Direct preparation of solid carbon dots by pyrolysis of collagen waste and their applications in fluorescent sensing and imaging

Xiaoyun Qin; Cuicui Fu; Jin Zhang; Wenlong Shao; Xiaomei Qin; Yanghai Gui; Lan Wang; Huishi Guo; Fenghua Chen; Liying Jiang; Gang Wu; Floris J. Bikker; Dan Luo

doi:10.3389/fchem.2022.1006389

Direct preparation of solid carbon dots by pyrolysis of collagen waste and their applications in fluorescent sensing and imaging

Xiaoyun Qin, Cuicui Fu, Jin Zhang, Wenlong Shao, Xiaomei Qin, Yanghai Gui, Lan Wang, Huishi Guo, Fenghua Chen, Liying Jiang, Gang Wu, Floris J. Bikker, Dan Luo^*

^*Corresponding author for this work

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

The fluorescent carbon dots (CDs) have found their extensive applications in sensing, bioimaging, and photoelectronic devices. In general terms, the synthesis of CDs is straight-forward, though their subsequent purification can be laborious. Therefore, there is a need for easier ways to generate solid CDs with a high conversion yield. Herein, we used collagen waste as a carbon source in producing solid CDs through a calcination procedure without additional chemical decomposition treatment of the raw material. Considering a mass of acid has destroyed the original protein macromolecules into the assembled structure with amino acids and peptide chains in the commercial extraction procedure of collagen product. The residual tissues were assembled with weak intermolecular interactions, which would easily undergo dehydration, polymerization, and carbonization during the heat treatment to produce solid CDs directly. The calcination parameters were surveyed to give the highest conversion yield at 78%, which occurred at 300°C for 2 h. N and S atomic doping CDs (N-CDs and S-CDs) were synthesized at a similar process except for immersion of the collagen waste in sulfuric acid or nitric acid in advance. Further experiments suggested the prepared CDs can serve as an excellent sensor platform for Fe³⁺ in an acid medium with high anti-interference. The cytotoxicity assays confirmed the biosafety and biocompatibility of the CDs, suggesting potential applications in bioimaging. This work provides a new avenue for preparing solid CDs with high conversion yield.

Original language	English
Article number	1006389
Pages (from-to)	1-14
Number of pages	14
Journal	Frontiers in Chemistry
Volume	10
DOIs	https://doi.org/10.3389/fchem.2022.1006389
Publication status	Published - 12 Sept 2022

Bibliographical note

Funding Information:
This work was supported by the National Natural Science Foundation of China (Nos. 21904120, 21671179, 21603193, 51902344, 5180021223, U1904213, and U20041102), Project of Central Plains Science and Technology Innovation Leading Talents (No.224200510026), Henan Province Science and Technology programs (Nos. 212102310858, 202102310282, 202102210045, and 202102210260), the Doctoral Scientific Research Foundation of Zhengzhou University of Light Industry (No. 2018BSJJ022).

Publisher Copyright:
Copyright © 2022 Qin, Fu, Zhang, Shao, Qin, Gui, Wang, Guo, Chen, Jiang, Wu, Bikker and Luo.

Funding

This work was supported by the National Natural Science Foundation of China (Nos. 21904120, 21671179, 21603193, 51902344, 5180021223, U1904213, and U20041102), Project of Central Plains Science and Technology Innovation Leading Talents (No.224200510026), Henan Province Science and Technology programs (Nos. 212102310858, 202102310282, 202102210045, and 202102210260), the Doctoral Scientific Research Foundation of Zhengzhou University of Light Industry (No. 2018BSJJ022).

Keywords

bioimaging
biomass
carbon dots
conversion yield
iron ions
sensing

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.3389/fchem.2022.1006389

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title = "Direct preparation of solid carbon dots by pyrolysis of collagen waste and their applications in fluorescent sensing and imaging",

abstract = "The fluorescent carbon dots (CDs) have found their extensive applications in sensing, bioimaging, and photoelectronic devices. In general terms, the synthesis of CDs is straight-forward, though their subsequent purification can be laborious. Therefore, there is a need for easier ways to generate solid CDs with a high conversion yield. Herein, we used collagen waste as a carbon source in producing solid CDs through a calcination procedure without additional chemical decomposition treatment of the raw material. Considering a mass of acid has destroyed the original protein macromolecules into the assembled structure with amino acids and peptide chains in the commercial extraction procedure of collagen product. The residual tissues were assembled with weak intermolecular interactions, which would easily undergo dehydration, polymerization, and carbonization during the heat treatment to produce solid CDs directly. The calcination parameters were surveyed to give the highest conversion yield at 78%, which occurred at 300°C for 2 h. N and S atomic doping CDs (N-CDs and S-CDs) were synthesized at a similar process except for immersion of the collagen waste in sulfuric acid or nitric acid in advance. Further experiments suggested the prepared CDs can serve as an excellent sensor platform for Fe3+ in an acid medium with high anti-interference. The cytotoxicity assays confirmed the biosafety and biocompatibility of the CDs, suggesting potential applications in bioimaging. This work provides a new avenue for preparing solid CDs with high conversion yield.",

keywords = "bioimaging, biomass, carbon dots, conversion yield, iron ions, sensing",

