Difference between revisions of "Design Guidelines For Sequestration Feedback Networks"

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(Created page with "{{Paper |Title=Design Guidelines For Sequestration Feedback Networks |Authors=Ania-Ariadna Baetica, Yoke Peng Leong, Noah Olsman, Richard M. Murray |Source=Submitted, <i>Cell...")
 
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|Title=Design Guidelines For Sequestration Feedback Networks
 
|Title=Design Guidelines For Sequestration Feedback Networks
 
|Authors=Ania-Ariadna Baetica, Yoke Peng Leong, Noah Olsman, Richard M. Murray
 
|Authors=Ania-Ariadna Baetica, Yoke Peng Leong, Noah Olsman, Richard M. Murray
|Source=Submitted, <i>Cell Systems<i> (Nov 2018)
+
|Source=Submitted, <i>Cell Systems</i> (Nov 2018)
 
|Abstract=Integral control is commonly used in mechanical and electrical systems to ensure perfect adaptation. A proposed design of integral control for synthetic biological systems employs the sequestration of two biochemical controller species. The unbound amount of controller species captures the integral of the error between the current and the desired state of the system. However, implementing integral control inside bacterial cells using sequestration feedback has been challenging due to the controller molecules being degraded and diluted. Furthermore, integral control can only be achieved under stability conditions that not all sequestration feedback networks fulfill. In this work, we give guidelines for ensuring stability and good performance (small steady-state error) in sequestration feedback networks. Our guidelines provide simple tuning options to obtain a flexible and practical biological implementation of sequestration feedback control. Using tools and metrics from control theory, we pave the path for the systematic design of synthetic biological systems.
 
|Abstract=Integral control is commonly used in mechanical and electrical systems to ensure perfect adaptation. A proposed design of integral control for synthetic biological systems employs the sequestration of two biochemical controller species. The unbound amount of controller species captures the integral of the error between the current and the desired state of the system. However, implementing integral control inside bacterial cells using sequestration feedback has been challenging due to the controller molecules being degraded and diluted. Furthermore, integral control can only be achieved under stability conditions that not all sequestration feedback networks fulfill. In this work, we give guidelines for ensuring stability and good performance (small steady-state error) in sequestration feedback networks. Our guidelines provide simple tuning options to obtain a flexible and practical biological implementation of sequestration feedback control. Using tools and metrics from control theory, we pave the path for the systematic design of synthetic biological systems.
 
|URL=https://www.biorxiv.org/content/biorxiv/early/2018/10/30/455493.full-text.pdf
 
|URL=https://www.biorxiv.org/content/biorxiv/early/2018/10/30/455493.full-text.pdf

Latest revision as of 15:47, 26 January 2019

Title Design Guidelines For Sequestration Feedback Networks
Authors Ania-Ariadna Baetica, Yoke Peng Leong, Noah Olsman, Richard M. Murray
Source Submitted, Cell Systems (Nov 2018)
Abstract Integral control is commonly used in mechanical and electrical systems to ensure perfect adaptation. A proposed design of integral control for synthetic biological systems employs the sequestration of two biochemical controller species. The unbound amount of controller species captures the integral of the error between the current and the desired state of the system. However, implementing integral control inside bacterial cells using sequestration feedback has been challenging due to the controller molecules being degraded and diluted. Furthermore, integral control can only be achieved under stability conditions that not all sequestration feedback networks fulfill. In this work, we give guidelines for ensuring stability and good performance (small steady-state error) in sequestration feedback networks. Our guidelines provide simple tuning options to obtain a flexible and practical biological implementation of sequestration feedback control. Using tools and metrics from control theory, we pave the path for the systematic design of synthetic biological systems.
Type Journal submission
URL https://www.biorxiv.org/content/biorxiv/early/2018/10/30/455493.full-text.pdf
Tag blom18-cellsys
ID 2018g
Funding DARPA BioCon
Flags