【2021年影響因子/JCR分區:13.273/Q1】《CHEMICAL ENGINEERING JOURNAL》Lotus-leaf-inspired hierarchical structured surface with non-fouling and mechanical bactericidal performances
作者:Rujian Jiang , Lingwan Hao,Lingjie Song , Limei Tian,? , Yong Fan , Jie Zhao,?, Chaozong L
關鍵字:Synergistic antibacterial Mechanical bactericidal Long-term antimicrobial Biomimetic hierarchical structures Lotus leaf surface
論文來源:期刊
發表時間:2020年
Antibiotics, a power tool to combat pathogenic bacterial infection, have experienced their inability to kill drug�resistant bacteria due to the development of antibiotic resistance. As an alternative, nanostructured, mechanical
bactericidal surfaces may hold promise in killing bacteria without triggering antimicrobial resistance; however,
accumulation of dead bacteria would greatly reduce their antimicrobial activity. In this study, for the fifirst time
we report a surprising discovery that the lotus leaf, well known for its superhydrophobicity, has demonstrated
not only strong repelling effffect against bacteria but also bactericidal activity via a cell-rupturing mechanism.
Inspired by this unexpected fifinding, we subsequently designed and prepared a hierarchically structured surface,
which was rendered superhydrophobic (water contact angle: 174°; roll-offff angle: < 1°) upon surface per-
flfluorination. The hierarchically structured surface has displayed remarkable synergistic antimicrobial activity
against Escherichia coli: while the majority of the bacteria (> 99%) were repelled from the surface (non-fouling),
those tenacious bacteria that managed to be in touch of the surface were physically killed completely. Compared
to a conventional superhydrophobic surface (non-fouling to some extent, but no bacteria-killing) or a mechanical
bactericidal surface (bacteria-killing but not bacteria-repelling), our new structured surface has the great ad�vantage in maintaining long-term effffectiveness in antimicrobial activity based entirely on physical mechanism.