N. Bouropoulos scite author profile

The assembly of amelogenin protein into nanospheres is postulated to be a key factor in the stability of enamel extracellular matrix framework, which provides the scaffolding for the initial enamel apatite crystals to nucleate and grow. Adsorption isotherms were evaluated in order to investigate the nature of interactions of amelogenin nanospheres with hydroxyapaite crystals in solution, where their assembly status and particle size distribution are defined. We report that the adsorption isotherm of a recombinant mouse amelogenin (rM179) on synthetic hydroxyapatite crystals can be described using a Langmuir model indicating that amelogenin nanospheres adsorb onto the surface of apatite crystals as binding units with defined adsorption sites. The adsorption affinity and the maximum adsorption sites were 19.7 x 10(5) L/mol and 6.09 x 10(-7) mol/m2, respectively, with an r2 value of 0.99. Knowing the composition and particle size distribution of amelogenin nanospheres under the condition of adsorption experiments, we have calculated the number of nanospheres and the crystal surface area covered by each population of nanospheres at their maximum adsorption. It was found that total maximum binding covers 64% of the area unit. This observation supports the speculation that amelogenin binding onto apatite surface is selective and occurs only at certain sites.

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Induction of Apatite by the Cooperative Effect of Amelogenin and the 32-kDa Enamelin

Bouropoulos

Moradian‐Oldak

2004

J Dent Res

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Extracellular matrix proteins are considered to play essential roles in controlling the nucleation, growth, and organization of hydroxyapatite crystals during enamel formation. The effects of amelogenin and the 32-kDa enamelin proteins on apatite nucleation were investigated by a steady-state gel diffusion device containing 10% gelatin gels loaded with 0, 0.75%, and 1.5% (w/w) native porcine amelogenins. It was found that the induction time for hydroxyapatite precipitation was strongly increased by the presence of amelogenins, suggesting an inhibitory effect of apatite nucleation. Addition of 18 micro g/mL of 32-kDa enamelin to 10% gelatin also caused inhibition of nucleation. Remarkably, addition of 18 and 80 micro g/mL of 32-kDa enamelin in gels containing 1.5% amelogenin accelerated the nucleation process in a dose-dependent manner. Our observations strongly suggest that the 32-kDa enamelin and amelogenins cooperate to promote nucleation of apatite crystals and propose a possible novel mechanism of mineral nucleation during enamel biomineralization.

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Optically Active Spherical Polyelectrolyte Brushes with a Nanocrystalline Magnetic Core

Bakandritsos

Bouropoulos

Zbořil

et al. 2008

Adv Funct Materials

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The unique properties of magnetic nanocrystals have triggered intensive research towards their effective functionalization and application in many technological fields. Although synthesis of magnetic colloids is being thoroughly studied, there is limited knowledge on the synthesis, characterization, and properties of magnetic polyelectrolyte spherical brushes. In the present work, the preparation of such hybrids and the subsequent formation of stable aqueous colloids are described. The core of the spherical brush consists of a magnetic γ‐Fe2O3 nanocrystallite (faceted but mostly spherical‐like) with a mean diameter of 17 nm. The bioadhesive polyelectrolyte poly(sodium 4‐styrene sulfonate), forming the surrounding brush layer, was proven to be an effective covalently modifying macromolecule for the iron oxide surface, as Fourier transform IR spectroscopy revealed. Several observations on colloidal aspects are discussed and are successfully explained by models and experiments describing polyelectrolyte brushes with a soft polymeric core. Finally, the hybrids exhibit their multifunctional character and their technological importance by combining in a single and soluble product with magnetic and nonlinear optical properties.

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Assembly of Amelogenin Proteolytic Products and Control of Octacalcium Phosphate Crystal Morphology

Moradian‐Oldak

Iijima

Bouropoulos

et al. 2003

Connective Tissue Research

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The formation of enamel apatite crystals involves extracellular molecular events among which matrix assembly, interactions with growing crystals, and protein processing and removal are the subject of numerous investigations. Following the description of amelogenin nanospheres and the evidence for their presence in vivo as the principal structural component of developing dental enamel, we have focused our studies on investigating at the molecular level the process of nanosphere assembly and evaluating the effects of amelogenin on crystal growth and morphology. This paper is a short review of our recent studies with a focus on the assembly of amelogenin proteolytic products and their modulating effect on octacalcium phosphate (OCP) crystal morphology. In addition, we report that incorporation of amelogenins into 10% gelatin gel does not affect diffusion of calcium. This remarkable finding indicates that the observed modulation effect by amelogenin on OCP crystal morphology is not due to alteration of calcium diffusion into the gels but is the result of direct amelogenin-mineral interactions.

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Assembly of Amelogenin Proteolytic Products and Control of Octacalcium Phosphate Crystal Morphology

Moradian‐Oldak

Iijima

Bouropoulos

et al. 2003

Connective Tissue Res.

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N. Bouropoulos

Analysis of Hydroxyapatite Surface Coverage by Amelogenin Nanospheres Following the Langmuir Model for Protein Adsorption

Induction of Apatite by the Cooperative Effect of Amelogenin and the 32-kDa Enamelin

Optically Active Spherical Polyelectrolyte Brushes with a Nanocrystalline Magnetic Core

Assembly of Amelogenin Proteolytic Products and Control of Octacalcium Phosphate Crystal Morphology

Assembly of Amelogenin Proteolytic Products and Control of Octacalcium Phosphate Crystal Morphology

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