the
model. In particular we present a formal asymptotic expansion near the sharp interface limit,
where the membrane is separated into two pure phases of saturated and unsaturated lipids, respectively.
Finally we perform numerical simulations and investigate the long-time behavior of
the model and its parameter dependence. Both the mathematical analysis and the numerical
simulations show the emergence of raft-like structures in the non-equilibrium case whereas in the
equilibrium case only macrodomains survive in the long-time evolution

Kampmann, Johannes

Rätz, Andreas

Röger, Matthias

Eldorado - Repository of the TU Dortmund

A coupled surface-Cahn-Hilliard bulk-diffusion system modeling lipid raft formation in cell membranes

Harald Garcke (16067042)

Kei Fong Lam (16232027)

Emanuel Sitka (16232030)

Vanessa Styles (4460662)

Sussex Research Online

A Cahn-Hilliard-Darcy model for tumour growth with chemotaxis and active transport

Using basic thermodynamic principles we derive a Cahn--Hilliard--Darcy model for tumour growth including nutrient diffusion, chemotaxis, active transport, adhesion, apoptosis and proliferation. The model generalises earlier models and in particular includes active transport mechanisms which ensure thermodynamic consistency. We perform a formally matched asymptotic expansion and develop several sharp interface models. Some of them are classical and some are new which for example include a jump in the nutrient density at the interface. A linear stability analysis for a growing nucleus is performed and in particular the role of the new active transport term is analysed. Numerical computations are performed to study the influence of the active transport term for specific growth scenarios

We propose and investigate a model for lipid raft formation and dynamics in biological membranes. The model describes the lipid composition of the membrane and an interaction with cholesterol. To account for cholesterol exchange between cytosol and cell membrane we couple a bulk-diffusion to an evolution equation on the membrane. The latter describes the relaxation dynamics for an energy which takes lipid-phase separation and lipid-cholesterol interaction energy into account. It takes the form of an (extended) Cahn-Hilliard equation. Different laws for the exchange term represent equilibrium and nonequilibrium models. We present a thermodynamic justification, analyze the respective qualitative behavior and derive asymptotic reductions of the model. In particular we present a formal asymptotic expansion near the sharp interface limit, where the membrane is separated into two pure phases of saturated and unsaturated lipids, respectively. Finally we perform numerical simulations and investigate the long-time behavior of the model and its parameter dependence. Both the mathematical analysis and the numerical simulations show the emergence of raft-like structures in the nonequilibrium case whereas in the equilibrium case only macrodomains survive in the long-time evolution

We propose and investigate a model for lipid raft formation and dynamics in biological membranes. The model describes the lipid composition of the membrane and an interaction with cholesterol. To account for cholesterol exchange between cytosol and cell membrane we couple a bulk-diffusion to an evolution equation on the membrane. The latter describes a relaxation dynamics for an energy taking lipid-phase separation and lipid-cholesterol interaction energy into account. It takes the form of an (extended) Cahn--Hilliard equation. Different laws for the exchange term represent equilibrium and non-equilibrium models. We present a thermodynamic justification, analyze the respective qualitative behavior and derive asymptotic reductions of the model. In particular we present a formal asymptotic expansion near the sharp interface limit, where the membrane is separated into two pure phases of saturated and unsaturated lipids, respectively. Finally we perform numerical simulations and investigate the long-time behavior of the model and its parameter dependence. Both the mathematical analysis and the numerical simulations show the emergence of raft-like structures in the non-equilibrium case whereas in the equilibrium case only macrodomains survive in the long-time evolution

A coupled surface-Cahn--Hilliard bulk-diffusion system modeling lipid raft formation in cell membranes

A Cahn-Hilliard-Darcy model for tumour growth with chemotaxis and active transport

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University of Regensburg Publication Server

Crossref

Eldorado - Repository of the TU Dortmund

Sussex Research Online

University of Regensburg Publication Server

University of Regensburg Publication Server

University of Regensburg Publication Server