Biomimetic dual templating of silica by polysaccharide/protein assemblies

The control of silica growth by living organisms such as diatoms is known to involve the templating effect of several biomolecules working concomitantly. However, until now, biomimetic studies involving model molecules have mainly been performed with single templates. We show here that the addition...

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Veröffentlicht in:	Colloids and surfaces, B, Biointerfaces B, Biointerfaces, 2008-08, Vol.65 (1), p.140-145
Hauptverfasser:	Gautier, Clémentine, Abdoul-Aribi, Nora, Roux, Cécile, Lopez, Pascal J., Livage, Jacques, Coradin, Thibaud
Format:	Artikel
Sprache:	eng
Schlagworte:	Alginate Alginates - chemistry Alginates - metabolism Bacillariophyceae Biomimetics Biomimetism Chemical Precipitation Chemical Sciences Dual templating Gelatin Gelatin - chemistry Gelatin - metabolism Glucuronic Acid - chemistry Glucuronic Acid - metabolism Hexuronic Acids - chemistry Hexuronic Acids - metabolism Inorganic chemistry Macromolecular Substances - metabolism Microscopy, Electron, Scanning Microscopy, Electron, Transmission Models, Biological Silica Silicon Dioxide - metabolism
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container_title	Colloids and surfaces, B, Biointerfaces
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creator	Gautier, Clémentine Abdoul-Aribi, Nora Roux, Cécile Lopez, Pascal J. Livage, Jacques Coradin, Thibaud
description	The control of silica growth by living organisms such as diatoms is known to involve the templating effect of several biomolecules working concomitantly. However, until now, biomimetic studies involving model molecules have mainly been performed with single templates. We show here that the addition of two biopolymers, gelatin and alginic acid, to silicate solutions allows the formation of complex structures resulting from the combined templating effect of both components at different scales. Gelatin is able to activate silica formation resulting in hybrid aggregates at the nanoscale. Alginic acid does not interfere with silica condensation but is able to control silica morphology through the assembly of these gelatin–silica aggregates at the microscale. For all materials, calcination up to 700 °C degrades the polymer component of the hybrid material and opens macroporosity in the silica network. In parallel, the high thermal stability of gelatin allows a good preservation of initial silica nanoparticle size upon heating whereas a coarsening process is observed in the sole presence of alginate. These results correlate well with previous models of biosilicification and suggest that the use of multiple templates is a suitable approach to elaborate more complex silica architectures.
doi_str_mv	10.1016/j.colsurfb.2008.03.005
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subjects	Alginate Alginates - chemistry Alginates - metabolism Bacillariophyceae Biomimetics Biomimetism Chemical Precipitation Chemical Sciences Dual templating Gelatin Gelatin - chemistry Gelatin - metabolism Glucuronic Acid - chemistry Glucuronic Acid - metabolism Hexuronic Acids - chemistry Hexuronic Acids - metabolism Inorganic chemistry Macromolecular Substances - metabolism Microscopy, Electron, Scanning Microscopy, Electron, Transmission Models, Biological Silica Silicon Dioxide - metabolism
title	Biomimetic dual templating of silica by polysaccharide/protein assemblies
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