Polyetheretherketone and titanium surface treatments to modify roughness and wettability - Improvement of bioactivity and antibacterial properties

doi:10.1016/j.jmst.2021.04.023

Abstract

Abstract:

Among the materials available for implant production, titanium is the most used while polyetheretherketone (PEEK) is emerging thanks to its stability and to the mechanical properties similar to the ones of the bone tissue. Material surface properties like roughness and wettability play a paramount role in cell adhesion, cell proliferation, osteointegration and implant stability. Moreover, the bacterial adhesion to the biomaterial and the biofilm formation depend on surface smoothness and hydrophobicity. In this work, two different treatments, sandblasting and air plasma, were used to increase respectively roughness and wettability of two materials: titanium and PEEK. Their effects were analyzed with profilometry and contact angle measurements. The biological properties of the material surfaces were also investigated in terms of cell adhesion and proliferation of NIH-3T3 cells, MG63 cells and human Dental Pulp Stem Cells. Moreover, the ability of Staphylococcus aureus to adhere and form a viable biofilm on the samples was evaluated. The biological properties of both treatments and both materials were compared with samples of Synthegra® titanium, which underwent laser ablation to obtain a porous micropatterning, characterized by a smooth surface to discourage bacterial adhesion. All cell types used were able to adhere and proliferate on samples of the tested materials. Cell adhesion was higher on sandblasted PEEK samples for both MG63 and NIH-3T3 cell lines, on the contrary, the highest proliferation rate was observed on sandblasted titanium and was only slightly dependent on wettability; hDPSCs were able to proliferate similarly on sandblasted samples of both tested materials. The highest osteoblast differentiation was observed on laser micropatterned titanium samples, but similar effects, even if limited, were also observed on both sandblasted materials and air plasma treated titanium. The lowest bacterial adhesion and biofilm formation was observed on micropatterned titanium samples whereas, the highest biofilm formation was detected on sandblasted PEEK samples, and in particular on samples not treated with air-plasma, which displayed the highest hydrophobicity. The results of this work showed that all the tested materials were able to sustain osteoblast adhesion and promote cell proliferation; moreover, this work highlights the feasible PEEK treatments which allow to obtain surface properties similar to those of titanium. The results here reported, clearly show that cell behavior depends on a complex combination of surface properties like wettability and roughness and material nature, and while a rough surface is optimal for cell adhesion, a smooth and less hydrophilic surface is the best choice to limit bacterial adhesion and biofilm formation.

Key words: PEEK, Titanium, Micropatterning, Roughness, Wettability, Differentiation

Davide Porrelli, Mario Mardirossian, Nicola Crapisi, Marco Urban, Nicola Andrea Ulian, Lorenzo Bevilacqua, Gianluca Turco, Michele Maglione. Polyetheretherketone and titanium surface treatments to modify roughness and wettability - Improvement of bioactivity and antibacterial properties[J]. J. Mater. Sci. Technol., 2021, 95: 213-224.

Figures/Tables 9

Fig. 1. Effects of treatments on surface roughness. Roughness values of titanium and PEEK samples before (grey) and after (light grey) air-plasma treatment. Relevant comparisons are indicated with an asterisk (p < 0.05) or with NS (not significant).

Fig. 2. Effects of treatments on wettability. Wettability, expressed with the contact angle, of sample surfaces before (dark grey) and after (light grey) air-plasma treatment. Relevant comparisons are indicated with an asterisk (p < 0.05) or with NS (not significant).

Fig. 3. Titanium surface morphology. SEM micrographs of titanium samples surfaces: Ti_M (A), Ti_M* (D), Ti_S (B), Ti_S* (E), Ti_L (C), Ti_L* (F). Scale bar is 100 µm.

Fig. 4. PEEK surface morphology. SEM micrographs of PEEK samples surfaces: P_M (A), P_M* (C), P_S (B), P_S* (D). Scale bar is 100 µm.

Fig. 5. Cell adhesion on treated samples. Cell adhesion measured for NIH-3T3 cells (A), MG63 cells (B) e hDPSCs (C) and expressed as the fluorescence intensity of the Alamar Blue. The asterisks indicate relevant statistically significant differences between samples for the same cell line (p < 0.05).

Fig. 6. Cell proliferation on treated samples. Proliferation rate trends for NIH3T3 cells (A), MG63 cells (B) and hDPSCs (C) cultured on titanium and PEEK samples. (?, P_S; ?, P_S*; ?, Ti_S; ○, Ti_S*; ?, Ti_L; △, Ti_L*. Asterisks indicate the relevant statistically significant differences (p < 0.05).

Fig. 7. ALP activity for hDPSCs cultured on treated samples. ALP activity expressed as the absorbance at 410 nm normalized for the amount of proteins measured in each sample at day 4 (light grey), day 7 (grey) and day 14 (dark grey). +, statistically significant differences within sample groups; *, statistically significant differences between groups at the same time point.

Fig. 8. Biofilm formation on treated samples. Biofilm viability evaluated with the MTT assay. Asterisks indicate the relevant statistically significant differences (p < 0.05).

Fig. 9. Bacterial adhesion. SEM micrographs of bacterial cells adhered on samples surfaces: P_S (A), P_S* (D), Ti_S (B), Ti_S* (E), Ti_L (C), Ti_L* (F). Scale bar is 10 µm.

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