Surface analysis of failed oral titanium implants

Esposito, Marco; Lausmaa, Jukka; Hirsch, Jan–M.; Thomsen, Peter

doi:10.1002/(sici)1097-4636(1999)48:4<559::aid-jbm23>3.0.co;2-m

Cited by 92 publications

(75 citation statements)

References 28 publications

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“…When Ti alloy is surgically implanted into the human bone, calcium phosphate layer spontaneously forms on its surface [1][2][3][4][5] . This ability of Ti alloy to form calcium phosphate is one of the reasons for its better hard-tissue compatibility than those of other metals and accelerates bone formation around itself in the human bone.…”

Section: Introductionmentioning

confidence: 99%

Inhibitory Effect of Zirconium Coating to Bone Bonding of Titanium Implants in Rat Femur

et al. 2017

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When titanium (Ti) alloys are used for bone xators after bone fracture, Ti alloys form new bone around themselves in human bone. This ability can cause re-fracture when the xators are retrieved after bone healing. Surface treatments that do not cause bone formation around Ti alloy are necessary. The purpose of this study was to clarify the inhibitory effect of zirconium (Zr) coating on bone bonding of Ti alloy in rat femur. Non-coated and Zr-coated Ti implants were inserted into the medullary canal of the right and left femur (randomized to side). Four weeks later, the femurs with the implants were removed. The shear strength of implant xation with the bone was measured by a pull-out test. The amount of the residual new bone adhered on the implants after the pull-out test was evaluated. Pull-out shear strength and the amount of bone elements around implant were lower in Zr-coated group than in non-coated group. Our study indicates that Zr coating inhibits bone bonding between Ti implant and bone in vivo. This technique may be useful to prevent re-fracture when Ti implants are removed from human bone after bone healing.

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Section: Introductionmentioning

confidence: 99%

Inhibitory Effect of Zirconium Coating to Bone Bonding of Titanium Implants in Rat Femur

et al. 2017

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“…Composition of surface oxide film on titanium varies according to environmental changes, though the film is macroscopically stable. When titanium which has been surgically implanted into the human jaw is characterized using Auger electron spectroscopy, its surface oxide film reveals constituents of calcium, phosphorus, and sulfur 4,5) . By immersing titanium and its alloys in Hanks' solution and other solutions [6][7][8] , preferential adsorption of phosphate ions occurs.…”

Section: Intelligent Interface and Surface Modificationmentioning

confidence: 99%

Surface treatment and modification of metals to add biofunction

Hanawa¹

2017

Dent. Mater. J.

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To add biocompatibility or biofunction to metal surface, an intelligent interface between metals and tissues must be acquired. Tremendous surface modification techniques are currently studied to create the intelligent interface. In particular, bone formation or bone bonding is major purpose of the surface modifications. Time transient of surface modification techniques are summarized and the importance of roughened or porous surface to combine materials with bone tissue is demonstrated. As an example of surface modification, electrodeposition of poly(ethylene glycol) to inhibit biofilm formation is introduced. A dual-functional surface is formed on titanium by micro arc oxidation. In addition, the effect of topography on the elongation and differentiation of human mesenchymal stem cells was confirmed on the hybrid micrometer-level and nanometer-level grooves of titanium surface. Metal surface is possibly biofunctionalized by various surface modification techniques.

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“…The composition and properties of the oxide film regenerated in a biological environment may be different from those in water. When titanium which has been surgically implanted into the human jaw is characterized using Auger electron spectroscopy, its surface oxide film reveals constituents of calcium, phosphorus, and sulfur [7,8]. By immersing titanium and its alloys in Hanks' solution and other solutions [9][10][11][12] ( Fig.…”

Section: Mechanism Of Osseointegration In Titaniummentioning

confidence: 99%

Biofunctionalization of Metallic Materials: Creation of Biosis–Abiosis Intelligent Interface

Hanawa

2015

Interface Oral Health Science 2014

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Osseointegration, the first concept of biosis-abiosis intelligent interface, is primarily explained, and researches on the elucidation of osseointegration mechanism and titanium-tissue interface observation are reviewed to understand a concept to create biosis-abiosis intelligent interface. In addition, current status of surface treatment of metallic materials is reviewed. In particular, a gap between research level progress and commercialization in surface treatments is focused. Mechanical property, durability, and manufacturing process of surface layer formed on titanium by surface treatment, are significant to commercialize the treatment, while most of researches focuses only evaluation of biocompatibility and biofunction. IntroductionExcellent biocompatibility and biofunction of ceramics and polymers are expected to show excellent properties as biomaterials; in fact many devices consisting of metals have been substituted by those consisting of ceramics and polymers. In spite of this event, over 70 % of implant devices in medical field including dentistry, especially over 95 % in orthopedics, still consist of metals, and this share is currently maintained, because of their high strength, toughness, and durability.On the contrary, a disadvantage of using metals as biomaterials is that they are typically artificial materials and have no biofunction. Therefore, metal surface naturally forms a clear interface against living tissue that works as a barrier to conduct biofunctions. To add biocompatibility and biofunction to metals, in other words, to create biosis-abiosis intelligent interface, surface treatment is essential,

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Surface analysis of failed oral titanium implants

Cited by 92 publications

References 28 publications

Inhibitory Effect of Zirconium Coating to Bone Bonding of Titanium Implants in Rat Femur

Inhibitory Effect of Zirconium Coating to Bone Bonding of Titanium Implants in Rat Femur

Surface treatment and modification of metals to add biofunction

Biofunctionalization of Metallic Materials: Creation of Biosis–Abiosis Intelligent Interface

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