Laser microgrooving and resorbable blast texturing for enhanced surface function of titanium alloy for dental implant applications

•Increased cell proliferation was seen on laser grooved and blast textured surfaces.•The effects on cell proliferation were observed early (day 2) and late (day 21).•Increased cell alignment was observed on laser grooved surfaces.•The superior proliferation may be attributable to guidance of cell al...

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Bibliographic Details
Published in:Biomedical engineering advances 2023-06, Vol.5, p.100090, Article 100090
Main Authors: Jones, Sophie E., Nichols, Luke, Elder, Steven H., Priddy, Lauren B.
Format: Article
Language:English
Subjects:
Bone-implant interface
Dental implants
Osseointegration
Surface properties
Titanium
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Summary:•Increased cell proliferation was seen on laser grooved and blast textured surfaces.•The effects on cell proliferation were observed early (day 2) and late (day 21).•Increased cell alignment was observed on laser grooved surfaces.•The superior proliferation may be attributable to guidance of cell alignment. Long-term dental implant success is dependent on biocompatibility and osseointegration between the bone and the implant. Surface modifications such as laser-induced microgrooving which increase contact area can enhance osseointegration by establishing and directing a stable attachment between the implant surface and peri‑implant bone. The objective of this study was to evaluate pre-osteoblast proliferation, morphology, and differentiation on titanium alloy (Ti64) surfaces—Laser-Lok© (LL), resorbable blast textured (RBT), and machined (M)—compared to tissue culture plastic (TCP) control. We hypothesized the LL surfaces would facilitate increased cellular alignment compared to all other groups, and LL and RBT surfaces would demonstrate enhanced proliferation and differentiation compared to M and TCP surfaces. Surface roughness was quantified using a surface profilometer, and water contact angle was measured to evaluate the hydrophilicity of the surfaces. Cellular function was assessed using quantitative viability and differentiation assays and image analyses, along with qualitative fluorescent (viability and cytoskeletal) imaging and scanning electron microscopy. No differences in surface roughness were observed between groups. Water contact angle indicated LL was the least hydrophilic surface, with RBT and M surfaces exhibiting greater hydrophilicity. Cell proliferation on day 2 was enhanced on both LL and RBT surfaces compared to M, and all three groups had higher cell numbers on day 2 compared to day 1. Cell orientation was driven by the geometry of the surface modification, as cells were more highly aligned on LL surfaces compared to TCP (on day 2) and RBT (on day 3). At day 21, cell proliferation was greater on LL, RBT, and TCP surfaces compared to M, though no differences in osteogenic differentiation were observed. Collectively, our results highlight the efficacy of laser microgrooved and resorbable blast textured surface modifications of Ti64 for enhancing cellular functions, which may facilitate improved osseointegration of dental implants.
ISSN:2667-0992
2667-0992
DOI:10.1016/j.bea.2023.100090