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Apatite Layer (apatite + layer)

Distribution by Scientific Domains

Polymers and Materials Science	100%

Selected Abstracts

Low Temperature Fabrication of ,-TCP,PCL Nanocomposites for Bone Implants,

ADVANCED ENGINEERING MATERIALS, Issue 8 2010
Michael Bernstein
Abstract A method to fabricate strong bioresorbable calcium phosphate,polymer nanocomposites with low polymer content without exposing the material to excessively high-processing temperatures is reported. Dense ,-TCP-based nanocomposites containing 5 or 15,vol% of uniformly distributed polycaprolactone (PCL) polymer were obtained by mixing ,-TCP nanopowder with PCL dissolved in chloroform followed by room temperature consolidation at the high pressure of 2.5,GPa (cold sintering). The composites had an attractive combination of compressive strength and ductility, and their dissolution behavior was similar to that of pure cold sintered ,-TCP. The immersion of ,-TCP,PCL composites in simulated body fluid (SBF) yielded in vitro deposition of a bone-like apatite layer suggesting the ability of these materials to bind to native bone tissue upon implantation. [source]

Apatite Deposition on NaOH-Treated PEEK and UHMWPE Films for Sclera Materials in Artificial Cornea Implants,

ADVANCED ENGINEERING MATERIALS, Issue 7 2010
Monica Pino
Abstract Cornea implants consist of a clear optic portion with a surrounding ring known as the skirt, which needs to integrate with the sclera. However, currently used skirt materials lead to poor tissue integration. Improvements in this respect may be achieved by using a bioactive skirt material that adapts to the metabolic activity of the cornea. Polyether etherketone (PEEK) and ultra-high molecular weight polyethylene (UHMWPE) might provide interesting alternatives, if they can be rendered bioactive. We, therefore, investigated the potential of surface-modifying PEEK and UHMWPE films through the use of a two-step treatment. This process involved a suitable chemical surface modification (via immersion in NaOH), with subsequent formation of apatite layers on the polymers' surfaces through exposure to supersaturated simulated body fluid (1.5 SBF). In the present work the effect of 5 and 10,M NaOH on formation of the apatite layer has been investigated with regard to wettability and topography features. In addition, the chemical stability of the apatite layer formed has been analyzed. Our data demonstrate that with an increase in NaOH concentration the wettability of the polymer increased, whilst some changes to the polymer film topography (increase/decrease in roughness) were observed. Most beneficially, the apatite layer that subsequently was grown on pre-treated PEEK and UHMWPE films through immersion in 1.5 SBF contained phosphate and carbonate ions, in similar ratios to those found in the apatite in dentine, thus, promising good in vivo bioactivity of these polymer films,a necessity if they are to be integrated into artificial cornea. [source]

Hydroxyapatite/Bioactive Glass Films Produced by a Sol,Gel Method: In Vitro Behavior

ADVANCED ENGINEERING MATERIALS, Issue 11 2009
Nihat C. Köseo
Abstract Hydroxyapatite (HA) and HA/bioactive glass (49S) films were deposited on Si(100) substrates by a sol,gel dip-coating method. The microstructure and in vitro bioactivity of the films were investigated by scanning electron microscopy (SEM), energy dispersive spectroscopy (EDS), and X-ray photoelectron spectroscopy (XPS). Polycrystalline HA and amorphous bioactive glass films were obtained after annealing at 600 and 400,°C, respectively. The crystallization temperature of HA was determined to be around 568,°C. The surfaces of the HA films were covered with an apatite layer consists of spherulites formed by nanosized needle-like aggregates after the soaking in simulated body fluid (SBF) for 10 days, while amorphous HA/bioactive glass surface was covered with larger spherical crystallites. Both XPS and EDS results obtained from HA/bioactive glass film, after soaking in SBF, showed increasing P amounts on the surface at the expense of Si. The higher density of the newly formed layer on HA/bioactive glass surface than that of the HA surface after 10 days of soaking was evidence of increased reaction rate and apatite forming ability when bioactive glass layer is present on the HA films. [source]

Novel Rice-shaped Bioactive Ceramic Nanoparticles (Adv. Eng.

