Mehmet Orhan scite author profile

For producing antibacterial textiles, the conventional finishing processes have high productivity and low processing costs, but textiles finished in these ways exhibit low durability against laundering. Therefore, cotton fabrics were bleached with hydrogen peroxide, finished with triclosan, and then treated with polycarboxylic acids such as 1,2,3,4-butanetetracarboxylic acid (BTCA) and citric acid (CA) as crosslinking agents to provide durable antibacterial properties. The surface of fibers treated with BTCA had a greater crosslinked area, and the surfaces of fabrics treated with CA were exposed to greater amounts of deformation due to the mechanical and chemical influences after 50 launderings. The bleaching and finishing treatments did not dramatically affect the breaking strength. However, the polycarboxylic acid treatment (both BTCA and CA) alone showed reductions in the breaking strength when the acid concentration was increased. The polycarboxylic acids were fairly effective against both bacteria, even at lower concentrations, when they were applied to stand-alone cotton fabrics, whereas the antibacterial activity decreased somewhat after the use of polycarboxylic acid and triclosan in the same recipes. Adding polycarboxylic acids to the antibacterial finishing recipes enhanced the durability after 50 launderings, and the durability of the recipes containing BTCA was much higher than that of the recipes containing CA.

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Obtaining medical textiles including microcapsules of the ozonated vegetable oils

Beşen

Balcı

Güneşoğlu

et al. 2017

Fibers Polym

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Improving the Antibacterial Property of Polyethylene Terephthalate by Cold Plasma Treatment

Orhan

Kut

Güneşoğlu

2012

Plasma Chem Plasma Process

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Development of Silver-Based Bactericidal Composite Nanofibers by Airbrushing

Bhullar

Rana

Özsel

et al. 2018

j nanosci nanotechnol

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In this article, we report a simple, cost-effective and eco-friendly method of airbrushing for the fabrication of antibacterial composite nanofibers using Nylon-6 and silver chloride (AgCl). The Nylon-6 is a widely used polymer for various biomedical applications because of its excellent biocompatibility and mechanical properties. Similarly, silver has also been known for their antibacterial, antifungal, antiviral, and anti-inflammatory properties. In order to enhance the antibacterial functionality of the Nylon-6, composite nanofibers in combination with AgCl have been fabricated using airbrush method. The chemical functional groups and morphological studies of the airbrushed Nylon-6/AgCl composite nanofibers were carried out by FTIR and SEM, respectively. The antibacterial activity of airbrushed Nylon-6/AgCl composite nanofibers was evaluated using Gram +ve (Staphylococcus aureus) and Gram -ve (Escherichia coli) bacterial strains. The results showed that the airbrushed Nylon-6/AgCl composite nanofibers have better antibacterial activity against the tested bacterial strains than the airbrushed Nylon-6 nanofibers. Therefore, the airbrushed Nylon-6/AgCl composite nanofibers could be used as a potential antibacterial scaffolding system for tissue engineering and regenerative medicine.

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Preparation of breathable polyurethane membranes with quaternary ammonium salt diols providing durable antibacterial property

Aydın

Demirci

Orhan

et al. 2018

J of Applied Polymer Sci

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Aim of this study was to produce hydrophilic breathable polyurethane membranes providing antibacterial property permanently by incorporation of a quaternary ammonium salt diol (QAS). The study was carried out by synthesis of nine different polyurethanes by solution polymerization through variations of their QAS and isocyanate contents. Fully amorphous membranes at a thickness of~30 μm were produced from the synthesized polymers and their thermal and morphological characteristics were determined. The effect of morphological structures on the membrane water vapor transmission rates (WVTR) and antibacterial properties were correlated. The WVTR increased with the increased temperature in all membranes over 10-40 C, all produced membranes showed water resistance up to a pressure of 2100 cmH2O and WVTR values above 60 g/m 2 h at 30 C. The WVTR increased by increasing amount of QAS including cationic groups and decreased by increasing isocyanate amount reducing the molecular chain flexibility. In addition, while the unmodified membranes did not show any antibacterial activity, the QAS-added membranes provided significant inactivation against Staphylococcus aureus and Escherichia coli of about 104 CFU within 5 h of contact time.

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Mehmet Orhan

Improving the antibacterial activity of cotton fabrics finished with triclosan by the use of 1,2,3,4‐butanetetracarboxylic acid and citric acid

Obtaining medical textiles including microcapsules of the ozonated vegetable oils

Improving the Antibacterial Property of Polyethylene Terephthalate by Cold Plasma Treatment

Development of Silver-Based Bactericidal Composite Nanofibers by Airbrushing

Preparation of breathable polyurethane membranes with quaternary ammonium salt diols providing durable antibacterial property

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