author = "Xiaoyun Qin and Cuicui Fu and Jin Zhang and Wenlong Shao and Xiaomei Qin and Yanghai Gui and Lan Wang and Huishi Guo and Fenghua Chen and Liying Jiang and Gang Wu and Bikker, {Floris J.} and Dan Luo",

note = "Funding Information: This work was supported by the National Natural Science Foundation of China (Nos. 21904120, 21671179, 21603193, 51902344, 5180021223, U1904213, and U20041102), Project of Central Plains Science and Technology Innovation Leading Talents (No.224200510026), Henan Province Science and Technology programs (Nos. 212102310858, 202102310282, 202102210045, and 202102210260), the Doctoral Scientific Research Foundation of Zhengzhou University of Light Industry (No. 2018BSJJ022). Publisher Copyright: Copyright {\textcopyright} 2022 Qin, Fu, Zhang, Shao, Qin, Gui, Wang, Guo, Chen, Jiang, Wu, Bikker and Luo.",

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month = sep,

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doi = "10.3389/fchem.2022.1006389",

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T1 - Direct preparation of solid carbon dots by pyrolysis of collagen waste and their applications in fluorescent sensing and imaging

AU - Qin, Xiaoyun

AU - Fu, Cuicui

AU - Zhang, Jin

AU - Shao, Wenlong

AU - Qin, Xiaomei

AU - Gui, Yanghai

AU - Wang, Lan

AU - Guo, Huishi

AU - Chen, Fenghua

AU - Jiang, Liying

AU - Wu, Gang

AU - Bikker, Floris J.

AU - Luo, Dan

N1 - Funding Information: This work was supported by the National Natural Science Foundation of China (Nos. 21904120, 21671179, 21603193, 51902344, 5180021223, U1904213, and U20041102), Project of Central Plains Science and Technology Innovation Leading Talents (No.224200510026), Henan Province Science and Technology programs (Nos. 212102310858, 202102310282, 202102210045, and 202102210260), the Doctoral Scientific Research Foundation of Zhengzhou University of Light Industry (No. 2018BSJJ022). Publisher Copyright: Copyright © 2022 Qin, Fu, Zhang, Shao, Qin, Gui, Wang, Guo, Chen, Jiang, Wu, Bikker and Luo.

PY - 2022/9/12

Y1 - 2022/9/12

N2 - The fluorescent carbon dots (CDs) have found their extensive applications in sensing, bioimaging, and photoelectronic devices. In general terms, the synthesis of CDs is straight-forward, though their subsequent purification can be laborious. Therefore, there is a need for easier ways to generate solid CDs with a high conversion yield. Herein, we used collagen waste as a carbon source in producing solid CDs through a calcination procedure without additional chemical decomposition treatment of the raw material. Considering a mass of acid has destroyed the original protein macromolecules into the assembled structure with amino acids and peptide chains in the commercial extraction procedure of collagen product. The residual tissues were assembled with weak intermolecular interactions, which would easily undergo dehydration, polymerization, and carbonization during the heat treatment to produce solid CDs directly. The calcination parameters were surveyed to give the highest conversion yield at 78%, which occurred at 300°C for 2 h. N and S atomic doping CDs (N-CDs and S-CDs) were synthesized at a similar process except for immersion of the collagen waste in sulfuric acid or nitric acid in advance. Further experiments suggested the prepared CDs can serve as an excellent sensor platform for Fe3+ in an acid medium with high anti-interference. The cytotoxicity assays confirmed the biosafety and biocompatibility of the CDs, suggesting potential applications in bioimaging. This work provides a new avenue for preparing solid CDs with high conversion yield.

AB - The fluorescent carbon dots (CDs) have found their extensive applications in sensing, bioimaging, and photoelectronic devices. In general terms, the synthesis of CDs is straight-forward, though their subsequent purification can be laborious. Therefore, there is a need for easier ways to generate solid CDs with a high conversion yield. Herein, we used collagen waste as a carbon source in producing solid CDs through a calcination procedure without additional chemical decomposition treatment of the raw material. Considering a mass of acid has destroyed the original protein macromolecules into the assembled structure with amino acids and peptide chains in the commercial extraction procedure of collagen product. The residual tissues were assembled with weak intermolecular interactions, which would easily undergo dehydration, polymerization, and carbonization during the heat treatment to produce solid CDs directly. The calcination parameters were surveyed to give the highest conversion yield at 78%, which occurred at 300°C for 2 h. N and S atomic doping CDs (N-CDs and S-CDs) were synthesized at a similar process except for immersion of the collagen waste in sulfuric acid or nitric acid in advance. Further experiments suggested the prepared CDs can serve as an excellent sensor platform for Fe3+ in an acid medium with high anti-interference. The cytotoxicity assays confirmed the biosafety and biocompatibility of the CDs, suggesting potential applications in bioimaging. This work provides a new avenue for preparing solid CDs with high conversion yield.

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KW - biomass

KW - carbon dots

KW - conversion yield

KW - iron ions

KW - sensing

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Direct preparation of solid carbon dots by pyrolysis of collagen waste and their applications in fluorescent sensing and imaging

Abstract

Bibliographical note

Funding

Keywords

UN SDGs

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