Laser-induced freestanding graphene with porous nanostructure for antimicrobial devices and inhibition of microbial fouling

Dejian Liang; Dan Wang; Guantao Wang; Mingguang Han; Weixiong Yang; Zhixiao Liu; Sida Luo

doi:10.1117/12.3009480

Laser-induced freestanding graphene with porous nanostructure for antimicrobial devices and inhibition of microbial fouling

Dejian Liang
, Dan Wang
, Guantao Wang
, Mingguang Han
, Weixiong Yang
, Zhixiao Liu
, Sida Luo^*

^*此作品的通讯作者

机械工程及自动化学院

Beijing Xinghang Electromechanical Equipment Co., Ltd.
Beihang University

科研成果: 书/报告/会议事项章节 › 会议稿件 › 同行评审

摘要

Laser-induced graphene (LIG) is a novel strategy for preparing graphene by taking advantage of the sufficient photothermal and photochemical reactions to develop nanomaterials with good physical and chemical properties. Recently, considerable research is devoted to efficiently prepare graphene antimicrobial devices taking advantage of the size and shape customizability of laser processing. However, the relationship between quantification of reduction rate and graphene nanostructure porosity has not been systematically studied. Hence, in this paper we applied a simple and efficient method to prepare graphene antibacterial paper by in situ reduction of polyimide in one step by exploiting the absorption of laser photon energy by the chemical bonds in the precursor material. And we further clarified the antibacterial mechanism of laser-induced graphene paper (LIGP) with the aim of achieving better antimicrobial performance by microstructure modulation through laser processing parameters. Microscopic analyses and colony counting assay were employed to demonstrate the antibacterial effect of graphene. Notably, LIGP at 1.0W laser power (LIGP-1.0W) exhibits the most significant bactericidal rate (94.1% for E. coli and 97.5% for S. aureus) attributed to its extremely high specific surface area (SSA, 189.3 m2 /g), the unique tunable nonporous structure increases extensive contact area with bacteria to provide more sites for capturing bacteria, which was further verified by oxidative stress-related mechanism. The prepared LIGP device can be used to prevent aluminum biocorrosion on material surface and used as antibacterial devices which can be customized to match diverse application scenarios.

源语言	英语
主期刊名	Eighth Asia Pacific Conference on Optics Manufacture and Third International Forum of Young Scientists on Advanced Optical Manufacturing, APCOM and YSAOM 2023
编辑	Xuejun Zhang, Xiaoyong Wang, Yifan Dai, Lingbao Kong, Dawei Zhang, Feng Gong, Lihua Li
出版商	SPIE
ISBN（电子版）	9781510672673
DOI	https://doi.org/10.1117/12.3009480
出版状态	已出版 - 2023
活动	8th Asia Pacific Conference on Optics Manufacture, APCOM 2023 and 3rd International Forum of Young Scientists on Advanced Optical Manufacturing, YSAOM 2023 - Shenzhen, 中国期限: 4 8月 2023 → 6 8月 2023

出版系列

姓名	Proceedings of SPIE - The International Society for Optical Engineering
卷	12976
ISSN（印刷版）	0277-786X
ISSN（电子版）	1996-756X

会议

会议	8th Asia Pacific Conference on Optics Manufacture, APCOM 2023 and 3rd International Forum of Young Scientists on Advanced Optical Manufacturing, YSAOM 2023
国家/地区	中国
市	Shenzhen
时期	4/08/23 → 6/08/23

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10.1117/12.3009480

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引用此

Liang, D., Wang, D., Wang, G., Han, M., Yang, W., Liu, Z., & Luo, S. (2023). Laser-induced freestanding graphene with porous nanostructure for antimicrobial devices and inhibition of microbial fouling. 在 X. Zhang, X. Wang, Y. Dai, L. Kong, D. Zhang, F. Gong, & L. Li (编辑), Eighth Asia Pacific Conference on Optics Manufacture and Third International Forum of Young Scientists on Advanced Optical Manufacturing, APCOM and YSAOM 2023 文章 129761O (Proceedings of SPIE - The International Society for Optical Engineering; 卷 12976). SPIE. https://doi.org/10.1117/12.3009480

Liang, Dejian ; Wang, Dan ; Wang, Guantao 等. / Laser-induced freestanding graphene with porous nanostructure for antimicrobial devices and inhibition of microbial fouling. Eighth Asia Pacific Conference on Optics Manufacture and Third International Forum of Young Scientists on Advanced Optical Manufacturing, APCOM and YSAOM 2023. 编辑 / Xuejun Zhang ; Xiaoyong Wang ; Yifan Dai ; Lingbao Kong ; Dawei Zhang ; Feng Gong ; Lihua Li. SPIE, 2023. (Proceedings of SPIE - The International Society for Optical Engineering).