ADVANCED ENGINEERING MATERIALS, Issue 5 2009
Mater.
The cover of Advanced Biomaterials shows Rice-shaped bioactive ceramic nanoparticles with 70 nm in average diameter and around 200 nm in length were produced by an improved sol-gel method. In comparison to most traditional bioactive glass/ceramic materials this novel bioactive ceramic contains a significant lower quantity of silicon and higher content of phosphorous. In vitro bioactivity test showed that this new class of materials can induce the deposition of an apatite layer from SBF solution, having potential to be used in both conventional orthopedic applications or in bone tissue engineering when incorporated in composite scaffolds. More information can be found in the article of J. F. Mano et al. on page B25. [source]

Novel Rice-shaped Bioactive Ceramic Nanoparticles,

ADVANCED ENGINEERING MATERIALS, Issue 5 2009
Zhongkui Hong
Rice-shaped bioactive ceramic nanoparticles of 70 nm average diameter and around 200 nm length were produced by an improved sol-gel method. In comparison to most traditional bioactive glass/ceramic materials, this novel bioactive ceramic contains a significant lower quantity of silicon and higher content of phosphorous. In vitro bioactivity tests showed that this new class of materials can induce the deposition of an apatite layer from simulated body fluid, having the potential to be used in both conventional orthopedic applications or in bone tissue engineering when incorporated in composite scaffolds. [source]

Deposition of Carbonated Hydroxyapatite (CO3HAp) on Poly(Methylmethacrylate) Surfaces by Decomposition of Calcium,EDTA Chelate

JOURNAL OF THE AMERICAN CERAMIC SOCIETY, Issue 10 2008
Yusuf Yusufoglu
Inspired from the nature, the development of organic,inorganic composites between polymers and hydroxyapatite (HAp) has been investigated extensively. In this study, bone-like apatite (carbonated hydroxyapatite, CO3HAp) was precipitated on poly(methylmethacrylate) (PMMA) films by the oxidative decomposition of Ca,EDTA (calcium,ethylenediamine tetraacetate) chelates. Corona-treated PMMA films were soaked in a Ca,EDTA,PO4,H2O2 solution and aged at 63°C and pH,9 for times ranging from 1 to 24 h. Apatite formed on PMMA films was characterized by X-ray diffraction, Fourier transform infrared (FTIR), Scanning electron microscope, energy-dipersive X-ray spectroscopy, and carbon analysis. The apatite was found to be CO3HAp with Ca/P atomic ratio ranging between 1.3 and 1.9. Elemental analyses indicated that the carbonate content of the apatite phase was around 6.5 wt% after 24 h of aging time. Lattice parameters were estimated using a Rietveld profile-analysis and found to be a=0.9438 nm and c=0.6901 nm. Furthermore, FTIR spectra indicated that the apatite deposited on PMMA was B-type CO3HAp, in which carbonate ions occupy the phosphate sites. In the first 3 h of aging, isolated rod-like HAp particles were observed. With time, the needle-like crystallites radiate from a nucleus to form double-spherulite shape particles. The crystallites grew into a continuous layer with a thickness of ,15 ,m after 24-h aging. The adhesive strength between the PMMA substrate and the apatite layer was determined to be around 1.7 MPa. [source]

Apatite Deposition on NaOH-Treated PEEK and UHMWPE Films for Sclera Materials in Artificial Cornea Implants,

Hydrothermal crystallization of carbonate-containing hydroxyapatite coatings prepared by radiofrequency-magnetron sputtering method

JOURNAL OF BIOMEDICAL MATERIALS RESEARCH, Issue 1 2007
Satoshi Nakamura
Abstract Carbonate-containing hydroxyapatite (HA) films were prepared by low-temperature hydrothermal annealing from carbonate-containing calcium phosphate amorphous coatings on titanium substrates. The biocompatibility of the carbonate-containing HA layers was estimated by in vitro tests using simulated body fluid (SBF). Precursory amorphous coatings were deposited with rf-magnetron sputtering apparatus, using calcium phosphate glass target in Ar/CO2 atmosphere. The carbonate-containing HA coatings were successfully formed by the annealing at above 130°C for 20 h. On the basis of SEM observation, about 2-,m thickness films coated rigidly were durable enough for the hydrothermal treatment. The coating layer was revealed to consist of single phase of PO4, and OH, partially carbonated HA by XRD and IR analyses. Overgrowing of bone-like apatite layers on the carbonate-containing HA surfaces in the SBF implied that the obtained films acquired a sufficient osteoconductivity, while it was still unclear that activity was enhanced, compared to pure HA coatings. The low-temperature hydrothermal annealing method was effective for preparation of rigid HA coatings on titanium as well as modification of their chemical compositions. © 2006 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 2007 [source]