TY - BOOK
T1 - Discrete event simulations for glycolysis pathway and energy balance
AU - Zwieten, van, D.A.J.
AU - Rooda, J.E.
AU - Armbruster, H.D.
AU - Nagy, J.D.
PY - 2010
Y1 - 2010
N2 - In this report, the biological network of the glycolysis pathway has been modeled using
discrete event models (DEMs). The most important feature of this pathway is that
energy is released. To create a stable steady-state system an energy molecule equilibrating
enzyme and metabolic reactions have been added, resulting in the energy balance system.
Stability and stochastic in
uences on the results have been investigated and result in
an unstable system, except for a small region of input parameters. To stabilize the
energy balance system some feedback regulators are presented. It is shown that stochastic
behavior has got a signicant in
uence on a otherwise stable biological system.
AB - In this report, the biological network of the glycolysis pathway has been modeled using
discrete event models (DEMs). The most important feature of this pathway is that
energy is released. To create a stable steady-state system an energy molecule equilibrating
enzyme and metabolic reactions have been added, resulting in the energy balance system.
Stability and stochastic in
uences on the results have been investigated and result in
an unstable system, except for a small region of input parameters. To stabilize the
energy balance system some feedback regulators are presented. It is shown that stochastic
behavior has got a signicant in
uence on a otherwise stable biological system.
M3 - Report
T3 - SE report
BT - Discrete event simulations for glycolysis pathway and energy balance
PB - Technische Universiteit Eindhoven
CY - Eindhoven
ER -