Electrochemical growth behavior, surface properties, and enhanced in vivo bone response of TiO2 nanotubes on microstructured surfaces of blasted, screw-shaped titanium implants

Young-Taeg SulDepartment of Biomaterials/Handicap Research, Institute for Clinical Sciences, Sahlgrenska Academy, Gothenburg University, Gothenburg, SwedenAbstract: TiO2 nanotubes are fabricated on TiO2 grit-blasted, screw-shaped rough titanium (ASTM grade 4) implants (3.75 × 7 mm) usi...

Full description

Bibliographic Details
Main Author: Young-Taeg Sul
Format: Article
Language:English
Published: Dove Medical Press 2010-02-01
Series:International Journal of Nanomedicine
Online Access:http://www.dovepress.com/electrochemical-growth-behavior-surface-properties-and-enhanced-in-viv-a3976
id doaj-ed87daeabcfa465c93fe893523a1e887
record_format Article
spelling doaj-ed87daeabcfa465c93fe893523a1e8872020-11-24T23:25:21ZengDove Medical PressInternational Journal of Nanomedicine1176-91141178-20132010-02-012010default87100Electrochemical growth behavior, surface properties, and enhanced in vivo bone response of TiO2 nanotubes on microstructured surfaces of blasted, screw-shaped titanium implantsYoung-Taeg SulYoung-Taeg SulDepartment of Biomaterials/Handicap Research, Institute for Clinical Sciences, Sahlgrenska Academy, Gothenburg University, Gothenburg, SwedenAbstract: TiO2 nanotubes are fabricated on TiO2 grit-blasted, screw-shaped rough titanium (ASTM grade 4) implants (3.75 × 7 mm) using potentiostatic anodization at 20 V in 1 M H3PO4 + 0.4 wt.% HF. The growth behavior and surface properties of the nanotubes are investigated as a function of the reaction time. The results show that vertically aligned nanotubes of ≈700 nm in length, with highly ordered structures of ≈40 nm spacing and ≈15 nm wall thickness may be grown independent of reaction time. The geometrical properties of nanotubes increase with reaction time (mean pore size, pore size distribution [PSD], and porosity ≈90 nm, ≈40–127 nm and 45%, respectively for 30 minutes; ≈107 nm, ≈63–140 nm and 56% for one hour; ≈108 nm, ≈58–150 nm and 60% for three hours). It is found that the fluorinated chemistry of the nanotubes of F-TiO2, TiOF2, and F-Ti-O with F ion incorporation of ≈5 at.%, and their amorphous structure is the same regardless of the reaction time, while the average roughness (Sa) gradually decreases and the developed surface area (Sdr) slightly increases with reaction time. The results of studies on animals show that, despite their low roughness values, after six weeks the fluorinated TiO2 nanotube implants in rabbit femurs demonstrate significantly increased osseointegration strengths (41 vs 29 Ncm; P = 0.008) and new bone formation (57.5% vs 65.5%; P = 0.008) (n = 8), and reveal more frequently direct bone/cell contact at the bone–implant interface by high-resolution scanning electron microscope observations as compared with the blasted, moderately rough implants that have hitherto been widely used for clinically favorable performance. The results of the animal studies constitute significant evidence that the presence of the nanotubes and the resulting fluorinated surface chemistry determine the nature of the bone responses to the implants. The present in vivo results point to potential applications of the TiO2 nanotubes in the field of bone implants and bone tissue engineering.Keywords: electrochemical fabrication, fluorinated TiO2 nanotubes, surface properties, osseointegrated titanium implant, in vivo bone response http://www.dovepress.com/electrochemical-growth-behavior-surface-properties-and-enhanced-in-viv-a3976
collection DOAJ
language English
format Article
sources DOAJ
author Young-Taeg Sul
spellingShingle Young-Taeg Sul
Electrochemical growth behavior, surface properties, and enhanced in vivo bone response of TiO2 nanotubes on microstructured surfaces of blasted, screw-shaped titanium implants
International Journal of Nanomedicine
