Select a metabolic model and a map (if you have) for objective optimization, the flux result can be visulized in the map.
Select a metabolic model and a map (if you have) for objective optimization, the flux result can be visulized in the map.
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*<font size=3>Robustness analysis</font> ([http://sb.nhri.org.tw/GEMsME/Simulation%20step3.html Step-by-step])
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*<font size=3>Flux variability analysis</font> ([http://sb.nhri.org.tw/GEMsME/Simulation%20step3.html Step-by-step])
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Select the reactions of interest in a model to see how sensitive the objective is to the particular reactions.
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Select a metabolic model and a map (if you have) for flux variability analysis, the min and max fluxes of reaction can be plotted in the map and the blocked reaction are tagged with crosses.
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*<font size=3>Flux variability analysis</font> ([http://sb.nhri.org.tw/GEMsME/Simulation%20step4.html Step-by-step])
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*<font size=3>Robustness analysis</font> ([http://sb.nhri.org.tw/GEMsME/Simulation%20step4.html Step-by-step])
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Select a metabolic model and a map (if you have) for flux variability analysis, the min and max fluxes of reaction can be plotted in the map and the blocked reaction are tagged with crosses.
+
Select the reactions of interest in a model to see how sensitive the objective is to the particular reactions.
*<font size=3>Essentiality analysis</font> ([http://sb.nhri.org.tw/GEMsME/Simulation%20step5.html Step-by-step])
*<font size=3>Essentiality analysis</font> ([http://sb.nhri.org.tw/GEMsME/Simulation%20step5.html Step-by-step])
