期刊
ACS APPLIED MATERIALS & INTERFACES
卷 10, 期 17, 页码 15189-15199出版社
AMER CHEMICAL SOC
DOI: 10.1021/acsami.7b19455
关键词
metal-organic frameworks; post-synthetic modification; tunability; cotton; antibacterial agent; antibacterial surface
资金
- National Science Foundation Division of Biomaterials [DMR-1352201]
- National Institutes of Health [1R21EB016838-021]
- NATIONAL INSTITUTE OF BIOMEDICAL IMAGING AND BIOENGINEERING [R21EB016838] Funding Source: NIH RePORTER
In the present study, a new copper metal organic framework (MOF)-cotton material was strategically fabricated to exploit its antibacterial properties for post-synthetic modification (PSM) to introduce a free amine to tune the physicochemical properties of the material. A modified methodology for carboxymethylation of natural cotton was utilized to enhance the number of nucleation sites for the MOF growth. Subsequently, MOF Cu-3(NH2BTC)(2) was synthesized into a homogenous surface-supported film via a layer-by-layer dip-coating process. The resultant materials contained uniformly distributed 1 mu m x 1 mu m octahedral MOF crystals around each carboxymethylated fiber. Importantly, the accessible free amine of the MOF ligand allowed for the PSM of the MOF cotton surface with valeric anhydride, yielding 23.5 +/- 2.2% modified. The Cu2+ ion-releasing performance of the materials was probed under biological conditions per submersion in complex media at 37 degrees C. Indeed, PSM induces a change in the copper flux of the material over the first 6 h. The materials continue to slowly release Cu2+ ions beyond 24 h tested at a flux of 0.22 +/- 0.003 mu mol.cm(-2)-h(-1) with the unmodified MOF-cotton and at 0.25 +/- 0.004 mu mol.cm(-2)-h(-1) with the modified MOF-cotton. The antibacterial activity of the material was explored using Escherichia coli by testing the planktonic and attached bacteria under a variety of conditions. MOF-cotton materials elicit antibacterial effects, yielding a 4-log reduction or greater, after 24 h of exposure. Additionally, the MOF-cotton materials inhibit the attachment of bacteria, under both dry and wet conditions. A material of this type would be ideal for clothing, bandages, and other textile applications. As such, this work serves as a precedence toward developing uniform, tunable MOF-composite textile materials that can kill bacteria and prevent the attachment of bacteria to the surface.
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