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Development of an Immunocapture-Based Polymeric Optical Fiber Sensor for Bacterial Detection in Water
Conventional methods for pathogen detection in water rely on time-consuming enrichment steps followed by biochemical identification strategies, which require assay times ranging from 24 hours to a week. However, in recent years, significant efforts have been made to develop biosensing technologies e...
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| Published in: | Polymers 2024-03, Vol.16 (6), p.861 |
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| cites | cdi_FETCH-LOGICAL-c411t-cbeead738b05020ba5818aa3333ec52adcd39d21a066cf36e1a74e40e5fd577b3 |
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| container_issue | 6 |
| container_start_page | 861 |
| container_title | Polymers |
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| creator | Lopes, Rafaela Nascimento Pinto, Paulo Henrique Silva Vargas, Juan David Lopez Dante, Alex Macrae, Andrew Allil, Regina Célia Barros Werneck, Marcelo Martins |
| description | Conventional methods for pathogen detection in water rely on time-consuming enrichment steps followed by biochemical identification strategies, which require assay times ranging from 24 hours to a week. However, in recent years, significant efforts have been made to develop biosensing technologies enabling rapid and close-to-real-time detection of waterborne pathogens. In previous studies, we developed a plastic optical fiber (POF) immunosensor using an optoelectronic configuration consisting of a U-Shape probe connected to an LED and a photodetector. Bacterial detection was evaluated with the immunosensor immersed in a bacterial suspension in water with a known concentration. Here, we report on the sensitivity of a new optoelectronic configuration consisting of two POF U-shaped probes, one as the reference and the other as the immunosensor, for the detection of
. In addition, another methos of detection was tested where the sensors were calibrated in the air, before being immersed in a bacterial suspension and then read in the air. This modification improved sensor sensitivity and resulted in a faster detection time. After the immunocapture, the sensors were DAPI-stained and submitted to confocal microscopy. The histograms obtained confirmed that the responses of the immunosensors were due to the bacteria. This new sensor detected the presence of
at 10
CFU/mL in less than 20 min. Currently, sub-20 min is faster than previous studies using fiber-optic based biosensors. We report on an inexpensive and faster detection technology when compared with conventional methods. |
| doi_str_mv | 10.3390/polym16060861 |
| format | article |
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. In addition, another methos of detection was tested where the sensors were calibrated in the air, before being immersed in a bacterial suspension and then read in the air. This modification improved sensor sensitivity and resulted in a faster detection time. After the immunocapture, the sensors were DAPI-stained and submitted to confocal microscopy. The histograms obtained confirmed that the responses of the immunosensors were due to the bacteria. This new sensor detected the presence of
at 10
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. In addition, another methos of detection was tested where the sensors were calibrated in the air, before being immersed in a bacterial suspension and then read in the air. This modification improved sensor sensitivity and resulted in a faster detection time. After the immunocapture, the sensors were DAPI-stained and submitted to confocal microscopy. The histograms obtained confirmed that the responses of the immunosensors were due to the bacteria. This new sensor detected the presence of
at 10
CFU/mL in less than 20 min. Currently, sub-20 min is faster than previous studies using fiber-optic based biosensors. 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. In addition, another methos of detection was tested where the sensors were calibrated in the air, before being immersed in a bacterial suspension and then read in the air. This modification improved sensor sensitivity and resulted in a faster detection time. After the immunocapture, the sensors were DAPI-stained and submitted to confocal microscopy. The histograms obtained confirmed that the responses of the immunosensors were due to the bacteria. This new sensor detected the presence of
at 10
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| ispartof | Polymers, 2024-03, Vol.16 (6), p.861 |
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| source | Open Access: PubMed Central; Publicly Available Content Database |
| subjects | Analysis Antibodies Antigens Bacteria Biosensors Configurations E coli Enzymes Escherichia coli Fiber optics Immunosensors Methods Optical fibers Optics Optoelectronics Pathogens Sensitivity Sensors Severe acute respiratory syndrome coronavirus 2 Thin films |
| title | Development of an Immunocapture-Based Polymeric Optical Fiber Sensor for Bacterial Detection in Water |
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