The effect of pH on the structural evolution of accelerated biomimetic apatite

The classic biomimetic apatite coating process can be accelerated by first immersing substrates into concentrated simulated body fluid, 5× SBF (SBF1), at 37°C, to form an initial coating of precursor apatite spheres, and subsequently transferring to a second 5× SBF (SBF2) solution which is devoid of...

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Bibliographic Details
Published in:Biomaterials 2004-10, Vol.25 (22), p.5323-5331
Main Authors: Chou, Yu-Fen, Chiou, Wen-An, Xu, Yuhuan, Dunn, James C.Y, Wu, Benjamin M
Format: Article
Language:English
Subjects:
Apatite Structure
Apatites - chemistry
Biomimetic material
Biomimetics
Body Fluids
Bone tissue engineering
Calcium Phosphates - chemistry
Coated Materials, Biocompatible
Humans
Hydrogen-Ion Concentration
Kinetics
Microscopy, Electron
Microscopy, Electron, Scanning
Microscopy, Electron, Transmission
Plasma - chemistry
Polystyrenes - chemistry
Simulated body fluid
Spectroscopy, Fourier Transform Infrared
Temperature
Tensile Strength
Time Factors
Tissue Engineering
X-Ray Diffraction
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Summary:The classic biomimetic apatite coating process can be accelerated by first immersing substrates into concentrated simulated body fluid, 5× SBF (SBF1), at 37°C, to form an initial coating of precursor apatite spheres, and subsequently transferring to a second 5× SBF (SBF2) solution which is devoid of crystal growth inhibitors to promote phase transformation of SBF1-derived precursor apatite spheres into final crystalline apatite plates. Since SBF1 governs the formation kinetics and composition of the initial precursor spheres, we hypothesized that the pH of the SBF1 solution will also influence the final structure of the SBF2-derived crystalline apatite. To test this hypothesis, polystyrene substrates were immersed into SBF1 with different pH (5.8 or 6.5), and then immersed into the identical SBF2 (pH=6.0). The resultant apatites exhibited similar 2 θ XRD peaks; FTIR spectra in terms of hydroxyl, phosphate and carbonate groups; and Ca/P atomic ratio (1.42 for SBF1 5.8 apatite; 1.48 for SBF1 6.5 apatite). SEM, TEM and electron diffraction show that while SBF1 6.5 (pH 6.5) precursor spheres transform into larger, single crystals plates, SBF1 5.8 (pH 5.8) precursor spheres developed minute, polycrystalline plate-like structures over predominantly spherical precursor substrate.
ISSN:0142-9612
1878-5905
DOI:10.1016/j.biomaterials.2003.12.037