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Main Authors: Zhou, Tianyu, Zhang, Zhiyang, Chen, Jiadong, Wang, Qiaoning, Chen, Yan, Wu, Yanzhou, Choo, Jaebum, Chen, Lingxin
Format: Artículo científico
Language:en
Published: Analytical chemistry 2025
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/40810673/
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author Zhou, Tianyu
Zhang, Zhiyang
Chen, Jiadong
Wang, Qiaoning
Chen, Yan
Wu, Yanzhou
Choo, Jaebum
Chen, Lingxin
author_facet Zhou, Tianyu
Zhang, Zhiyang
Chen, Jiadong
Wang, Qiaoning
Chen, Yan
Wu, Yanzhou
Choo, Jaebum
Chen, Lingxin
Zhou, Tianyu
Zhang, Zhiyang
Chen, Jiadong
Wang, Qiaoning
Chen, Yan
Wu, Yanzhou
Choo, Jaebum
Chen, Lingxin
collection PubMed - marine biology
contents Advancing Whole-Cell Biosensors: Kinetics-Dependent Metabolic SERS Analytics for Pollutant Differentiation and Quantification. Zhou, Tianyu Zhang, Zhiyang Chen, Jiadong Wang, Qiaoning Chen, Yan Wu, Yanzhou Choo, Jaebum Chen, Lingxin Biosensing Techniques Spectrum Analysis, Raman Escherichia coli Silver Metal Nanoparticles Kinetics Gold Metals, Heavy Environmental Pollutants Machine Learning Whole-cell biosensors (WCBs), which detect targeting analytes through cellular responses, have become powerful tools for environmental monitoring. However, existing WCBs often rely on the single-channel low-dimension signal outputs (e.g., fluorescence), hindering the detection and differentiation of multiple analytes. Herein, we demonstrated a surface enhanced Raman scattering (SERS)-based WCB strategy via detecting kinetics-dependent metabolic responses between multiple pollutants and bacteria, enabling differentiation of 8 heavy metals and 5 perfluorinated compounds (PFASs). In this strategy, the wild-type () without gene editing is used as the sensing bacterium, and ultrathin gold shell coated silver nanoparticles (Ag@AuNPs) are used as SERS enhancement substrates. The Ag@AuNPs exhibit high sensitivity and biocompatibility, enabling the determination of trace bacterial metabolites and preventing signal interference from cellular toxicity responses to silver-based nanoparticles. By combining the SERS spectra of the pollutant-exposed at different bacteria-nanoparticle coincubation time points, we constructed joint SERS spectra for predictive analytics using machine learning (ML) algorithms. We have successfully achieved the precise classification of various pollutants with high prediction accuracy, including different types and forms of heavy metals (100%) and different PFASs (≥92%), as well as the quantification of representative pollutants. The successful detection of different heavy metal ions and PFASs in seawater demonstrates its potential for detecting and distinguishing harmful pollutants in complex real-world environments. This work demonstrates a facile and efficient WCB platform for pollutant classification and quantification, providing an effective analytical method for environmental monitoring.
format Artículo científico
id pubmed_40810673
institution PubMed
language en
publishDate 2025
publisher Analytical chemistry
record_format pubmed
spellingShingle Advancing Whole-Cell Biosensors: Kinetics-Dependent Metabolic SERS Analytics for Pollutant Differentiation and Quantification.
Zhou, Tianyu
Zhang, Zhiyang
Chen, Jiadong
Wang, Qiaoning
Chen, Yan
Wu, Yanzhou
Choo, Jaebum
Chen, Lingxin
Biosensing Techniques
Spectrum Analysis, Raman
Escherichia coli
Silver
Metal Nanoparticles
Kinetics
Gold
Metals, Heavy
Environmental Pollutants
Machine Learning
Advancing Whole-Cell Biosensors: Kinetics-Dependent Metabolic SERS Analytics for Pollutant Differentiation and Quantification. Zhou, Tianyu Zhang, Zhiyang Chen, Jiadong Wang, Qiaoning Chen, Yan Wu, Yanzhou Choo, Jaebum Chen, Lingxin Biosensing Techniques Spectrum Analysis, Raman Escherichia coli Silver Metal Nanoparticles Kinetics Gold Metals, Heavy Environmental Pollutants Machine Learning Whole-cell biosensors (WCBs), which detect targeting analytes through cellular responses, have become powerful tools for environmental monitoring. However, existing WCBs often rely on the single-channel low-dimension signal outputs (e.g., fluorescence), hindering the detection and differentiation of multiple analytes. Herein, we demonstrated a surface enhanced Raman scattering (SERS)-based WCB strategy via detecting kinetics-dependent metabolic responses between multiple pollutants and bacteria, enabling differentiation of 8 heavy metals and 5 perfluorinated compounds (PFASs). In this strategy, the wild-type () without gene editing is used as the sensing bacterium, and ultrathin gold shell coated silver nanoparticles (Ag@AuNPs) are used as SERS enhancement substrates. The Ag@AuNPs exhibit high sensitivity and biocompatibility, enabling the determination of trace bacterial metabolites and preventing signal interference from cellular toxicity responses to silver-based nanoparticles. By combining the SERS spectra of the pollutant-exposed at different bacteria-nanoparticle coincubation time points, we constructed joint SERS spectra for predictive analytics using machine learning (ML) algorithms. We have successfully achieved the precise classification of various pollutants with high prediction accuracy, including different types and forms of heavy metals (100%) and different PFASs (≥92%), as well as the quantification of representative pollutants. The successful detection of different heavy metal ions and PFASs in seawater demonstrates its potential for detecting and distinguishing harmful pollutants in complex real-world environments. This work demonstrates a facile and efficient WCB platform for pollutant classification and quantification, providing an effective analytical method for environmental monitoring.
title Advancing Whole-Cell Biosensors: Kinetics-Dependent Metabolic SERS Analytics for Pollutant Differentiation and Quantification.
topic Biosensing Techniques
Spectrum Analysis, Raman
Escherichia coli
Silver
Metal Nanoparticles
Kinetics
Gold
Metals, Heavy
Environmental Pollutants
Machine Learning
url https://pubmed.ncbi.nlm.nih.gov/40810673/