Bedoukian   RussellIPM   RussellIPM   Piezoelectric Micro-Sprayer


Home
Animal Taxa
Plant Taxa
Semiochemicals
Floral Compounds
Semiochemical Detail
Semiochemicals & Taxa
Synthesis
Control
Invasive spp.
References

Abstract

Guide

Alphascents
Pherobio
InsectScience
E-Econex
Counterpart-Semiochemicals
Print
Email to a Friend
Kindly Donate for The Pherobase

« Previous AbstractDefining adult asthma endotypes by clinical features and patterns of volatile organic compounds in exhaled air    Next Abstract"Application of a Sex Pheromone, Pheromone Analogs, and Verticillium lecanii for Management of Heterodera glycines" »

Appl Environ Microbiol


Title:Microscale biosensor for measurement of volatile fatty acids in anoxic environments
Author(s):Meyer RL; Larsen LH; Revsbech NP;
Address:"Department of Microbial Ecology, University of Aarhus, Bd. 540, Ny Munkegade, 8000 Aarhus C, Denmark. rikke.meyer@biology.au.dk"
Journal Title:Appl Environ Microbiol
Year:2002
Volume:68
Issue:3
Page Number:1204 - 1210
DOI: 10.1128/AEM.68.3.1204-1210.2002
ISSN/ISBN:0099-2240 (Print) 1098-5336 (Electronic) 0099-2240 (Linking)
Abstract:"A microscale biosensor for acetate, propionate, isobutyrate, and lactate is described. The sensor is based on the bacterial respiration of low-molecular-weight, negatively charged species with a concomitant reduction of NO(-)(3) to N(2)O. A culture of denitrifying bacteria deficient in N(2)O reductase was immobilized in front of the tip of an electrochemical N(2)O microsensor. The bacteria were separated from the outside environment by an ion-permeable membrane and supplied with nutrients (except for electron donors) from a medium reservoir behind the N(2)O sensor. The signal of the sensor, which corresponded to the rate of N(2)O production, was proportional to the supply of the electron donor to the bacterial mass. The selectivity for volatile fatty acids compared to other organic compounds was increased by selectively enhancing the transport of negatively charged compounds into the sensor by electrophoretic migration (electrophoretic sensitivity control). The sensor was susceptible to interference from O(2), N(2)O, NO(2)(-), H(2)S, and NO(-)(3). Interference from NO(-)(3) was low and could be quantified and accounted for. The detection limit was equivalent to about 1 microM acetate, and the 90% response time was 30 to 90 s. The response of the sensor was not affected by changes in pH between 5.5 and 9 and was also unaffected by changes in salinity in the range of 2 to 32 per thousand. The functioning of the sensor over a temperature span of 7 to 30 degrees C was investigated. The concentration range for a linear response was increased five times by increasing the temperature from 7 to 19.5 degrees C. The life span of the biosensor varied between 1 and 3 weeks after manufacturing"
Keywords:"Anaerobiosis *Biosensing Techniques Electrochemistry/instrumentation Fatty Acids, Volatile/*metabolism Hydrogen-Ion Concentration Nitrates/metabolism Nitrous Oxide/*metabolism Sodium Chloride Stenotrophomonas/classification/genetics/*growth & development;"
Notes:"MedlineMeyer, Rikke Louise Larsen, Lars Hauer Revsbech, Niels Peter eng Evaluation Study Research Support, Non-U.S. Gov't 2002/03/02 Appl Environ Microbiol. 2002 Mar; 68(3):1204-10. doi: 10.1128/AEM.68.3.1204-1210.2002"

 
Back to top
 
Citation: El-Sayed AM 2024. The Pherobase: Database of Pheromones and Semiochemicals. <http://www.pherobase.com>.
© 2003-2024 The Pherobase - Extensive Database of Pheromones and Semiochemicals. Ashraf M. El-Sayed.
Page created on 16-11-2024