Increasing the Hydrophobicity of a PP Film Using a Helium/CF4 DBD Treatment at Atmospheric Pressure

Geyter, Nathalie De; Morent, Rino; Gengembre, L.; Leys, Christophe; Payen, Edmond; Vlierberghe, Sandra Van; Schacht, Etienne

doi:10.1007/s11090-008-9124-4

Cited by 64 publications

(26 citation statements)

References 46 publications

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“…Recently, dielectric barrier discharge (DBD) plasma treatment operated at atmospheric pressure has attracted increasing interests because it offers a more flexible, reliable, less expensive and continuous way in surface modification than conventional low pressure plasma [15][16][17][18][19]. More importantly, up to date, the surface modification of PMMA IOL has not succeed in improving blood compatibility and reducing cells proliferation together.…”

Section: Introductionmentioning

confidence: 99%

Surface Modification of Hydrophobic PMMA Intraocular Lens by the Immobilization of Hydroxyethyl Methacrylate for Improving Application in Ophthalmology

Wei

Liu

Gao

et al. 2011

Plasma Chem Plasma Process

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To improve application of hydrophobic polymethyl methacrylate intraocular lens (PMMA IOL) in a convenient and continuous way, 2-hydroxyethyl methacrylate (HEMA) was immobilized by dielectric barrier discharge plasma at relatively high pressure. The hydrophilicity and topography of the modified IOL surface were comprehensively evaluated by contact angle and atomic force microscopy, while the surface biocompatibility of the modified IOL was investigated by platelets adhesion and cells proliferation experiments. The results revealed that the hydrophilicity of the HEMA-g-PMMA IOL samples were significantly and permanently improved. Less platelets attachment was observed on the modified IOL, especially in the HEMA 2 -g-PMMA IOL group (with 1.65 9 10 -1 mol/L HEMA concentration), which also suppressed the proliferation of cells.

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Section: Introductionmentioning

confidence: 99%

Surface Modification of Hydrophobic PMMA Intraocular Lens by the Immobilization of Hydroxyethyl Methacrylate for Improving Application in Ophthalmology

Wei

Liu

Gao

et al. 2011

Plasma Chem Plasma Process

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“…In the past decades, plasma treatment of polymers has been extensively studied using different types of non-thermal plasmas operating at low or atmospheric pressure [15][16][17][18][19][20][21][22][23][24]. However, nowadays, atmospheric pressure plasma sources [4,5,25,26] are predominantly studied since the polymer industry requires a surface modification technique which can be integrated in a continuous production or finishing line.…”

Section: Introductionmentioning

confidence: 99%

Effect of humid air exposure between successive helium plasma treatments on PET foils

Jacobs¹,

Morent²,

Desmet³

et al. 2010

Surface and Coatings Technology

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“…The Lissajous figure of the microplasma array in water was obtained by measuring the charges across the capacitor (2.0 F) in series to ground and the applied voltage across the discharge device. The Lissajous figure is used to calculate the discharge power (17). Because the optical emission spectra of an atom or molecule contain specific information about the atom or molecule, they can be used to identify the major excited reactive species generated by the N 2 , He, air, or O 2 plasma in water.…”

Section: Methodsmentioning

confidence: 99%

Inactivation of Escherichia coli Cells in Aqueous Solution by Atmospheric-Pressure N ₂ , He, Air, and O ₂ Microplasmas

Zhou

Zhang

et al. 2015

Appl Environ Microbiol

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bAtmospheric-pressure N 2 , He, air, and O 2 microplasma arrays have been used to inactivate Escherichia coli cells suspended in aqueous solution. Measurements show that the efficiency of inactivation of E. coli cells is strongly dependent on the feed gases used, the plasma treatment time, and the discharge power. Compared to atmospheric-pressure N 2 and He microplasma arrays, air and O 2 microplasma arrays may be utilized to more efficiently kill E. coli cells in aqueous solution. The efficiencies of inactivation of E. coli cells in water can be well described by using the chemical reaction rate model, where reactive oxygen species play a crucial role in the inactivation process. Analysis indicates that plasma-generated reactive species can react with E. coli cells in water by direct or indirect interactions.Plasma, called the fourth fundamental state of matter, in addition to solids, liquids, and gases, consists of equal numbers of positive ions and negative electrons (negative ions in some cases) and other reactive species, generally resulting from the ionization of neutral gases. Due to the reactive species in plasma, gas-based reactive plasmas are thought to be effective in killing various microorganisms (1-3). Therefore, recently, the inactivation of microorganisms in water by atmospheric-pressure cold plasmas (APCP) has attracted great attention for biomedical and environmental applications due to their lethal effects on bacteria and fungi (4-8), since APCP include many reactive species similar to those in the conventional methods of microorganism inactivation, such as ozone generation (9), UV irradiation (10), chemical agents (11), electrical fields (12, 13), and microwave irradiation (14).The chemical reaction rates of these plasma-activated species may be improved greatly when atmospheric-pressure nonequilibrium plasmas are generated in water (4-7, 15). These short-lived species can be formed in the vicinity of microorganisms and efficiently kill microorganisms in water. Usually, it is relatively hard to generate stable atmospheric-pressure plasmas in water. Among various plasma sources (4, 5, 7), atmospheric-pressure arc discharge has frequently been used for killing microorganisms in water. Compared to other sources, the strong arc discharges are less influenced by the aqueous environment while obviously leading to an increase in the water temperature with high energy consumption. This arc discharge can also cause serious damage to heat-sensitive materials, and the volume of treated aqueous solution is limited, since the arc plasma is usually controllable only in a small processing space.Previously (16), we designed an atmospheric-pressure air microplasma array to inactivate Pseudomonas fluorescens cells in aqueous media. The microplasma produced by hollow-fiberbased microplasma jets is stable and extremely efficient in killing P. fluorescens cells in aqueous media. This design demonstrates potential application for large-volume plasma inactivation of bacterial cells in water. In this study, we repor...

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Increasing the Hydrophobicity of a PP Film Using a Helium/CF4 DBD Treatment at Atmospheric Pressure

Cited by 64 publications

References 46 publications

Surface Modification of Hydrophobic PMMA Intraocular Lens by the Immobilization of Hydroxyethyl Methacrylate for Improving Application in Ophthalmology

Surface Modification of Hydrophobic PMMA Intraocular Lens by the Immobilization of Hydroxyethyl Methacrylate for Improving Application in Ophthalmology

Effect of humid air exposure between successive helium plasma treatments on PET foils

Inactivation of Escherichia coli Cells in Aqueous Solution by Atmospheric-Pressure N ₂ , He, Air, and O ₂ Microplasmas

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Increasing the Hydrophobicity of a PP Film Using a Helium/CF4 DBD Treatment at Atmospheric Pressure

Cited by 64 publications

References 46 publications

Surface Modification of Hydrophobic PMMA Intraocular Lens by the Immobilization of Hydroxyethyl Methacrylate for Improving Application in Ophthalmology

Surface Modification of Hydrophobic PMMA Intraocular Lens by the Immobilization of Hydroxyethyl Methacrylate for Improving Application in Ophthalmology

Effect of humid air exposure between successive helium plasma treatments on PET foils

Inactivation of Escherichia coli Cells in Aqueous Solution by Atmospheric-Pressure N 2 , He, Air, and O 2 Microplasmas

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Product

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Inactivation of Escherichia coli Cells in Aqueous Solution by Atmospheric-Pressure N ₂ , He, Air, and O ₂ Microplasmas