@inproceedings{aac5ce38e3424ae3b081fe6c954a9c49,

title = "Laser-induced freestanding graphene with porous nanostructure for antimicrobial devices and inhibition of microbial fouling",

abstract = "Laser-induced graphene (LIG) is a novel strategy for preparing graphene by taking advantage of the sufficient photothermal and photochemical reactions to develop nanomaterials with good physical and chemical properties. Recently, considerable research is devoted to efficiently prepare graphene antimicrobial devices taking advantage of the size and shape customizability of laser processing. However, the relationship between quantification of reduction rate and graphene nanostructure porosity has not been systematically studied. Hence, in this paper we applied a simple and efficient method to prepare graphene antibacterial paper by in situ reduction of polyimide in one step by exploiting the absorption of laser photon energy by the chemical bonds in the precursor material. And we further clarified the antibacterial mechanism of laser-induced graphene paper (LIGP) with the aim of achieving better antimicrobial performance by microstructure modulation through laser processing parameters. Microscopic analyses and colony counting assay were employed to demonstrate the antibacterial effect of graphene. Notably, LIGP at 1.0W laser power (LIGP-1.0W) exhibits the most significant bactericidal rate (94.1\% for E. coli and 97.5\% for S. aureus) attributed to its extremely high specific surface area (SSA, 189.3 m2 /g), the unique tunable nonporous structure increases extensive contact area with bacteria to provide more sites for capturing bacteria, which was further verified by oxidative stress-related mechanism. The prepared LIGP device can be used to prevent aluminum biocorrosion on material surface and used as antibacterial devices which can be customized to match diverse application scenarios.",

keywords = "Aluminum biocorrosion, Antimicrobial devices, Antimicrobial performance, Graphene antibacterial paper, Laser-induced graphene, Microstructure modulation, Nanostructure porosity",

author = "Dejian Liang and Dan Wang and Guantao Wang and Mingguang Han and Weixiong Yang and Zhixiao Liu and Sida Luo",

note = "Publisher Copyright: {\textcopyright} COPYRIGHT SPIE. Downloading of the abstract is permitted for personal use only.; 8th Asia Pacific Conference on Optics Manufacture, APCOM 2023 and 3rd International Forum of Young Scientists on Advanced Optical Manufacturing, YSAOM 2023 ; Conference date: 04-08-2023 Through 06-08-2023",

year = "2023",

doi = "10.1117/12.3009480",

language = "英语",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Xuejun Zhang and Xiaoyong Wang and Yifan Dai and Lingbao Kong and Dawei Zhang and Feng Gong and Lihua Li",

booktitle = "Eighth Asia Pacific Conference on Optics Manufacture and Third International Forum of Young Scientists on Advanced Optical Manufacturing, APCOM and YSAOM 2023",

address = "美国",

}

Liang, D, Wang, D, Wang, G, Han, M, Yang, W, Liu, Z & Luo, S 2023, Laser-induced freestanding graphene with porous nanostructure for antimicrobial devices and inhibition of microbial fouling. 在 X Zhang, X Wang, Y Dai, L Kong, D Zhang, F Gong & L Li (编辑), Eighth Asia Pacific Conference on Optics Manufacture and Third International Forum of Young Scientists on Advanced Optical Manufacturing, APCOM and YSAOM 2023., 129761O, Proceedings of SPIE - The International Society for Optical Engineering, 卷 12976, SPIE, 8th Asia Pacific Conference on Optics Manufacture, APCOM 2023 and 3rd International Forum of Young Scientists on Advanced Optical Manufacturing, YSAOM 2023, Shenzhen, 中国, 4/08/23. https://doi.org/10.1117/12.3009480

Laser-induced freestanding graphene with porous nanostructure for antimicrobial devices and inhibition of microbial fouling. / Liang, Dejian; Wang, Dan; Wang, Guantao 等.
Eighth Asia Pacific Conference on Optics Manufacture and Third International Forum of Young Scientists on Advanced Optical Manufacturing, APCOM and YSAOM 2023. 编辑 / Xuejun Zhang; Xiaoyong Wang; Yifan Dai; Lingbao Kong; Dawei Zhang; Feng Gong; Lihua Li. SPIE, 2023. 129761O (Proceedings of SPIE - The International Society for Optical Engineering; 卷 12976).

科研成果: 书/报告/会议事项章节 › 会议稿件 › 同行评审

TY - GEN

T1 - Laser-induced freestanding graphene with porous nanostructure for antimicrobial devices and inhibition of microbial fouling

AU - Liang, Dejian

AU - Wang, Dan

AU - Wang, Guantao

AU - Han, Mingguang

AU - Yang, Weixiong

AU - Liu, Zhixiao

AU - Luo, Sida

N1 - Publisher Copyright: © COPYRIGHT SPIE. Downloading of the abstract is permitted for personal use only.

