Imaging-based optofluidic biolaser array encapsulated with dynamic living organisms
Optofluidic biolasers have emerged as promising tools for biomedical analysis due to their strong light-matter interactions and miniaturized size. Recent developments in optofluidic lasers have opened a new Frontier in monitoring biological processes. However, most biolasers require precise recordin...
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sg-ntu-dr.10356-1593522022-06-15T02:06:07Z Imaging-based optofluidic biolaser array encapsulated with dynamic living organisms Gong, Xuerui Feng, Shilun Qiao, Zhen Chen, Yu-Cheng School of Electrical and Electronic Engineering School of Chemical and Biomedical Engineering Engineering::Electrical and electronic engineering Engineering::Bioengineering Emission Spectroscopy Escherichia Coli Optofluidic biolasers have emerged as promising tools for biomedical analysis due to their strong light-matter interactions and miniaturized size. Recent developments in optofluidic lasers have opened a new Frontier in monitoring biological processes. However, most biolasers require precise recording of the lasing spectrum at the single cavity level, which limits its application in high-throughput applications. Herein, a microdroplet laser array encapsulated with living Escherichia coli was printed on highly reflective mirrors, where laser emission images were employed to reflect the dynamic changes in living organisms. The concept of image-based lasing analysis was proposed by quantifying the integrated pixel intensity of the lasing image from whispering-gallery modes. Finally, dynamic interactions between E. coli and antibiotic drugs were compared under fluorescence and laser emission images. The amplification that occurred during laser generation enabled the quantification of tiny biological changes in the gain medium. Laser imaging presented a significant increase in integrated pixel intensity by 2 orders of magnitude. Our findings demonstrate that image-based lasing analysis is more sensitive to dynamic changes than fluorescence analysis, paving the way for high-throughput on-chip laser analysis of living organisms. Agency for Science, Technology and Research (A*STAR) Nanyang Technological University This research is supported by A*STAR under its AME IRG Grant (project no. A2084c0063). We would like to thank the lab support from Centre of Bio-Devices and Bioinformatics and Internal grant NAP SUG-M4082308.040 from NTU. 2022-06-15T02:06:07Z 2022-06-15T02:06:07Z 2021 Journal Article Gong, X., Feng, S., Qiao, Z. & Chen, Y. (2021). Imaging-based optofluidic biolaser array encapsulated with dynamic living organisms. Analytical Chemistry, 93(14), 5823-5830. https://dx.doi.org/10.1021/acs.analchem.1c00020 0003-2700 https://hdl.handle.net/10356/159352 10.1021/acs.analchem.1c00020 33734676 2-s2.0-85103489172 14 93 5823 5830 en A2084c0063 NAP SUG-M4082308.040 Analytical Chemistry © 2021 American Chemical Society. All rights reserved. |
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Engineering::Electrical and electronic engineering Engineering::Bioengineering Emission Spectroscopy Escherichia Coli |
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Engineering::Electrical and electronic engineering Engineering::Bioengineering Emission Spectroscopy Escherichia Coli Gong, Xuerui Feng, Shilun Qiao, Zhen Chen, Yu-Cheng Imaging-based optofluidic biolaser array encapsulated with dynamic living organisms |
| description |
Optofluidic biolasers have emerged as promising tools for biomedical analysis due to their strong light-matter interactions and miniaturized size. Recent developments in optofluidic lasers have opened a new Frontier in monitoring biological processes. However, most biolasers require precise recording of the lasing spectrum at the single cavity level, which limits its application in high-throughput applications. Herein, a microdroplet laser array encapsulated with living Escherichia coli was printed on highly reflective mirrors, where laser emission images were employed to reflect the dynamic changes in living organisms. The concept of image-based lasing analysis was proposed by quantifying the integrated pixel intensity of the lasing image from whispering-gallery modes. Finally, dynamic interactions between E. coli and antibiotic drugs were compared under fluorescence and laser emission images. The amplification that occurred during laser generation enabled the quantification of tiny biological changes in the gain medium. Laser imaging presented a significant increase in integrated pixel intensity by 2 orders of magnitude. Our findings demonstrate that image-based lasing analysis is more sensitive to dynamic changes than fluorescence analysis, paving the way for high-throughput on-chip laser analysis of living organisms. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Gong, Xuerui Feng, Shilun Qiao, Zhen Chen, Yu-Cheng |
| format |
Article |
| author |
Gong, Xuerui Feng, Shilun Qiao, Zhen Chen, Yu-Cheng |
| author_sort |
Gong, Xuerui |
| title |
Imaging-based optofluidic biolaser array encapsulated with dynamic living organisms |
| title_short |
Imaging-based optofluidic biolaser array encapsulated with dynamic living organisms |
| title_full |
Imaging-based optofluidic biolaser array encapsulated with dynamic living organisms |
| title_fullStr |
Imaging-based optofluidic biolaser array encapsulated with dynamic living organisms |
| title_full_unstemmed |
Imaging-based optofluidic biolaser array encapsulated with dynamic living organisms |
| title_sort |
imaging-based optofluidic biolaser array encapsulated with dynamic living organisms |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/159352 |
| _version_ |
1736856363241308160 |