Feedback control is widely used in chemical engineering to improve the performance and robustness of chemical processes. Feedback controllers require a ‘subtractor’ that is able to compute the error between the process output and the reference signal. In the case of embedded biomolecular control circuits, subtractors designed using standard chemical reaction network theory can only realise one-sided subtraction, rendering standard controller design approaches inadequate. Here, we show how a biomolecular controller that allows tracking of required changes in the outputs of enzymatic reaction processes can be designed and implemented within the framework of chemical reaction network theory. The controller architecture employs an inversion-bas...
Background: Cycles of covalent modification are ubiquitous motifs in cellular signalling. Although s...
The control of biochemical processes is a major goal in many fields, encompassing metabolic engineer...
The design of synthetic circuits for controlling molecular-scale processes is an important goal of s...
Feedback control is widely used in chemical engineering to improve the performance and robustness of...
We show how an embedded reference tracking biomolecular controller for enzymatic reactions can be de...
We consider the design of synthetic embedded feedback circuits that can implement desired changes in...
The use of abstract chemical reaction networks (CRNs) as a modelling and design framework for the im...
We consider the design of synthetic embedded feedback circuits that can implement desired changes in...
Chemical reaction networks can be utilised as basic components for nucleic acid feedback control sys...
For control in biomolecular systems, the most basic objective of maintaining a small error in a targ...
We show how an important class of nonlinear feedback controllers can be designed using idealized abs...
Reliable biochemical implementations of linear controllers can provide a large set of tools for the ...
International audienceThe advancements of synthetic biology make biochemical systems of increasing c...
Principles of feedback control have been shown to naturally arise in biological systems and successf...
Chemical Reaction Network (CRN) models based on the mass-action law play an important role in the li...
Background: Cycles of covalent modification are ubiquitous motifs in cellular signalling. Although s...
The control of biochemical processes is a major goal in many fields, encompassing metabolic engineer...
The design of synthetic circuits for controlling molecular-scale processes is an important goal of s...
Feedback control is widely used in chemical engineering to improve the performance and robustness of...
We show how an embedded reference tracking biomolecular controller for enzymatic reactions can be de...
We consider the design of synthetic embedded feedback circuits that can implement desired changes in...
The use of abstract chemical reaction networks (CRNs) as a modelling and design framework for the im...
We consider the design of synthetic embedded feedback circuits that can implement desired changes in...
Chemical reaction networks can be utilised as basic components for nucleic acid feedback control sys...
For control in biomolecular systems, the most basic objective of maintaining a small error in a targ...
We show how an important class of nonlinear feedback controllers can be designed using idealized abs...
Reliable biochemical implementations of linear controllers can provide a large set of tools for the ...
International audienceThe advancements of synthetic biology make biochemical systems of increasing c...
Principles of feedback control have been shown to naturally arise in biological systems and successf...
Chemical Reaction Network (CRN) models based on the mass-action law play an important role in the li...
Background: Cycles of covalent modification are ubiquitous motifs in cellular signalling. Although s...
The control of biochemical processes is a major goal in many fields, encompassing metabolic engineer...
The design of synthetic circuits for controlling molecular-scale processes is an important goal of s...