Formation process of apatite layer on titanium-coated silicon wafer surfaces

Sawaguchi, Haruna; Xu, Jiale; Kawai, Takeshi; Matsukawa, Takashi; Nonomura, Yoshiaki

doi:10.2109/jcersj2.16034

Cited by 4 publications

(6 citation statements)

References 15 publications

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“…SBF, as well as human blood plasma, is a solution supersaturated with apatite [ 7 ], and, thus, apatite formation on materials occurs as a result of the heterogeneous nucleation and growth of the apatite nuclei that spontaneously proceeds by taking up calcium and phosphate ions in SBF once the apatite nuclei have formed [ 7 ]. It should be noted that homogenous nucleation rarely occurs in SBF, but nevertheless has been reported in several papers [ 70 ]. The apatite nucleation that occurs is affected by both chemical factors such as hydroxyl groups, surface energy and surface charge, as well as physical factors, such as roughness.…”

Section: The Role Of Materials Geometry and Texturementioning

confidence: 99%

The Use of Simulated Body Fluid (SBF) for Assessing Materials Bioactivity in the Context of Tissue Engineering: Review and Challenges

2020

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Some special implantable materials are defined as “bioactive” if they can bond to living bone, forming a tight and chemically-stable interface. This property, which is inherent to some glass compositions, or can be induced by applying appropriate surface treatments on otherwise bio-inert metals, can be evaluated in vitro by immersion studies in simulated body fluid (SBF), mimicking the composition of human plasma. As a result, apatite coating may form on the material surface, and the presence of this bone-like “biomimetic skin” is considered predictive of bone-bonding ability in vivo. This review article summarizes the story and evolution of in vitro bioactivity testing methods using SBF, highlighting the influence of testing parameters (e.g., formulation and circulation of the solution) and material-related parameters (e.g., composition, geometry, texture). Suggestions for future methodological refinements are also provided at the end of the paper.

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Section: The Role Of Materials Geometry and Texturementioning

confidence: 99%

The Use of Simulated Body Fluid (SBF) for Assessing Materials Bioactivity in the Context of Tissue Engineering: Review and Challenges

2020

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“…A decrease in roughness value was previously observed after titanium coating on polished side of silicon wafer (from 0.06 to 0.04 µm). [ 46 ]…”

Section: Resultsmentioning

confidence: 99%

“…A decrease in roughness value was previously observed after titanium coating on polished side of silicon wafer (from 0.06 to 0.04 µm). [46] The fabrication techniques and processed material have great impact on the surface properties of produced MNs. Hence, the initial roughness value of the material to be processed is vital and is directly associated with the final roughness value.…”

Section: Surface Profile Analysismentioning

confidence: 99%

Xenon Difluoride Dry Etching for the Microfabrication of Solid Microneedles as a Potential Strategy in Transdermal Drug Delivery

Eş

Kafadenk

Gormus

et al. 2023

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“…Examples include thermal treatments [36,37], glow discharge [73][74][75], ultraviolet [49,[75][76][77], and high-energy low-current DC electron beam [78,79] irradiations, as well as electron cyclotron resonance plasma oxidation [80] and laser [81,82] treatments, which together produce very thin surface layers of the substrate with oxidation and/or partial degradation [49,[73][74][75][76][77][78][79][80][81] or surface texturization [82]. More specifically, the surface of substrates can be coated with an interlayer of another compound [48,67,[83][84][85][86][87][88][89][90][91][92][93][94][95][96][97][98] containing special binding agents [99][100][101] before the CaPO 4 are deposited. That is, zinc orthophosphate…”

Section: General Knowledge Terminology and Definitionsmentioning

confidence: 99%

“…More specifically, the surface of substrates can be coated with an interlayer of another compound [48,67,[83][84][85][86][87][88][89][90][91][92][93][94][95][96][97][98] containing special binding agents [99][100][101] before the CaPO 4 are deposited. That is, zinc orthophosphate [48], bioglass [88,89], titania [90][91][92], SiC [93], calcium carbonate [94], titanium [95,96] and diamond [97] coatings have been pre-deposited on the surface of various substrates onto which CaPO 4 are subsequently deposited. Similarly, organophosphate polymers have been chemically bonded to chemically inert polyethylene via surface graft polymerization of phosphate-containing monomers [67].…”

Section: General Knowledge Terminology and Definitionsmentioning

confidence: 99%

There Are over 60 Ways to Produce Biocompatible Calcium Orthophosphate (CaPO4) Deposits on Various Substrates

Dorozhkin

2023

J. Compos. Sci.

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A The present overview describes various production techniques for biocompatible calcium orthophosphate (abbreviated as CaPO4) deposits (coatings, films and layers) on the surfaces of various types of substrates to impart the biocompatible properties for artificial bone grafts. Since, after being implanted, the grafts always interact with the surrounding biological tissues at the interfaces, their surface properties are considered critical to clinical success. Due to the limited number of materials that can be tolerated in vivo, a new specialty of surface engineering has been developed to desirably modify any unacceptable material surface characteristics while maintaining the useful bulk performance. In 1975, the development of this approach led to the emergence of a special class of artificial bone grafts, in which various mechanically stable (and thus suitable for load-bearing applications) implantable biomaterials and artificial devices were coated with CaPO4. Since then, more than 7500 papers have been published on this subject and more than 500 new publications are added annually. In this review, a comprehensive analysis of the available literature has been performed with the main goal of finding as many deposition techniques as possible and more than 60 methods (double that if all known modifications are counted) for producing CaPO4 deposits on various substrates have been systematically described. Thus, besides the introduction, general knowledge and terminology, this review consists of two unequal parts. The first (bigger) part is a comprehensive summary of the known CaPO4 deposition techniques both currently used and discontinued/underdeveloped ones with brief descriptions of their major physical and chemical principles coupled with the key process parameters (when possible) to inform readers of their existence and remind them of the unused ones. The second (smaller) part includes fleeting essays on the most important properties and current biomedical applications of the CaPO4 deposits with an indication of possible future developments.

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Formation process of apatite layer on titanium-coated silicon wafer surfaces

Cited by 4 publications

References 15 publications

The Use of Simulated Body Fluid (SBF) for Assessing Materials Bioactivity in the Context of Tissue Engineering: Review and Challenges

The Use of Simulated Body Fluid (SBF) for Assessing Materials Bioactivity in the Context of Tissue Engineering: Review and Challenges

Xenon Difluoride Dry Etching for the Microfabrication of Solid Microneedles as a Potential Strategy in Transdermal Drug Delivery

There Are over 60 Ways to Produce Biocompatible Calcium Orthophosphate (CaPO4) Deposits on Various Substrates

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