Monitoring microbial metabolites using an inductively coupled resonance circuit

Daniil Karnaushenko; Larysa Baraban; Dan Ye; Ilke Uguz; Rafael G. Mendes; Mark H. Rümmeli; J. Arjan G.M. De Visser; Oliver G. Schmidt; Gianaurelio Cuniberti; Denys Makarov

doi:10.1038/srep12878

Monitoring microbial metabolites using an inductively coupled resonance circuit

Daniil Karnaushenko, Larysa Baraban, Dan Ye, Ilke Uguz, Rafael G. Mendes, Mark H. Rümmeli, J. Arjan G.M. De Visser, Oliver G. Schmidt, Gianaurelio Cuniberti, Denys Makarov

Department of Biomedical Engineering

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

We present a new approach to monitor microbial population dynamics in emulsion droplets via changes in metabolite composition, using an inductively coupled LC resonance circuit. The signal measured by such resonance detector provides information on the magnetic field interaction with the bacterial culture, which is complementary to the information accessible by other detection means, based on electric field interaction, i.e. capacitive or resistive, as well as optical techniques. Several charge-related factors, including pH and ammonia concentrations, were identified as possible contributors to the characteristic of resonance detector profile. The setup enables probing the ionic byproducts of microbial metabolic activity at later stages of cell growth, where conventional optical detection methods have no discriminating power.

Original language	English
Article number	12878
Journal	Scientific Reports
Volume	5
DOIs	https://doi.org/10.1038/srep12878
State	Published - 12 Aug 2015

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abstract = "We present a new approach to monitor microbial population dynamics in emulsion droplets via changes in metabolite composition, using an inductively coupled LC resonance circuit. The signal measured by such resonance detector provides information on the magnetic field interaction with the bacterial culture, which is complementary to the information accessible by other detection means, based on electric field interaction, i.e. capacitive or resistive, as well as optical techniques. Several charge-related factors, including pH and ammonia concentrations, were identified as possible contributors to the characteristic of resonance detector profile. The setup enables probing the ionic byproducts of microbial metabolic activity at later stages of cell growth, where conventional optical detection methods have no discriminating power.",

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T1 - Monitoring microbial metabolites using an inductively coupled resonance circuit

AU - Karnaushenko, Daniil

AU - Baraban, Larysa

AU - Ye, Dan

AU - Uguz, Ilke

AU - Mendes, Rafael G.

AU - Rümmeli, Mark H.

AU - De Visser, J. Arjan G.M.

AU - Schmidt, Oliver G.

AU - Cuniberti, Gianaurelio

AU - Makarov, Denys

PY - 2015/8/12

Y1 - 2015/8/12

N2 - We present a new approach to monitor microbial population dynamics in emulsion droplets via changes in metabolite composition, using an inductively coupled LC resonance circuit. The signal measured by such resonance detector provides information on the magnetic field interaction with the bacterial culture, which is complementary to the information accessible by other detection means, based on electric field interaction, i.e. capacitive or resistive, as well as optical techniques. Several charge-related factors, including pH and ammonia concentrations, were identified as possible contributors to the characteristic of resonance detector profile. The setup enables probing the ionic byproducts of microbial metabolic activity at later stages of cell growth, where conventional optical detection methods have no discriminating power.

AB - We present a new approach to monitor microbial population dynamics in emulsion droplets via changes in metabolite composition, using an inductively coupled LC resonance circuit. The signal measured by such resonance detector provides information on the magnetic field interaction with the bacterial culture, which is complementary to the information accessible by other detection means, based on electric field interaction, i.e. capacitive or resistive, as well as optical techniques. Several charge-related factors, including pH and ammonia concentrations, were identified as possible contributors to the characteristic of resonance detector profile. The setup enables probing the ionic byproducts of microbial metabolic activity at later stages of cell growth, where conventional optical detection methods have no discriminating power.

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Monitoring microbial metabolites using an inductively coupled resonance circuit

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