Topography characterization and initial cellular interaction of plasma-based Ar + beam-treated PDMS surfaces (original) (raw)

Plasma-surface modification of biomaterials

Plasma-surface modification (PSM) is an effective and economical surface treatment technique for many materials and of growing interests in biomedical engineering. This article reviews the various common plasma techniques and experimental methods as applied to biomedical materials research, such as plasma sputtering and etching, plasma implantation, plasma deposition, plasma polymerization, laser plasma deposition, plasma spraying, and so on. The unique advantage of plasma modification is that the surface properties and biocompatibility can be enhanced selectively while the bulk attributes of the materials remain unchanged. Existing materials can, thus, be used and needs for new classes of materials may be obviated thereby shortening the time to develop novel and better biomedical devices. Recent work has spurred a number of very interesting applications in the biomedical field. This review article concentrates upon the current status of these techniques, new applications, and achievements pertaining to biomedical materials research. Examples described include hard tissue replacements, blood contacting prostheses, ophthalmic devices, and other products. #

Plasma Assisted Surface Modification Processes for Biomedical Materials and Devices

This contribution reviews cold plasma processes that are investigated and utilized in academic and technological fields related to Life Sciences, in particular for tailoring surface composition and morphology of materials of different utilization in Medicine and Biology for implants, prostheses, biosensors, devices and scaffolds for tissue engineering. The final goal of the research in this field is, in general, to achieve the capability of driving at will the behaviour (adhesion, growth, morphology, physiology, etc.) of cells and biological tissues in vitro and in vivo at the surface of modified materials. Recent advances on different plasma-processes for biomedical applications, developed in radiofrequency (RF, 13.56 MHz) Glow Discharges at the group of the authors are reported in this review, including: the synthesis of functional surfaces for direct cell growth and biomolecule immobilization; the deposition of non-fouling coatings; the deposition of nano-composite bacterial resi...

PDMS surface modification using atmospheric pressure plasma

2011

We report an experimental study of the surface modification of polydimethylsiloxane (PDMS) by atmospheric pressure plasma (APP). The contact angle of a water droplet, scanning electron microscopy (SEM), and Fourier-transform infrared spectroscopy (FTIR) were used to analyze the modified surface and the hydrophilic stability of PDMS samples, which were mixed with different ratios of base polymer and curing agent. The modified hydrophilic surface of PDMS lasted for 20 days, the duration of our experiment. In FTIR analysis, a broad peak at 3420 cm À1 appeared after plasma treatment for 15 s, which corresponded to hydroxyl group formation on the PDMS surface during plasma treatment. Another new finding is that the magnitude of the peak for PDMS-05, which contained excess curing agent, was the smallest among the PDMS samples. Thus, the plasma treatment modifies the surface of the PDMS by adding hydroxyl groups and the resulting hydrophilic surface depends on the ratio of base polymer to curing agent. Moreover, SEM analysis showed that the bare PDMS-05 sample had a cracked surface, while the bare PDMS-20 was relatively smooth. This cracked or rough topology of the bare PDMS decreased with increased base polymer on reducing amount of curing agent. This improvement in the surface roughness of the plasmatreated samples may be caused by a shallow etching process that occurs during plasma treatment with oxygen gas. It constitutes an effective method for modifying the surface of PDMS without specific skills, expensive apparatus, or clean-room facilities.

Surface Modification of Polymeric Materials by Plasma Treatment

Materials Research, 2002

Low-temperature plasma treatment has been used in the last years as a useful tool to modify the surface properties of different materials, in special of polymers. In the present work low temperature plasma was used to treat the surface of asymmetric porous substrates of polysulfone (PSf) membranes. The main purpose of this work was to study the influence of the exposure time and the power supplied to argon plasma on the permeability properties of the membranes. Three rf power levels, respectively 5, 10 and 15 W were used. Treatment time ranged from 1 to 50 min. Reduction of single gas permeability was observed with Ar plasma treatments at low energy bombardment (5 W) and short exposure time (20 min). Higher power and/or higher plasma exposition time causes a degradation process begins. The chemical and structural characterization of the membranes before and after the surface modification was done by AFM, SEM and XPS.

Treatment of PDMS surfaces using pulsed DBD plasmas: comparing the use of different gases and its influence on adhesion

In this work we present some results of the treatment of polydimethylsiloxane (PDMS) surfaces using pulsed dielectric barrier discharge plasmas. The results of plasma treatment using different gases and mixtures, argon, argon plus water vapor, helium, helium plus water vapor, nitrogen and nitrogen plus water vapor, were compared testing the adhesion between two PDMS samples for each kind of plasma. We also studied the water contact angle in function of plasma process time of PDMS surfaces with each kind of plasma treatment. The plasma was characterized by optical emission spectroscopy (OES) to identify the emitting species and determine the plasma temperatures. The plasma temperature for each process was estimated comparing the spectrum obtained by OES with the spectrum generated by SpecAir simulation code. Measurements of power delivered to the plasmas were also performed. As the results, all the process using different gases show good adhesion efficacy between PDMS samples when long exposure time (larger than 150 seconds) is applied. However, when only a few discharges are applied to PDMS samples the helium plasma process presented best results. Atomic Force Microscopy (AFM) analysis of PDMS samples treated with helium plasma showed reduction in the surface roughness, which increase the surface contact area and improves the adhesion.

I. JUNKAR et al.: PLASMA TREATMENT OF BIOMEDICAL MATERIALS PLASMA TREATMENT OF BIOMEDICAL MATERIALS

2016

Surface plasma treatment techniques for modification of biomedical polymeric materials are presented. The emphasis is on the use of non-equilibrium radiofrequency (RF) oxygen and nitrogen plasma. By variation of discharge parameters (power, discharge frequency, type of gas) and plasma parameters (density of neutrals and ions, kinetic energy of electrons, gas temperature) it is possible to produce polymer surfaces with different surface properties. Already after short plasma treatment time the surface of polymeric material becomes hydrophilic. Formation of nitrogen and oxygen functional groups is observed immediately after plasma treatment. By optimisation of plasma treatment time the number of newly formed functional groups can be increased. Plasma treatment also produces morphological changes of the surface; nanohills of different shapes and height can be formed on PET surface depending on the treatment time and type of gas. Evidently the change in surface morphology affects the ch...

Plasma Modification of Biomaterials Controlled by Surface Analysis

Biomaterials are defined as materials to interact or be in contact with biological systems. This paper describes the fumctionalization of soft polymer surfaces against non-specific protein adsorption. A RF plasma changes the chemical composition of a surface within the nm-range, without changing bulk material properties. The chemical control of the surface is assured by X-ray Photoelectron Spectroscopy (XPS) and contact angle measurements (CAM). NH 3 -H 2 treated Polystyrene (PS) chips are used for enhanced biological-immobilization for sensors. Such biosensors use fluorescence immunoassays in medical diagnostics. Pseudomonas aeruginosa is one of the most prevalent bacterial strains in a clinical environment. Teflon-like films deposited on native PVC are used for the preparation of non-fouling surfaces through the physisorption of PEO-PPO-PEO Pluronics ® co-polymers. Secondly, PEO-like and Ag/PEO-like polymers were prepared by plasma polymerization techniques.

Plasma Treatment of Biomedical Materials

Materiali in tehnologije, 2011

Topography characterization and initial cellular interaction of plasma-based Ar + beam-treated PDMS surfaces (original) (raw)

Related papers