author_facet Young-Taeg Sul
author_sort Young-Taeg Sul
title Electrochemical growth behavior, surface properties, and enhanced in vivo bone response of TiO2 nanotubes on microstructured surfaces of blasted, screw-shaped titanium implants
title_short Electrochemical growth behavior, surface properties, and enhanced in vivo bone response of TiO2 nanotubes on microstructured surfaces of blasted, screw-shaped titanium implants
title_full Electrochemical growth behavior, surface properties, and enhanced in vivo bone response of TiO2 nanotubes on microstructured surfaces of blasted, screw-shaped titanium implants
title_fullStr Electrochemical growth behavior, surface properties, and enhanced in vivo bone response of TiO2 nanotubes on microstructured surfaces of blasted, screw-shaped titanium implants
title_full_unstemmed Electrochemical growth behavior, surface properties, and enhanced in vivo bone response of TiO2 nanotubes on microstructured surfaces of blasted, screw-shaped titanium implants
title_sort electrochemical growth behavior, surface properties, and enhanced in vivo bone response of tio2 nanotubes on microstructured surfaces of blasted, screw-shaped titanium implants
publisher Dove Medical Press
series International Journal of Nanomedicine
issn 1176-9114
1178-2013
publishDate 2010-02-01
description Young-Taeg SulDepartment of Biomaterials/Handicap Research, Institute for Clinical Sciences, Sahlgrenska Academy, Gothenburg University, Gothenburg, SwedenAbstract: TiO2 nanotubes are fabricated on TiO2 grit-blasted, screw-shaped rough titanium (ASTM grade 4) implants (3.75 × 7 mm) using potentiostatic anodization at 20 V in 1 M H3PO4 + 0.4 wt.% HF. The growth behavior and surface properties of the nanotubes are investigated as a function of the reaction time. The results show that vertically aligned nanotubes of ≈700 nm in length, with highly ordered structures of ≈40 nm spacing and ≈15 nm wall thickness may be grown independent of reaction time. The geometrical properties of nanotubes increase with reaction time (mean pore size, pore size distribution [PSD], and porosity ≈90 nm, ≈40–127 nm and 45%, respectively for 30 minutes; ≈107 nm, ≈63–140 nm and 56% for one hour; ≈108 nm, ≈58–150 nm and 60% for three hours). It is found that the fluorinated chemistry of the nanotubes of F-TiO2, TiOF2, and F-Ti-O with F ion incorporation of ≈5 at.%, and their amorphous structure is the same regardless of the reaction time, while the average roughness (Sa) gradually decreases and the developed surface area (Sdr) slightly increases with reaction time. The results of studies on animals show that, despite their low roughness values, after six weeks the fluorinated TiO2 nanotube implants in rabbit femurs demonstrate significantly increased osseointegration strengths (41 vs 29 Ncm; P = 0.008) and new bone formation (57.5% vs 65.5%; P = 0.008) (n = 8), and reveal more frequently direct bone/cell contact at the bone–implant interface by high-resolution scanning electron microscope observations as compared with the blasted, moderately rough implants that have hitherto been widely used for clinically favorable performance. The results of the animal studies constitute significant evidence that the presence of the nanotubes and the resulting fluorinated surface chemistry determine the nature of the bone responses to the implants. The present in vivo results point to potential applications of the TiO2 nanotubes in the field of bone implants and bone tissue engineering.Keywords: electrochemical fabrication, fluorinated TiO2 nanotubes, surface properties, osseointegrated titanium implant, in vivo bone response
url http://www.dovepress.com/electrochemical-growth-behavior-surface-properties-and-enhanced-in-viv-a3976
work_keys_str_mv AT youngtaegsul electrochemicalgrowthbehaviorsurfacepropertiesandenhancedinvivoboneresponseoftio2nanotubesonmicrostructuredsurfacesofblastedscrewshapedtitaniumimplants
_version_ 1725558038217097216