Litcius/Paper detail

Interfacing gene circuits with microelectronics through engineered population dynamics

M. Omar Din, Aida Martín, Ivan Razinkov, Nicholas Csicsery, Jeff Hasty

2020Science Advances39 citationsDOIOpen Access PDF

Abstract

While there has been impressive progress connecting bacterial behavior with electrodes, an attractive observation to facilitate advances in synthetic biology is that the growth of a bacterial colony can be determined from impedance changes over time. Here, we interface synthetic biology with microelectronics through engineered population dynamics that regulate the accumulation of charged metabolites. We demonstrate electrical detection of the bacterial response to heavy metals via a population control circuit. We then implement this approach to a synchronized genetic oscillator where we obtain an oscillatory impedance profile from engineered bacteria. We lastly miniaturize an array of electrodes to form "bacterial integrated circuits" and demonstrate its applicability as an interface with genetic circuits. This approach paves the way for new advances in synthetic biology, analytical chemistry, and microelectronic technologies.

Topics & Concepts

InterfacingMicroelectronicsSynthetic biologyElectronic circuitPopulationElectrical impedanceNanotechnologyComputer scienceBiologyBiological systemElectronic engineeringMaterials scienceComputational biologyElectrical engineeringEngineeringComputer hardwareSociologyDemographyMicrobial Fuel Cells and Bioremediationbioluminescence and chemiluminescence researchMolecular Communication and Nanonetworks