Nanostructuring of a Titanium Material by High‐Pressure Torsion Improves Pre‐Osteoblast Attachment

Faghihi, Shahab; Zhilyaev, Alexander P.; Szpunar, Jerzy A.; Azari, Fereshteh; Vali, Hojatollah; Tabrizian, Maryam

doi:10.1002/adma.200602276

Cited by 127 publications

(102 citation statements)

References 31 publications

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“…The latter includes biomedical applications [3], the development of corrosionresistant materials, high fatigue life materials, enhanced magnetic and thermoelectric properties, and improved hydrogen adsorption kinetics [2]. Recently, a great attention was paid on achieving high strength and high electroconductivity in Cu-based alloys [4][5][6], and it was claimed that such materials possess both characteristics simultaneously.…”

Section: Introductionmentioning

confidence: 99%

Effect of annealing on wear resistance and electroconductivity of copper processed by high-pressure torsion

et al. 2013

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The influences of annealing temperature on the wear properties and electrical conductivity of Cu were studied after processing by high-pressure torsion (HPT). The annealing of Cu specimens processed by HPT leads to an increase in electroconductivity and a decrease in the wear rate. It is apparent that a nanotribolayer at the surface induced during wear sliding plays a more significant role than the ultrafine-grained structure. A slight increase was observed in the microhardness of HPT copper specimens upon annealing at a relatively low temperature (100°C), and this is most likely due to a change in texture. The annealing leads to an increase in the Taylor factor by *5 %, which is in good agreement with the increase in the microhardness level which is also by *5 %. It is apparent that low-temperature annealing of HPT copper may produce optimal properties of the specimens including high strength and electroconductivity with a lower wear rate.

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Section: Introductionmentioning

confidence: 99%

Effect of annealing on wear resistance and electroconductivity of copper processed by high-pressure torsion

et al. 2013

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“…A variety of ceramic products have been clinically applied as biomaterials, and their advantages include high biocompatibility, in vivo stability, and superior mechanical characteristics compared to biomaterials such as synthetic polymers, resins, and metals [1][2][3][4][5][6][7][8][9][10][11][12][13]. Alumina ceramics are particularly effective as biomaterials owing to their high strength, resistance to wear, and smooth surface [6][7][8].…”

Section: Introductionmentioning

confidence: 99%

Biocompatibility and Bone Tissue Compatibility of Alumina Ceramics Reinforced with Carbon Nanotubes

et al. 2012

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Aims: The addition of carbon nanotubes (CNTs) remarkably improves the mechanical characteristics of base materials. CNT/alumina ceramic composites are expected to be highly functional biomaterials useful in a variety of medical fields. Biocompatibility and bone tissue compatibility were studied for the application of CNT/alumina composites as biomaterials.Methods & results: Inflammation reactions in response to the composite were as mild as those of alumina ceramic alone in a subcutaneous implantation study. In bone implantation testing, the composite showed good bone tissue compatibility and connected directly to new bone. An in vitro cell attachment test was performed for osteoblasts, chondrocytes, fibroblasts, and smooth muscle cells, and CNT/alumina composite showed cell attachment similar to that of alumina ceramic.Discussion & conclusion: Owing to proven good biocompatibility and bone tissue compatibility, the application of CNT/alumina composites as biomaterials that contact bone, such as prostheses in arthroplasty and devices for bone repair, are expected.4

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“…According to Ref. [47], the natural oxide layer on HPT Ti samples was quite different from that on their CG counterparts in chemical bonding structures. XPS studies revealed that the HPT-processed substrates showed a weakening of the Ti bonding in the TiO 2 on HPT sample, which may lead to the faster dissolution rate of the oxide during the formation of TNT layers.…”

Section: The Influence Of Substrate Grain Size On the Tnt Morphologiesmentioning

confidence: 99%

The influence of surface roughness and high pressure torsion on the growth of anodic titania nanotubes on pure titanium

Gao

Starink

2016

Applied Surface Science

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Anodic titanium dioxide nanotube (TNT) arrays have wide applications in photocatalytic, catalysis, electronics, solar cells and biomedical implants. When TNT coatings are combined with severe plastic deformation (SPD), metal processing techniques which efficiently improve the strength of metals, a new generation of biomedical implant is made possible with both improved bulk and surface properties. This work investigated the effect of processing by high pressure torsion (HPT) and different mechanical preparations on the substrate and subsequently on the morphology of TNT layers. HPT processing was applied to refine the grain size of commercially pure titanium samples and substantially improved their strength and hardness. Subsequent anodization at 30 V in 0.25 wt. % NH 4 F for 2 hours to form TNT layers on sample surfaces prepared with different mechanical preparation methods was carried out. It appeared that the local roughness of the titanium surface on a microscopic level affected the TNT morphology more than the macroscopic surface roughness. For HPTprocessed sample, the substrate has to be pre-treated by a mechanical preparation finer than 4000 grit for HPT to have a significant influence on TNTs. During the formation of TNT layers the oxide dissolution rate was increased for the ultrafine-grained microstructure formed due to HPT processing.

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Nanostructuring of a Titanium Material by High‐Pressure Torsion Improves Pre‐Osteoblast Attachment

Cited by 127 publications

References 31 publications

Effect of annealing on wear resistance and electroconductivity of copper processed by high-pressure torsion

Effect of annealing on wear resistance and electroconductivity of copper processed by high-pressure torsion

Biocompatibility and Bone Tissue Compatibility of Alumina Ceramics Reinforced with Carbon Nanotubes

The influence of surface roughness and high pressure torsion on the growth of anodic titania nanotubes on pure titanium

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