NiTi laser textured implants with improved in vivo osseointegration: An experimental study in rats

doi:10.1016/j.jmst.2021.11.014

Abstract

Abstract:

Laser surface texturing is a versatile approach for manufacturing implants with suitable surfaces for osseointegration. This work explores the use of laser to fabricate NiTi textured implants, testing two different groove-based designs. Their performance was evaluated in vivo through implantation in Sprague Dawley rats’ femur, being then analyzed after 4 and 12 weeks of implantation. Push-out experiments and histological characterization allowed to assess bone-implant bond and osseointegration and to compare the laser textured solutions with non-textured NiTi. Histology showed that, at 4 weeks of implantation, mainly immature woven bone was present whilst at 12 weeks a more mature bone had developed. Considering the largest implantation time (12 weeks), results showed extraction forces considerably higher for textured implants (G2 and G3). Moreover, when comparing G2 and G3, it was found that G2 (having the highest textured surface area) displayed the maximum extraction force among all groups, with an increase of 212% when compared to non-textured implants (G1).
These results prove that the design and manufacturing technology are effective to promote an improved bone-implant bond, aiming the development of orthopedic implants.

Key words: NiTi, Laser surface texturing, In vivo studies, Osseointegration, Implants

M.M. Costa, A. Miranda, F. Bartolomeu, O. Carvalho, S. Matos, G. Miranda, F.S. Silva. NiTi laser textured implants with improved in vivo osseointegration: An experimental study in rats[J]. J. Mater. Sci. Technol., 2022, 114: 120-130.

Figures/Tables 15

Fig. 1. Non-textured NiTi implant (G1).

Fig. 2. Schematic representation of laser apparatus (A) and strategic design (B) for textures manufacture.

Fig. 3. Surgical procedure and implantation.

Fig. 4. Push-out assay. (A) Schematic representation, (B) real image of push-out setup and (C) load-displacement curve (gray area represents energy absorption).

Fig. 5. Schematic representation of the cuts made for histological characterization.

Fig. 6. SEM micrographs of G2 and G3 laser textured implants before in vivo implantation and respective obtained dimensions in µm (a=groove width, b=wall thickness and c=depth).

Fig. 7. Radiographic images of the leg of Sprague Dawley rats after the implantation times (4 and 12 weeks) with NiTi implants (G1, G2 and G3).

Fig. 8. Push-out results regarding maximum force for the different groups, at each timepoint. Values shown as mean ± SD. *- p < 0.05; **- p < 0.01; *** - p < 0.001; **** - p < 0.0001.

Table 1. Energy absorption to failure (Ea) for the different groups at each timepoint.

Group	Timepoint (weeks)	E_a (mean ± SD, mJ)
G1	4	70.37 ± 33.95
G1	12	63.64 ± 13.33
G2	4	78.15 ± 27.24
G2	12	158.57 ± 48.88
G3	4	60.37 ± 21.88
G3	12	109.67 ± 17.89

Fig. 9. Typical load-displacement curves for all groups and timepoints.

Fig. 10. Histological sections of the implants and bone tissues after 4 and 12 weeks of implantation.

Fig. 11. SEM micrographs and EDS spectra of G1 specimens, after push-out tests, for (A) 4 weeks and (B) 12 weeks.

Fig. 12. SEM micrographs of bone cavity for G1, after push-out experiments, for (A) 4 weeks and (B) 12 weeks: number 1 corresponds to secondary mode and number 2 to back-scattered mode.

Fig. 13. SEM micrographs and EDS spectra of G2 and G3, after push-out tests, for 4 and 12 weeks.

Fig. 14. SEM micrographs of bone cavity for G2 and G3, after push-out experiments, for the different timepoints: 4 and 12 weeks.

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