TY - JOUR
T1 - Application of the cellular oxidation biosensor to Toxicity Identification Evaluations for high-throughput toxicity assessment of river water
AU - Ooi, Lia
AU - Okazaki, Keisuke
AU - Arias-Barreiro, Carlos R.
AU - Heng, Lee Yook
AU - Mori, Izumi C.
N1 - Funding Information:
This work was supported by Kurita Water and Environment Foundation and JSPS Asian Core Program (Research and Education Center for the Risk Based Asian Oriented Integrated Watershed Management) to I.C.M. and International Joint Usage/Research Center Collaboration of IPSR Okayama University to L.Y.H. and I.C.M..
Funding Information:
This work was supported by Kurita Water and Environment Foundation and JSPS Asian Core Program (Research and Education Center for the Risk Based Asian Oriented Integrated Watershed Management) to I.C.M. and International Joint Usage/Research Center Collaboration of IPSR Okayama University to L.Y.H. and I.C.M.. Appendix A
Publisher Copyright:
© 2020 The Authors
PY - 2020/5
Y1 - 2020/5
N2 - Toxicity Identification Evaluation (TIE) is a useful method for the classification and identification of toxicants in a composite environment water sample. However, its extension to a larger sample size has been restrained owing to the limited throughput of toxicity bioassays. Here we reported the development of a high-throughput method of TIE Phase I. This newly developed method was assisted by the fluorescence-based cellular oxidation (CO) biosensor fabricated with roGFP2-expressing bacterial cells in 96-well microplate format. The assessment of four river water samples from Langat river basin by this new method demonstrated that the contaminant composition of the four samples can be classified into two distinct groups. The entire toxicity assay consisted of 2338 tests was completed within 12 h with a fluorescence microplate reader. Concurrently, the sample volume for each assay was reduced to 50 μL, which is 600 to 4700 times lesser to compare with conventional bioassays. These imply that the throughput of the CO biosensor-assisted TIE Phase I is now feasible for constructing a large-scale toxicity monitoring system, which would cover a whole watershed scale.
AB - Toxicity Identification Evaluation (TIE) is a useful method for the classification and identification of toxicants in a composite environment water sample. However, its extension to a larger sample size has been restrained owing to the limited throughput of toxicity bioassays. Here we reported the development of a high-throughput method of TIE Phase I. This newly developed method was assisted by the fluorescence-based cellular oxidation (CO) biosensor fabricated with roGFP2-expressing bacterial cells in 96-well microplate format. The assessment of four river water samples from Langat river basin by this new method demonstrated that the contaminant composition of the four samples can be classified into two distinct groups. The entire toxicity assay consisted of 2338 tests was completed within 12 h with a fluorescence microplate reader. Concurrently, the sample volume for each assay was reduced to 50 μL, which is 600 to 4700 times lesser to compare with conventional bioassays. These imply that the throughput of the CO biosensor-assisted TIE Phase I is now feasible for constructing a large-scale toxicity monitoring system, which would cover a whole watershed scale.
KW - Ecotoxicity management
KW - High-throughput cytotoxicity biosensor
KW - Integrated watershed management
KW - River water pollution
KW - Toxicity identification evaluation
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U2 - 10.1016/j.chemosphere.2020.125933
DO - 10.1016/j.chemosphere.2020.125933
M3 - Article
C2 - 32079055
AN - SCOPUS:85078558117
SN - 0045-6535
VL - 247
JO - Chemosphere
JF - Chemosphere
M1 - 125933
ER -