PY - 2023

Y1 - 2023

N2 - Laser-induced graphene (LIG) is a novel strategy for preparing graphene by taking advantage of the sufficient photothermal and photochemical reactions to develop nanomaterials with good physical and chemical properties. Recently, considerable research is devoted to efficiently prepare graphene antimicrobial devices taking advantage of the size and shape customizability of laser processing. However, the relationship between quantification of reduction rate and graphene nanostructure porosity has not been systematically studied. Hence, in this paper we applied a simple and efficient method to prepare graphene antibacterial paper by in situ reduction of polyimide in one step by exploiting the absorption of laser photon energy by the chemical bonds in the precursor material. And we further clarified the antibacterial mechanism of laser-induced graphene paper (LIGP) with the aim of achieving better antimicrobial performance by microstructure modulation through laser processing parameters. Microscopic analyses and colony counting assay were employed to demonstrate the antibacterial effect of graphene. Notably, LIGP at 1.0W laser power (LIGP-1.0W) exhibits the most significant bactericidal rate (94.1% for E. coli and 97.5% for S. aureus) attributed to its extremely high specific surface area (SSA, 189.3 m2 /g), the unique tunable nonporous structure increases extensive contact area with bacteria to provide more sites for capturing bacteria, which was further verified by oxidative stress-related mechanism. The prepared LIGP device can be used to prevent aluminum biocorrosion on material surface and used as antibacterial devices which can be customized to match diverse application scenarios.

AB - Laser-induced graphene (LIG) is a novel strategy for preparing graphene by taking advantage of the sufficient photothermal and photochemical reactions to develop nanomaterials with good physical and chemical properties. Recently, considerable research is devoted to efficiently prepare graphene antimicrobial devices taking advantage of the size and shape customizability of laser processing. However, the relationship between quantification of reduction rate and graphene nanostructure porosity has not been systematically studied. Hence, in this paper we applied a simple and efficient method to prepare graphene antibacterial paper by in situ reduction of polyimide in one step by exploiting the absorption of laser photon energy by the chemical bonds in the precursor material. And we further clarified the antibacterial mechanism of laser-induced graphene paper (LIGP) with the aim of achieving better antimicrobial performance by microstructure modulation through laser processing parameters. Microscopic analyses and colony counting assay were employed to demonstrate the antibacterial effect of graphene. Notably, LIGP at 1.0W laser power (LIGP-1.0W) exhibits the most significant bactericidal rate (94.1% for E. coli and 97.5% for S. aureus) attributed to its extremely high specific surface area (SSA, 189.3 m2 /g), the unique tunable nonporous structure increases extensive contact area with bacteria to provide more sites for capturing bacteria, which was further verified by oxidative stress-related mechanism. The prepared LIGP device can be used to prevent aluminum biocorrosion on material surface and used as antibacterial devices which can be customized to match diverse application scenarios.

KW - Aluminum biocorrosion

KW - Antimicrobial devices

KW - Antimicrobial performance

KW - Graphene antibacterial paper

KW - Laser-induced graphene

KW - Microstructure modulation

KW - Nanostructure porosity

UR - https://www.scopus.com/pages/publications/85182394723

U2 - 10.1117/12.3009480

DO - 10.1117/12.3009480

M3 - 会议稿件

AN - SCOPUS:85182394723

T3 - Proceedings of SPIE - The International Society for Optical Engineering

BT - Eighth Asia Pacific Conference on Optics Manufacture and Third International Forum of Young Scientists on Advanced Optical Manufacturing, APCOM and YSAOM 2023

A2 - Zhang, Xuejun

A2 - Wang, Xiaoyong

A2 - Dai, Yifan

A2 - Kong, Lingbao

A2 - Zhang, Dawei

A2 - Gong, Feng

A2 - Li, Lihua

PB - SPIE

T2 - 8th Asia Pacific Conference on Optics Manufacture, APCOM 2023 and 3rd International Forum of Young Scientists on Advanced Optical Manufacturing, YSAOM 2023

Y2 - 4 August 2023 through 6 August 2023

ER -

Liang D, Wang D, Wang G, Han M, Yang W, Liu Z 等. Laser-induced freestanding graphene with porous nanostructure for antimicrobial devices and inhibition of microbial fouling. 在 Zhang X, Wang X, Dai Y, Kong L, Zhang D, Gong F, Li L, 编辑, Eighth Asia Pacific Conference on Optics Manufacture and Third International Forum of Young Scientists on Advanced Optical Manufacturing, APCOM and YSAOM 2023. SPIE. 2023. 129761O. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.3009480

Laser-induced freestanding graphene with porous nanostructure for antimicrobial devices and inhibition of microbial fouling

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