One of the main goals of metabolic engineering is to obtain high levels of a microbial product through genetic modifications. To improve the productivity of such a process, the dynamic implementation of metabolic engineering strategies has been proven to be more beneficial compared to static genetic manipulations in which the gene expression is not controlled over time, by resolving the trade-off between growth and production. In this work, a bilevel optimization framework based on constraint-based models is applied to identify an optimal strategy for dynamic genetic and process level manipulations to increase productivity. The dynamic enzyme-cost flux balance analysis (deFBA) as underlying metabolic network model captures the network dynam...
Genetic modifications, such as gene knockout technique, have become mainstream in metabolic engineer...
Production of biofuels and bio-based chemicals is being increasingly pursued by chemical industry to...
The current production of a number of commodity chemicals relies on the exploitation of fossil fuels...
© 2016 Modulating the expression of target genes is an effective metabolic engineering approach to i...
The regulation of metabolic activity by tuning enzyme expression levels is crucial to sustain cellul...
© 2018 In this work, a model predictive control of a fed-batch bioreactor is presented, described by...
8 páginas, 5 figuras, 1 tablaKinetic models have a great potential for metabolic engineering applica...
Since the 1970s, bioprocess engineering has focussed on the optimization of the production of chemic...
Many high-demand industrial products are generated by microorganisms, including fuels, food, vitamin...
Metabolic engineering has grown dramatically and is now widely used, particularly in the production ...
Microorganisms are well positioned to address many societal concerns in areas such as health, sustai...
BACKGROUND: Through genetic engineering it is possible to introduce targeted genetic changes and her...
Abstract Background Production...
We developed a dynamic flux balance model for fed-batch Saccharomyces cereVisiae fermentation that c...
A dynamic flux balance model based on a genome-scale metabolic network reconstruction is developed f...
Genetic modifications, such as gene knockout technique, have become mainstream in metabolic engineer...
Production of biofuels and bio-based chemicals is being increasingly pursued by chemical industry to...
The current production of a number of commodity chemicals relies on the exploitation of fossil fuels...
© 2016 Modulating the expression of target genes is an effective metabolic engineering approach to i...
The regulation of metabolic activity by tuning enzyme expression levels is crucial to sustain cellul...
© 2018 In this work, a model predictive control of a fed-batch bioreactor is presented, described by...
8 páginas, 5 figuras, 1 tablaKinetic models have a great potential for metabolic engineering applica...
Since the 1970s, bioprocess engineering has focussed on the optimization of the production of chemic...
Many high-demand industrial products are generated by microorganisms, including fuels, food, vitamin...
Metabolic engineering has grown dramatically and is now widely used, particularly in the production ...
Microorganisms are well positioned to address many societal concerns in areas such as health, sustai...
BACKGROUND: Through genetic engineering it is possible to introduce targeted genetic changes and her...
Abstract Background Production...
We developed a dynamic flux balance model for fed-batch Saccharomyces cereVisiae fermentation that c...
A dynamic flux balance model based on a genome-scale metabolic network reconstruction is developed f...
Genetic modifications, such as gene knockout technique, have become mainstream in metabolic engineer...
Production of biofuels and bio-based chemicals is being increasingly pursued by chemical industry to...
The current production of a number of commodity chemicals relies on the exploitation of fossil fuels...