This finding is in accord with the XPS results described above F

This finding is in accord with the XPS results described above. Figure 4 AFM images. AFM images of pristine PET (PET), PET treated by

plasma and grafted with BPD (PET/plasma/BPD), PET treated by plasma and grafted with BPD and then with Ag nanoparticles (PET/plasma/BPD/AgNP), and PET treated by plasma and grafted with Ag nanoparticles previously grafted with dithiol (PET/plasma/AgNP*). R a is surface roughness of samples in nanometers. Similar results were obtained by electrokinetic analysis (Figure 5). After BPD grafting of plasma-treated PET, zeta potential decreases in comparison with pristine PET due to the GSK458 cell line presence of -SH groups and diphenyl rings of dithiol on the sample surface. Another change of surface chemistry Selleckchem Ralimetinib and charge is visible after the grafting with AgNPs, which is due to the presence of AgNPs on the sample surface. Since the silver concentration is low, the observed change is low, too. Grafting of the plasma-treated PET with AgNP* particles leads to only negligible change in zeta potential (compare PET/plasma and PET/plasma/AgNP* cases in Figure 5). Small

change in zeta potential shows that only a small amount of AgNP* particles is attached in this case. All these findings are in accord with the results of XPS analysis described above (see also Table 1). Figure 5 Zeta potential. Zeta potential determined on pristine (PET), PET treated by plasma (PET/plasma), PET treated by plasma and grafted with BPD (PET/plasma/BPD), PET treated by plasma and

grafted with BPD learn more and then subsequently with Ag nanoparticles (PET/plasma/BPD/AgNP), and PET treated by plasma and grafted with Ag nanoparticles previously grafted with dithiol (PET/plasma/AgNP*). HS means data obtained by the streaming current method and Helmholtz-Smoluchowski equation; FM means data obtained by the streaming potential method and Fairbrother-Mastins equation. The systems studied may have potential application, e.g., in medicine as prevention of creation of bacterial biofilm [22]. Conclusions Two different procedures were used for coating of PET surface with until silver nanoparticles. Both procedures are based on the surface activation of PET by Ar plasma discharge and use of dithiol as binding reagent between silver nanoparticles and plasma-modified PET surface. XPS results confirmed creation of a silver nanoparticle-thiol layer (in the case of AgNP) on the PET surface. Rather large objects observed on AFM images show that a significant aggregation of deposited AgNPs takes place during the grafting procedure. Grafting with thiols and gold nano-objects generally leads to a decrease of the zeta potential. We achieved higher concentration of silver nanoparticles by deposition on PET grafted beforehand with dithiol. Acknowledgements This work was supported by GACR under projects 14-18149P (A.R.) and P108/12/G108. References 1.

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