研究成果汇总

纳米银/聚乳酸(Ag/PLLA)多孔膜的抗细菌粘附性质研究

2012-08-09 江筱莉 点击:[]

通常,表面粗糙度的增加会诱导细菌的吸附,但是在含有纳米银的多孔聚合物表面上,细菌的吸附得到了有效的抑制。我们在试验中采用了金葡菌和大肠杆菌,对这两种不同种属和形状的细菌,Ag/PLLA多孔结构都显示了很好的抗粘附能力,对大肠杆菌的效应尤为显著。多孔结构对纳米银的抗菌效率有较大的提升作用。多孔结构增大了纳米银与水环境的接触面积,从而促进了银离子的释放,同时这种孔洞结构有利于银离子在材料表面的富集,防止其扩散或被流动的水环境带走,因此将对吸附在表面的细菌具有更强的杀伤效率。同时细胞毒性试验表明,Ag/PLLA多孔结构的表面并不会对细胞产生毒性,是一种安全的生物材料。

通过BF法制备的纳米银/聚合物多孔膜,提供了一种简单,易控制的方法,改变生物材料的表面性质,使材料成为具有利于细胞生长,并兼具抗菌性的多功能材料。通过BF法和纳米银的界面效应,可以调控该复合膜的多种表面性质,如多孔膜的孔洞大小,膜的厚度,也可以通过调控纳米银的表面性质得到多功能的材料表面。

Xiaoli Jiang, Tianzhu Zhang, Shiying He, Jingjing Ling, Ning Gu, Yu Zhang, Xuefeng Zhou, Xing Wang, and Lu Cheng.Bacterial Adhesion on Honeycomb-Structured Poly(L-Lactic Acid) Surface with Ag Nanoparticles.J. Biomed. Nanotechnol. 8, 791-799 (2012)

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Fig. 1. (A) TEM image of Ag nanoparticles-impregnated PLLA and (inset) the size distribution of Ag nanoparticles. (B) Darkfield microscopy image of flat Ag/PLLA film cast at 30% RH. The plasmon resonant colors indicate the presence of Ag nanoparticles. (C) Optical microscope image and (D) darkfield image of honeycomb-patterned Ag/PLLA film cast at 90% RH.

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Fig. 3. Amount of Ag+ released from flat and honeycomb-structured Ag/PLLA films in deionized water as a function of time.

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Fig. 4. Histograms of bacterial adhesion degree for PLLA and Ag/PLLA films after 24 h incubation against two microorganisms.

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Fig. 5. SEM images of (A, B, C) S. aureus and (D, E, F) E. coli adhesion on (A, D) flat PLLA films, (B, E) flat Ag/PLLA films, and (C, F) honeycomb-structured Ag/PLLA films after 24 h of culture, respectively.

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Fig. 6. Cross-sectional schematic diagram of the adhesion behavior of bacteria on (A) flat or (B) honeycomb-structured Ag/PLLA films. Cross-sectional SEM images of S. aureus adhesion on (C) flat or (D) honeycomb-structured Ag/PLLA films after 24 h of culture.