Rolled-Up Monolayer Graphene Tubular Micromotors: Enhanced Performance and Antibacterial Property

被引:25
|
作者
Zhang, Biran [1 ]
Huang, Gaoshan [1 ]
Wang, Lu [1 ]
Wang, Tianbo [2 ]
Liu, Lu [3 ,4 ]
Di, Zengfeng [2 ]
Liu, Xuanyong [3 ]
Mei, Yongfeng [1 ]
机构
[1] Fudan Univ, State Key Lab ASIC & Syst, Dept Mat Sci, Shanghai 200433, Peoples R China
[2] Chinese Acad Sci, Shanghai Inst Microsyst & Technol, State Key Lab Funct Mat Informat, Shanghai 200050, Peoples R China
[3] Chinese Acad Sci, Shanghai Inst Ceram, State Key Lab High Performance Ceram & Superfine, Shanghai 200050, Peoples R China
[4] Shanghai Normal Univ, Key Lab Mol Imaging Probes & Sensors, Shanghai Key Lab Rare Earth Funct Mat,Minist Educ, State Key Lab Resource Chem,Shanghai Municipal Ed, Shanghai 200234, Peoples R China
来源
CHEMISTRY-AN ASIAN JOURNAL | 2019年 / 14卷 / 14期
关键词
antibacterial property; catalytic motion; graphene; hydrophobic effect; micromotors; TEMPLATE ELECTROSYNTHESIS; PROPULSION; OXIDE; NANOMATERIALS; FABRICATION; NANOMOTORS; MICROBOTS; DELIVERY; ENGINES; MOTION;
D O I
10.1002/asia.201900301
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
The motion of catalytic tubular micromotors are driven by the oxygen bubbles generated from chemical reaction and is influenced by the resistance from the liquid environment. Herein, we fabricated a rolled-up graphene tubular micromotor, in which the graphene layer was adopted as the outmost surface. Due to the hydrophobic property of the graphene layer, the fabricated micromotor performed a motion pattern that could escape from the attraction from the bubbles. In addition, Escherichia coli and Staphylococcus culture experiments proved that the graphene outer surface displays antibacterial property. Considering the bubble-avoiding and antibacterial properties, the rolled-up graphene tubular micromotor holds great potential for various applications such as in vivo drug delivery and biosensors.
引用
收藏
页码:2479 / 2484
页数:6
相关论文
共 50 条
  • [1] Catalytic/magnetic assemblies of rolled-up tubular nanomembrane-based micromotors
    Naeem, Sumayyah
    Mujtaba, Jawayria
    Naeem, Farah
    Xu, Kailiang
    Huang, Gaoshan
    Solovev, Alexander A.
    Zhang, Jing
    Mei, Yongfeng
    RSC ADVANCES, 2020, 10 (60) : 36526 - 36530
  • [2] Architecting Graphene Oxide Rolled-Up Micromotors: A Simple Paper-Based Manufacturing Technology
    Baptista-Pires, Luis
    Orozco, Jahir
    Guardia, Pablo
    Merkoci, Arben
    SMALL, 2018, 14 (03)
  • [3] Exceptional points in rolled-up tubular microcavities
    Fang, Yangfu
    Li, Shilong
    Kiravittaya, Suwit
    Mei, Yongfeng
    JOURNAL OF OPTICS, 2017, 19 (09)
  • [4] Magnetic and meniscus-effect control of catalytic rolled-up micromotors
    Li, Jin-Xing
    Lu, Bing-Rui
    Shen, Zhenkui
    Xu, Zhencheng
    Li, Hui
    Wen, Juanjuan
    Li, Zhidong
    Qu, Xin-Ping
    Chen, Yi-fang
    Mei, Yongfeng
    Liu, Ran
    MICROELECTRONIC ENGINEERING, 2011, 88 (08) : 1792 - 1794
  • [5] Electromagnetic wave propagation in a rolled-up tubular microcavity
    Huang, Gaoshan
    Mei, Yongfeng
    JOURNAL OF MATERIALS CHEMISTRY C, 2017, 5 (11) : 2758 - 2770
  • [6] Exceptional transport property in a rolled-up germanium tube
    Guo, Qinglei
    Wang, Gang
    Chen, Da
    Li, Gongjin
    Huang, Gaoshan
    Zhang, Miao
    Wang, Xi
    Mei, Yongfeng
    Di, Zengfeng
    APPLIED PHYSICS LETTERS, 2017, 110 (11)
  • [7] Tubular optical microcavities based on rolled-up photonic crystals
    Briche, Remi
    Benamrouche, Aziz
    Cremillieu, Pierre
    Regreny, Philippe
    Leclercq, Jean-Louis
    Letartre, Xavier
    Danescu, Alexandre
    Callard, Segolene
    APL PHOTONICS, 2020, 5 (10)
  • [8] Optical properties of rolled-up tubular microcavities from shaped nanomembranes
    Huang, G. S.
    Kiravittaya, S.
    Quinones, V. A. Bolanos
    Ding, F.
    Benyoucef, M.
    Rastelli, A.
    Mei, Y. F.
    Schmidt, O. G.
    APPLIED PHYSICS LETTERS, 2009, 94 (14)
  • [9] Infrared tubular microcavity based on rolled-up GeSn/Ge nanomembranes
    Wu, Xiang
    Tian, Ziao
    Cong, Hui
    Wang, Yang
    Edy, Riyanto
    Huang, Gaoshan
    Di, Zengfeng
    Xue, Chunlai
    Mei, Yongfeng
    NANOTECHNOLOGY, 2018, 29 (42)
  • [10] Realization of uniaxially strained, rolled-up monolayer CVD graphene on a Si platform via heteroepitaxial InGaAs/GaAs bilayers
    Mao, Guoming
    Wang, Qi
    Chai, Zhaoer
    Liu, Hao
    Liu, Kai
    Ren, Xiaomin
    RSC ADVANCES, 2017, 7 (24): : 14481 - 14486
12345