Roberto Hübler scite author profile

Micro and nanoscale changes allow the optimization of physico-chemical properties of titanium implant surfaces. Recently UV and plasma treatments have allowed surface hydrophilicity to take increased prominence; however, this beneficial effect is short-lived. The aim of this study is to investigate methodologies post-anodizing treatment to generate and maintain high surface hydrophilicity along with high biocompatibility. Anodized surfaces were characterized regarding physical–chemical properties. Then, surface wettability with nanomorphology was evaluated at different times and with distinct post-treatments: as deposited, with a reactive plasma and UV-light post-treatment, stored in air or deionized (DI) water. Adhesion, alkaline phosphatase (ALP) activity and bone cell viability tests were executed after the incremental treatments. The anodizing process generated a surface with TiO 2 nanotubes morphology and micro-roughness. Plasma-treated surfaces resulted in the most hydrophilic samples and this property was maintained for a longer period when those were stored in DI water (angle variation of 7° to 12° in 21 days). Furthermore, plasma post-treatment changed the titanium surface crystalline phase from amorphous to anatase. Anodized surfaces modified by reactive plasma and stored in DI water suggest better hydrophilicity stability, biocompatibility, ALP activity and achievement of crystalline phase alteration, indicating future potential use on biomedical implants.

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Antibacterial potential associated with drug-delivery built TiO2 nanotubes in biomedical implants

Kunrath

Leal

Hübler

et al. 2019

AMB Expr

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The fast evolution of surface treatments for biomedical implants and the concern with their contact with cells and microorganisms at early phases of bone healing has boosted the development of surface topographies presenting drug delivery potential for, among other features, bacterial growth inhibition without impairing cell adhesion. A diverse set of metal ions and nanoparticles (NPs) present antibacterial properties of their own, which can be applied to improve the implant local response to contamination. Considering the promising combination of nanostructured surfaces with antibacterial materials, this critical review describes a variety of antibacterial effects attributed to specific metals, ions and their combinations. Also, it explains the TiO 2 nanotubes (TNTs) surface creation, in which the possibility of aggregation of an active drug delivery system is applicable. Also, we discuss the pertinent literature related to the state of the art of drug incorporation of NPs with antibacterial properties inside TNTs, along with the promising future perspectives of in situ drug delivery systems aggregated to biomedical implants.

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Application of TiO₂Nanotubes as a Drug Delivery System for Biomedical Implants: A Critical Overview

et al. 2018

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TiO 2 nanotubes (TNTs) surfaces have been applied as a coating to metallic biomedical implants, presenting promising results in preliminary analyses in terms of integration to living tissues when considering cell adhesion and proliferation, physicochemical properties and biocompatibility. They also present the potential to incorporate drugs and regulate their release to the surrounding tissues. Considering this particular potential, a critical review of the latest studies that considered the possible incorporation of specific drugs like antibiotics, anti-inflamma-tories and/or proteins and cytokines capable of positively influence the healing process at the implant-tissue interface has been considered relevant. Also, a summary about TNTs physicochemical characteristics and biocompatibility studies is presented. Advanced methods for regulating this drug-release mechanism and its specific chemical immobilization in an in vivo environment are discussed, along with TNTs future clinical perspectives.

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Effects of low-level laser therapy on bone formed after distraction osteogenesis

et al. 2009

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This study evaluated the effect of low-level laser therapy (LLLT) on the chemical composition, crystallinity and crystalline structure of bone at the site of distraction osteogenesis. Five rabbits were subjected to distraction osteogenesis (latency = 3 days; rate and frequency = 0.7 mm/day for 7 days; consolidation = 10 days), and three were given LLLT with arsenide-gallium-aluminum (AsGaAl; 830 nm, 40 mW): 10 J/cm(2) dose per spot, applied directly to the distraction osteogenesis site during the consolidation stage at 48 h intervals. Samples were harvested at the end of the consolidation stage. X-ray fluorescence and X-ray diffraction were used to analyze chemical composition, crystallinity and crystalline structure of bone at the distraction osteogenesis site. The analysis of chemical composition and calcium (Ca) and phosphorus (P) ratios revealed greater mineralization in the LLLT group. Diffractograms showed that the crystalline structure of the samples was similar to that of hydroxyapatites. Crystallinity percentages were greater in rabbits that were given LLLT. Crystallinity (41.14% to 54.57%) and the chemical composition of the bone at the distraction osteogenesis site were similar to the that of the control group (42.37% to 49.29%). The results showed that LLLT had a positive effect on the biomodulation of newly formed bone.

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Roberto Hübler

Effect of bismuth oxide on white mineral trioxide aggregate: chemical characterization and physical properties

Extension of hydrophilicity stability by reactive plasma treatment and wet storage on TiO₂nanotube surfaces for biomedical implant applications

Antibacterial potential associated with drug-delivery built TiO2 nanotubes in biomedical implants

Application of TiO₂Nanotubes as a Drug Delivery System for Biomedical Implants: A Critical Overview

Effects of low-level laser therapy on bone formed after distraction osteogenesis

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Roberto Hübler

Effect of bismuth oxide on white mineral trioxide aggregate: chemical characterization and physical properties

Extension of hydrophilicity stability by reactive plasma treatment and wet storage on TiO2nanotube surfaces for biomedical implant applications

Antibacterial potential associated with drug-delivery built TiO2 nanotubes in biomedical implants

Application of TiO2Nanotubes as a Drug Delivery System for Biomedical Implants: A Critical Overview

Effects of low-level laser therapy on bone formed after distraction osteogenesis

Contact Info

Product

Resources

About

Extension of hydrophilicity stability by reactive plasma treatment and wet storage on TiO₂nanotube surfaces for biomedical implant applications

Application of TiO₂Nanotubes as a Drug Delivery System for Biomedical Implants: A Critical Overview