Integrated Design of a Dual-Mode Colorimetric Sensor Driven by Enzyme-like Activity Regulation Strategy for Ultratrace and Portable Detection of Hg2

Integrated Design of a Dual-Mode Colorimetric Sensor Driven by Enzyme-like Activity Regulation Strategy for Ultratrace and Portable Detection of Hg2

Colorimetric analysis for mercury detection has great application potential in the prevention of health damage caused by mercury in the environment. Sensitivity, selectivity, and portability are core competencies of sensors, and concentrating these properties in a single sensor for efficient mercury...

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Bibliographic Details
Published in:Environmental science & technology Vol. 57; no. 36; pp. 13397 - 13407
Main Authors: Luo, Linpin, Zhuo, Junchen, Zhang, Yinuo, Zhang, Weihao, Su, Wenqiao, Sun, Jing, Shen, Yizhong, Wang, Jianlong
Format: Journal Article
Language:English
Published: Easton American Chemical Society 12-09-2023
Subjects:
Calibration
Colorimetry
Copper selenides
Copper sulfides
Damage prevention
Ecotoxicology and Public Health
Enzymes
Heavy metals
Mercury
Mercury (metal)
Nanosensors
Portability
Selenium
Self calibration
Sensors
Smartphones
Water analysis
Water sampling
colorimetric
onsite
dual-mode
enzyme-like activities
Hg2+ detection
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Summary:Colorimetric analysis for mercury detection has great application potential in the prevention of health damage caused by mercury in the environment. Sensitivity, selectivity, and portability are core competencies of sensors, and concentrating these properties in a single sensor for efficient mercury detection remains a great challenge. Herein, a hollow structure CuS@CuSe@PVP (CCP) was prepared in which the enzyme-like activities could be activated by Hg2+ due to the antagonism between Hg and Se, inspiring the establishment of a colorimetric method for Hg2+ detection. As for Hg2+ detection performance, the linear range (LR) and limit of detection (LOD) were 1–900 and 0.81 nM in the POD-like activity system, respectively. Also, 5–550 nM of LR and 2.34 nM of LOD were achieved in the OD-like activity system. Further, a smartphone-mediated portable RGB nanosensor was fabricated, with a LOD down to 6.65 nM in the POD-like system and 7.97 nM in the OD-like system. Moreover, the excellent self-calibration and satisfactory recovery of 94.77%–106.16% were shown in the application of real water samples analysis. This study represented advanced progress toward emerging applications of nanozymes with multiple enzyme-like activities in heavy metal detection and will accelerate the development of efficient and portable heavy metal sensors.
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ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.3c04469