A bioreporter bioluminescent integrated circuit for very low-level chemical sensing in both gas and liquid environments

Vijayaraghavan, R.; Islam, Syed K.; Zhang, M.; Ripp, Steven; Caylor, S.; Bull, Nora D; Moser, S.; Terry, S.C.; Blalock, Benjamin J.; Sayler, Gary S.

doi:10.1016/j.snb.2006.10.064

Cited by 44 publications

(31 citation statements)

References 9 publications

(17 reference statements)

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“…Also, new affinity sensors, such as transmembrane sensors and sensors utilizing whole cells or cell networks, have significantly improved. For example, a proof-of-concept for a whole-cell bioluminescent bioreporter for the detection of VOCs has been developed (91). These bioluminescent bioreporters generate visible light in response to specific chemical or physical agents in their environment.…”

Section: Identification and Quantification Of The Plant-emitted Vocsmentioning

confidence: 99%

“…These bioluminescent bioreporters generate visible light in response to specific chemical or physical agents in their environment. LODs of less than one μg L −1 have been reported for such systems (91). Despite the lag in response and lack of correlation between concentration and bioluminescence, it was hypothesized that the bioreporter can produce qualitative as well as quantitative results.…”

Section: Identification and Quantification Of The Plant-emitted Vocsmentioning

confidence: 99%

See 1 more Smart Citation

Detection of Diseased Plants by Analysis of Volatile Organic Compound Emission

Jansen

Wildt

Kappers

et al. 2011

Annu. Rev. Phytopathol.

109

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This review focuses on the detection of diseased plants by analysis of volatile organic compound (VOC) emissions. It includes an overview of studies that report on the impact of infectious and noninfectious diseases on these emissions and discusses the specificity of disease-induced emissions. The review also provides an overview of processes that affect the gas balance of plant volatiles, including their loss processes. These processes are considered as important because they contribute to the time-dynamic concentration profiles of plant-emitted volatiles. In addition, we describe the most popular techniques currently in use to measure volatiles emitted from plants, with emphasis on agricultural application. Dynamic sampling coupled with gas chromatography and followed by an appropriate detector is considered as the most appropriate method for application in agriculture. It is recommended to evaluate the state-of-the-art in the fields concerned with this method and to explore the development of a new instrument based on the specific needs for application in agricultural practice. However, to apply such an instrument in agriculture remains a challenge, mainly due to high costs.

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Section: Identification and Quantification Of The Plant-emitted Vocsmentioning

confidence: 99%

Section: Identification and Quantification Of The Plant-emitted Vocsmentioning

confidence: 99%

Detection of Diseased Plants by Analysis of Volatile Organic Compound Emission

Jansen

Wildt

Kappers

et al. 2011

Annu. Rev. Phytopathol.

109

View full text Add to dashboard Cite

show abstract

“…7(b) can be used. The cellular structure can be a bioluminescent bioreporter [39][40][41][42] that produces a reporter protein, which in this case is a luciferase (LU), on excitation by an analyte. The bioreporter can be developed by engineering LU genes genetically in other living cells [43].…”

Section: B Bio-electro Interface Modelmentioning

confidence: 99%

Biologically Inspired Bio-Cyber Interface Architecture and Model for Internet of Bio-NanoThings Applications

Chude-Okonkwo

Malekian

Maharaj

2016

IEEE Trans. Commun.

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“…The bioluminescent-bioreporter integrated circuit (BBIC) was one of the first developments in which genetically engineered bacteria are interfaced with an electronic circuit and has been reported many times in the last decade since its first development [Simpson et al 2001b;Bolton et al 2002;Ripp et al 2003;Nivens et al 2004;Vijayaraghavan et al 2007]. In these studies, a biosensor, i.e.…”

Section: Optical Microchip-based Biosensorsmentioning

confidence: 99%

Synthetic Biology and Microdevices

Venken

Marchal

Vanderleyden

2013

J. Emerg. Technol. Comput. Syst.

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Recent developments demonstrate that the combination of microbiology with micro-and nanoelectronics is a successful approach to develop new miniaturized sensing devices and other technologies. In the last decade, there is a shift from the optimization of the abiotic components, e.g. the chip, to the improvement of the processing capabilities of cells through genetic engineering. The synthetic biology approach will not only give rise to systems with new functionalities, but will also improve the robustness and speed of their response towards applied signals. To this end, the development of new genetic circuits has to be guided by computational design methods that enable to tune and optimize the circuit response. As the successful design of genetic circuits is highly dependent on the quality and reliability of its composing elements, intense characterization of standard biological parts will be crucial for an efficient rational design process in the development of new genetic circuits. Microengineered devices can thereby offer a new analytical approach for the study of complex biological parts and systems. By summarizing the recent techniques in creating new synthetic circuits and in integrating biology with microdevices, this review aims at emphasizing the power of combining synthetic biology with microfluidics and microelectronics.

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A bioreporter bioluminescent integrated circuit for very low-level chemical sensing in both gas and liquid environments

Cited by 44 publications

References 9 publications

Detection of Diseased Plants by Analysis of Volatile Organic Compound Emission

Detection of Diseased Plants by Analysis of Volatile Organic Compound Emission

Biologically Inspired Bio-Cyber Interface Architecture and Model for Internet of Bio-NanoThings Applications

Synthetic Biology and Microdevices

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