Difference between revisions of "Stoichiometric Matrix (analysis)"
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| + | ;Analysis title | ||
| + | :[[File:Default-analysis-icon.png]] Stoichiometric Matrix | ||
| + | ;Provider | ||
| + | :[[Institute of Systems Biology]] | ||
| + | ;Class | ||
| + | :{{Class|biouml.plugins.modelreduction.StoichiometricAnalysis}} | ||
| + | ;Plugin | ||
| + | :[[Biouml.plugins.modelreduction (plugin)|biouml.plugins.modelreduction (Model reduction plug-in)]] | ||
| + | |||
| + | ==== Description ==== | ||
The stoichiometric matrix ''N'' provides the linear relationship of the model between the flux rates of the (enzymatic) reactions and the derivatives of the reactant (enzyme) concentrations. | The stoichiometric matrix ''N'' provides the linear relationship of the model between the flux rates of the (enzymatic) reactions and the derivatives of the reactant (enzyme) concentrations. | ||
If a reaction network has ''n'' reactions and ''m'' participating molecular species then the dynamic mass balance equation can be written as | If a reaction network has ''n'' reactions and ''m'' participating molecular species then the dynamic mass balance equation can be written as | ||
| − | :: [[File: | + | :: [[File:Differential-algebraic-equations-Stoichiometric-Matrix-stoich1.png]] |
where ''v'' is the flux vector and ''S'' is the concentration vector: | where ''v'' is the flux vector and ''S'' is the concentration vector: | ||
| − | :: [[File: | + | :: [[File:Differential-algebraic-equations-Stoichiometric-Matrix-stoich2.png]] |
==== Example ==== | ==== Example ==== | ||
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Consider the following system of reactions: | Consider the following system of reactions: | ||
| − | :: [[File: | + | :: [[File:Differential-algebraic-equations-Stoichiometric-Matrix-stoich3.png]] |
This systems comprises four reactions and five different molecular species. The stoichiometry matrix for this system can be written as: | This systems comprises four reactions and five different molecular species. The stoichiometry matrix for this system can be written as: | ||
| − | :: [[File: | + | :: [[File:Differential-algebraic-equations-Stoichiometric-Matrix-stoich4.png]] |
where the rows correspond to ''S''<sub>1</sub>, ''S''<sub>2</sub>, ''S''<sub>3</sub>, ''S''<sub>4</sub> and ''S''<sub>5</sub>, respectively. Note that the process of converting a reaction scheme into a stoichiometry matrix can be a lossy transformation, for example, the stoichiometries in the second reaction simplify when included in the matrix. | where the rows correspond to ''S''<sub>1</sub>, ''S''<sub>2</sub>, ''S''<sub>3</sub>, ''S''<sub>4</sub> and ''S''<sub>5</sub>, respectively. Note that the process of converting a reaction scheme into a stoichiometry matrix can be a lossy transformation, for example, the stoichiometries in the second reaction simplify when included in the matrix. | ||
[[Category:Analyses]] | [[Category:Analyses]] | ||
| − | [[Category: | + | [[Category:Differential algebraic equations (analyses group)]] |
| + | [[Category:ISB analyses]] | ||
| + | [[Category:Autogenerated pages]] | ||
Latest revision as of 18:14, 9 December 2020
- Analysis title
Stoichiometric Matrix
- Provider
- Institute of Systems Biology
- Class
StoichiometricAnalysis- Plugin
- biouml.plugins.modelreduction (Model reduction plug-in)
[edit] Description
The stoichiometric matrix N provides the linear relationship of the model between the flux rates of the (enzymatic) reactions and the derivatives of the reactant (enzyme) concentrations.
If a reaction network has n reactions and m participating molecular species then the dynamic mass balance equation can be written as
where v is the flux vector and S is the concentration vector:
[edit] Example
Consider the following system of reactions:
This systems comprises four reactions and five different molecular species. The stoichiometry matrix for this system can be written as:
where the rows correspond to S1, S2, S3, S4 and S5, respectively. Note that the process of converting a reaction scheme into a stoichiometry matrix can be a lossy transformation, for example, the stoichiometries in the second reaction simplify when included in the matrix.
