Physico-chemical and biological evaluation of excimer laser irradiated polyethylene terephthalate (pet) surfaces.

The aim of this work was to investigate the consequences of excimer laser irradiation on the physico-chemical and biological properties of polyethylene terephthalate (PET) films, currently used for medical devices. Three PET films from different origins were studied in the present work, chosen with respect to their chemical and physical properties, which are of high importance for ulterior medical application as vascular prostheses. Multiple assays were carried out to characterize the physical and chemical effects of the laser irradiation: surface morphology tests (light microscopy, Dektak profilometer and confocal laser scanning microscopy) showed the strong transformation of the surface with the laser treatment. Contact angle measurements revealed a significant increase of the surface energy for each PET depending on the applied fluency. Finally XPS characterization of the surface demonstrated the appearance of new chemical species favorable for cell attachment. This aspect had to be strongly considered regarding to the multiple biological effects of laser irradiated surfaces on living cells. Different cell culture experiments were carried out with L132 human epithelial cells after 6-days culture: proliferation and vitality rate, cell adhesion and cell morphology. Results clearly revealed that laser treatment improved cell proliferation (up to 140% with respect to controls), vitality (10% higher than controls), morphology and adhesion kinetics (more than 16% of control). A significant correlation (R2=0.906) was also established on one PET between the fluencies of laser treatment and the cellular response. These results emphasized high importance of the choice of the PET material for a medical application: only one of the three considered PET films showed really improved cellular response.

Periodic mode hopping induced by thermo-optic effects in continuous-wave optical parametric oscillators.

We show that thermal effects can lead to periodic mode hopping in cw optical parametric oscillators (OPOs). This mode hopping may occur as soon as two modes have different intensities at the point where they exchange their stability; this condition is easily fulfilled in OPOs that are triply resonant, or doubly resonant with a weakly resonant pump. We have observed such oscillations experimentally in a type II OPO in both configurations. A simple thermo-optic multimode model reproduces well the experimental regimes. We expect that multimode instabilities based on this mechanism can be observed with various aspects in many experimental setups at high pumping rate.