石墨烯的疏水性作为抑制致病细菌和真菌生物膜形成的驱动力。

Hydrophobicity of graphene as a driving force for inhibiting biofilm formation of pathogenic bacteria and fungi.

机构信息

Faculty of Dentistry, National University of Singapore, Singapore.

Graphene and Nanomaterials Research Centre, MackGraphe, Mackenzie Presbyterian University, Brazil.

出版信息

Dent Mater. 2019 Mar;35(3):403-413. doi: 10.1016/j.dental.2018.09.016. Epub 2019 Jan 21.

DOI:10.1016/j.dental.2018.09.016

PMID:30679015

Abstract

OBJECTIVE

To evaluate the surface and wettability characteristics and the microbial biofilm interaction of graphene coating on titanium.

METHODS

Graphene was deposited on titanium (Control) via a liquid-free technique. The transfer was performed once (TiGS), repeated two (TiGD) and five times (TiGV) and characterized by AFM (n=10), Raman spectroscopy (n=10), contact angle and SFE (n=5). Biofilm formation (n=3) to Streptococcus mutans, Enterococcus faecalis, Pseudomonas aeruginosa and Candida albicans was evaluated after 24h by CV assay, CFU, XTT and confocal microscopy. Statistics were performed by one-way Anova, Tukey's tests and Pearson's correlation analysis at a pre-set significance level of 5 %.

RESULTS

Raman mappings revealed coverage yield of 82 % for TiGS and ≥99 % for TiGD and TiGV. Both TiGD and TiGV presented FWHM>44cm and I/I ratio<0.12, indicating multiple graphene layers and occlusion of defects. The contact angle was significantly higher for TiGD and TiGV (110° and 117°) comparing to the Control (70°). The SFE was lower for TiGD (13.8mN/m) and TiGV (12.1mN/m) comparing to Control (38.3mN/m). TiGD was selected for biofilm assays and exhibited significant reduction in biofilm formation for all microorganisms compared to Control. There were statistical correlations between the high contact angle and low SFE of TiGD and decreased biofilm formation.

SIGNIFICANCE

TiGD presented high quality and coverage and decreased biofilm formation for all species. The increased hydrophobicity of graphene films was correlated with the decreased biofilm formation for various species.

摘要

目的

评估石墨烯涂层在钛上的表面和润湿性特性以及微生物生物膜相互作用。

方法

通过无液技术将石墨烯沉积在钛上（对照）。转移进行了一次（TiGS）、两次（TiGD）和五次（TiGV），并通过 AFM（n=10）、拉曼光谱（n=10）、接触角和 SFE（n=5）进行了表征。在 24 小时后，通过 CV 测定、CFU、XTT 和共聚焦显微镜评估了变形链球菌、粪肠球菌、铜绿假单胞菌和白色念珠菌的生物膜形成（n=3）。在设定的 5%显著水平下，通过单向方差分析、Tukey 检验和 Pearson 相关分析进行统计。

结果

拉曼映射显示 TiGS 的覆盖率为 82%，TiGD 和 TiGV 的覆盖率均≥99%。TiGD 和 TiGV 均呈现 FWHM>44cm 和 I/I 比值<0.12，表明存在多层石墨烯和缺陷的闭塞。与对照（70°）相比，TiGD 和 TiGV 的接触角明显更高（110°和 117°）。与对照（38.3mN/m）相比，TiGD（13.8mN/m）和 TiGV（12.1mN/m）的 SFE 较低。选择 TiGD 进行生物膜测定，与对照相比，所有微生物的生物膜形成均显著减少。TiGD 的高接触角和低 SFE 与生物膜形成减少之间存在统计学相关性。

意义

TiGD 表现出高质量和高覆盖率，并降低了所有物种的生物膜形成。石墨烯膜的疏水性增加与各种物种的生物膜形成减少相关。

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石墨烯的疏水性作为抑制致病细菌和真菌生物膜形成的驱动力。

Hydrophobicity of graphene as a driving force for inhibiting biofilm formation of pathogenic bacteria and fungi.

机构信息

出版信息

OBJECTIVE

METHODS

RESULTS

SIGNIFICANCE

目的

方法

结果

意义

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