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A hierarchy of biomolecular proportional-integral-derivative feedback controllers for robust perfect adaptation and dynamic performance

Maurice Filo, Sant Kumar, Mustafa Khammash

2022Nature Communications66 citationsDOIOpen Access PDF

Abstract

Proportional-Integral-Derivative (PID) feedback controllers are the most widely used controllers in industry. Recently, the design of molecular PID-controllers has been identified as an important goal for synthetic biology and the field of cybergenetics. In this paper, we consider the realization of PID-controllers via biomolecular reactions. We propose an array of topologies offering a compromise between simplicity and high performance. We first demonstrate that different biomolecular PI-controllers exhibit different performance-enhancing capabilities. Next, we introduce several derivative controllers based on incoherent feedforward loops acting in a feedback configuration. Alternatively, we show that differentiators can be realized by placing molecular integrators in a negative feedback loop, which can be augmented by PI-components to yield PID-controllers. We demonstrate that PID-controllers can enhance stability and dynamic performance, and can also reduce stochastic noise. Finally, we provide an experimental demonstration using a hybrid setup where in silico PID-controllers regulate a genetic circuit in single yeast cells.

Topics & Concepts

PID controllerControl theory (sociology)Computer scienceFeed forwardRealization (probability)Synthetic biologyStability (learning theory)Negative feedbackFeedback loopNoise (video)Control engineeringControl (management)EngineeringMathematicsTemperature controlBioinformaticsArtificial intelligenceElectrical engineeringBiologyStatisticsImage (mathematics)Computer securityVoltageMachine learningGene Regulatory Network AnalysisMonoclonal and Polyclonal Antibodies ResearchMicrobial Metabolic Engineering and Bioproduction