Bella H. Neufeld scite author profile

In the present study, a new copper metal-organic framework (MOF)-cotton material was strategically fabricated to exploit its antibacterial properties for postsynthetic 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(NHBTC) was synthesized into a homogenous surface-supported film via a layer-by-layer dip-coating process. The resultant materials contained uniformly distributed 1 μm × 1 μm 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 Cu ion-releasing performance of the materials was probed under biological conditions per submersion in complex media at 37 °C. Indeed, PSM induces a change in the copper flux of the material over the first 6 h. The materials continue to slowly release Cu ions beyond 24 h tested at a flux of 0.22 ± 0.003 μmol·cm·h with the unmodified MOF-cotton and at 0.25 ± 0.004 μmol·cm·h 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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Metal–Organic Framework Material Inhibits Biofilm Formation of Pseudomonas aeruginosa

Neufeld

Lutzke

et al. 2017

Adv Funct Materials

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An 85% reduction in the bacterial attachment of Pseudomonas aeruginosa is achieved using a water‐stable metal–organic framework (MOF) blended with chitosan. These materials demonstrate this reduction in bacterial adhesion in the first 6 h and maintain it over the full 24 h exposure period, a remarkable impediment of biofilm formation to achieve, given the strength of this bacteria strain. The films elicit the same inhibitory effect after a second round of experiments, suggesting reusability of the materials. Characterization of the films by powder X‐ray diffraction, attenuated total reflectance‐IR, and scanning electron microscopy supports retention of the MOF structure within the chitosan matrix. The extensive control experiments employed in this study isolate the observed biological effects to the synthesized films, and not to possible leachates from the films. This presents the first account of using a water‐stable MOF within a polymer as a means to achieve an antibacterial surface by demonstrating an 85% reduction in bacterial attachment of Pseudomonas aeruginosa.

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Nitric oxide-releasing S-nitrosated derivatives of chitin and chitosan for biomedical applications

et al. 2014

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Critical nitric oxide concentration for Pseudomonas aeruginosa biofilm reduction on polyurethane substrates

Neufeld

Reynolds

2016

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Bacterial colonies that reside on a surface, known as biofilms, are intrinsically impenetrable to traditional antibiotics, ultimately driving research toward an alternative therapeutic approach. Nitric oxide (NO) has gained attention for its biologically beneficial properties, particularly centered around its antibacterial capabilities. NO donors that can release the molecule under physiological conditions (such as S-nitrosothiols) can be utilized in clinical settings to combat bacterial biofilm infections. Herein the authors describe determining a critical concentration of NO necessary to cause >90% reduction of a Pseudomonas aeruginosa biofilm grown on medical grade polyurethane films. The biofilm was grown under optimal culture conditions [in nutrient broth media (NBM) at 37 °C] for 24 h before the addition of the NO donor S-nitrosoglutathione (GSNO) in NBM for an additional 24 h. The cellular viability of the biofilm after the challenge period was tested using varying concentrations of NO to determine the critical amount necessary to cause at least a 90% reduction in bacterial biofilm viability. The critical GSNO concentration was found to be 10 mM, which corresponds to 2.73 mM NO. Time kill experiments were performed on the 24 h biofilm using the critical amount of NO at 4, 8, 12, and 16 h and it was determined that the 90% biofilm viability reduction occurred at 12 h and was sustained for the entire 24 h challenge period. This critical concentration was subsequently tested for total NO release via a nitric oxide analyzer. The total amount of NO released over the 12 h challenge period was found to be 5.97 ± 0.66 × 10(-6) mol NO, which corresponds to 1.49 ± 0.17 μmol NO/ml NBM. This is the first identification of the critical NO concentration needed to elicit this biological response on a medically relevant polymer.

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Small Molecule Interferences in Resazurin and MTT-Based Metabolic Assays in the Absence of Cells

et al. 2018

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In vitro assays (such as resazurin and MTT) provide an opportunity to determine the cytotoxicity of novel therapeutics before moving forward with expensive and resource-intensive in vivo studies. A concern with using these assays, however, is the production of false responses in the presence of particular chemical functionalities. To better understand this phenomenon, 19 small molecules at 6 concentrations (1 μM-100 mM) were tested in the presence of resazurin and MTT reagents to highlight potential interfering species. Through the use of absorbance measurements (using well-plate assays and UV-vis spectroscopy) with parallel MS analysis, we have shown that significant conversion of the assay reagents readily occurs in the presence of many tested interfering species without the need for any cellular activity. The most attributable sources of interference seem to arise from the presence of thiol and carboxylic acid moieties. Interestingly, the detectable interferences were more prevalent and larger in the presence of MTT (19 species with some deviations >3000%) compared to resazurin (16 species with largest deviation of ∼150%). Additionally, those deviations in the presence of resazurin were only substantial at high concentrations, while MTT showed deviations across the tested concentrations. This comprehensive study gives insight into chemical functional groups (thiols, amines, amides, carboxylic acids) that may interfere with resazurin and MTT assays in the absence of metabolic activity and indicates that proper control studies must be performed to obtain accurate data from these in vitro assays.

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Bella H. Neufeld

Surface-Anchored Metal–Organic Framework–Cotton Material for Tunable Antibacterial Copper Delivery

Metal–Organic Framework Material Inhibits Biofilm Formation of Pseudomonas aeruginosa

Nitric oxide-releasing S-nitrosated derivatives of chitin and chitosan for biomedical applications

Critical nitric oxide concentration for Pseudomonas aeruginosa biofilm reduction on polyurethane substrates

Small Molecule Interferences in Resazurin and MTT-Based Metabolic Assays in the Absence of Cells

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