Detection of buried explosives with immobilized bacterial bioreporters
Summary The unchecked dispersal of antipersonnel landmines since the late 19th century has resulted in large areas contaminated with these explosive devices, creating a substantial worldwide humanitarian safety risk. The main obstacle to safe and effective landmine removal is the identification of t...
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doaj-dc8099444dec4471a1706bb1b471e9532021-02-17T15:39:02ZengWileyMicrobial Biotechnology1751-79152021-01-0114125126110.1111/1751-7915.13683Detection of buried explosives with immobilized bacterial bioreportersBenjamin Shemer0Etai Shpigel1Carina Hazan2Yossef Kabessa3Aharon J. Agranat4Shimshon Belkin5Institute of Life Sciences The Hebrew University of Jerusalem Jerusalem IsraelInstitute of Life Sciences The Hebrew University of Jerusalem Jerusalem IsraelInstitute of Chemistry The Hebrew University of Jerusalem Jerusalem IsraelThe Department of Applied Physics The Hebrew University of Jerusalem Jerusalem IsraelThe Department of Applied Physics The Hebrew University of Jerusalem Jerusalem IsraelInstitute of Life Sciences The Hebrew University of Jerusalem Jerusalem IsraelSummary The unchecked dispersal of antipersonnel landmines since the late 19th century has resulted in large areas contaminated with these explosive devices, creating a substantial worldwide humanitarian safety risk. The main obstacle to safe and effective landmine removal is the identification of their exact location, an activity that currently requires entry of personnel into the minefields; to date, there is no commercialized technology for an efficient stand‐off detection of buried landmines. In this article, we describe the optimization of a microbial sensor strain, genetically engineered for the remote detection of 2,4,6‐trinitrotoloune (TNT)‐based mines. This bioreporter, designed to bioluminescence in response to minute concentrations of either TNT or 2,4‐dinitotoluene (DNT), was immobilized in hydrogel beads and optimized for dispersion over the minefield. Following modifications of the hydrogel matrix in which the sensor bacteria are encapsulated, as well as their genetic reporting elements, these sensor bacteria sensitively detected buried 2,4‐dinitrotoluene in laboratory experiments. Encapsulated in 1.5 mm 2% alginate beads containing 1% polyacrylic acid, they also detected the location of a real metallic antipersonnel landmine under field conditions. To the best of our knowledge, this is the first report demonstrating the detection of a buried landmine with a luminescent microbial bioreporter.https://doi.org/10.1111/1751-7915.13683 |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Benjamin Shemer Etai Shpigel Carina Hazan Yossef Kabessa Aharon J. Agranat Shimshon Belkin |
spellingShingle |
Benjamin Shemer Etai Shpigel Carina Hazan Yossef Kabessa Aharon J. Agranat Shimshon Belkin Detection of buried explosives with immobilized bacterial bioreporters Microbial Biotechnology |
author_facet |
Benjamin Shemer Etai Shpigel Carina Hazan Yossef Kabessa Aharon J. Agranat Shimshon Belkin |
author_sort |
Benjamin Shemer |
title |
Detection of buried explosives with immobilized bacterial bioreporters |
title_short |
Detection of buried explosives with immobilized bacterial bioreporters |
title_full |
Detection of buried explosives with immobilized bacterial bioreporters |
title_fullStr |
Detection of buried explosives with immobilized bacterial bioreporters |
title_full_unstemmed |
Detection of buried explosives with immobilized bacterial bioreporters |
title_sort |
detection of buried explosives with immobilized bacterial bioreporters |
publisher |
Wiley |
series |
Microbial Biotechnology |
issn |
1751-7915 |
publishDate |
2021-01-01 |
description |
Summary The unchecked dispersal of antipersonnel landmines since the late 19th century has resulted in large areas contaminated with these explosive devices, creating a substantial worldwide humanitarian safety risk. The main obstacle to safe and effective landmine removal is the identification of their exact location, an activity that currently requires entry of personnel into the minefields; to date, there is no commercialized technology for an efficient stand‐off detection of buried landmines. In this article, we describe the optimization of a microbial sensor strain, genetically engineered for the remote detection of 2,4,6‐trinitrotoloune (TNT)‐based mines. This bioreporter, designed to bioluminescence in response to minute concentrations of either TNT or 2,4‐dinitotoluene (DNT), was immobilized in hydrogel beads and optimized for dispersion over the minefield. Following modifications of the hydrogel matrix in which the sensor bacteria are encapsulated, as well as their genetic reporting elements, these sensor bacteria sensitively detected buried 2,4‐dinitrotoluene in laboratory experiments. Encapsulated in 1.5 mm 2% alginate beads containing 1% polyacrylic acid, they also detected the location of a real metallic antipersonnel landmine under field conditions. To the best of our knowledge, this is the first report demonstrating the detection of a buried landmine with a luminescent microbial bioreporter. |
url |
https://doi.org/10.1111/1751-7915.13683 |
work_keys_str_mv |
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