Biodegradable and photostable Nb2C MXene quantum dots as promising nanofluorophores for metal ions sensing and fluorescence imaging

[Display omitted] •Fluorescent Nb2C QDs with well-defined MXene phase structures were synthesized.•The Nb2C QDs presented high biocompatibility and unique biodegradation property.•The Nb2C QDs showed promising application in fluorescence imaging and sensing. Conventional fluorescent probes are eithe...

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Bibliographic Details
Published in:Sensors and actuators. B, Chemical Chemical, 2020-04, Vol.309, p.127735, Article 127735
Main Authors: Yang, Guanghui, Zhao, Jinlai, Yi, Shaozhen, Wan, Xuejuan, Tang, Jiaoning
Format: Article
Language:English
Subjects:
Biocompatibility
Biodegradability
Biodegradation
Biomedical materials
Crystal structure
Crystallography
Detection
Environmental monitoring
Fluorescence
Fluorescent indicators
Fluorescent probes
Heavy metals
Imaging
Metal ions
MXene quantum dots
MXenes
Niobium carbide
Photobleaching resistance
Quantum dots
Stability
Toxicity
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Summary:[Display omitted] •Fluorescent Nb2C QDs with well-defined MXene phase structures were synthesized.•The Nb2C QDs presented high biocompatibility and unique biodegradation property.•The Nb2C QDs showed promising application in fluorescence imaging and sensing. Conventional fluorescent probes are either easily photobleached or non-biodegradable, which often leads to the unstable fluorescence signal output and long-term biological toxicity. Therefore, the development of novel fluorescent materials with both excellent photostability and biodegradability is of great significance for further broadening their application in numerous research fields. In this work, Nb2C quantum dots (Nb2C QDs) with pristine crystallographic structures of Nb2C MXene phases and surface oxygen-containing species are synthesized by an ultrasound assisted physicochemical exfoliation in tetrapropylammonium hydroxide. Detailed analyses indicate that the Nb2C QDs not only possess excellent chemical- and photo-stable fluorescence emission but also achieve successful application in fluorescence sensing of heavy metal ions and fluorescence imaging. More importantly, it is confirmed that the Nb2C QDs present high biocompatibility and unique biodegradation property responsive to human myeloperoxidase, implying the application safety of Nb2C QDs in vivo. Under the background of ever-growing and stringent requirements for biosafety and technical stability, the chemical- and photo-stability, biocompatibility, biodegradability, and most importantly the promising fluorescence sensing/imaging characteristic of the obtained Nb2C QDs may argue well for their future applications in environmental monitoring, biomedical diagnosis, visual display, and anti-counterfeiting.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2020.127735