| People | Locations | Statistics |
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| Naji, M. |
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| Motta, Antonella |
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| Aletan, Dirar |
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| Mohamed, Tarek |
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| Ertürk, Emre |
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| Taccardi, Nicola |
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| Kononenko, Denys |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Bih, L. |
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| Casati, R. |
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| Muller, Hermance |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ospanova, Alyiya |
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| Blanpain, Bart |
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| Ali, M. A. |
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| Popa, V. |
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| Rančić, M. |
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| Ollier, Nadège |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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| Rignanese, Gian-Marco |
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Wolf, Stephan E.
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (41/41 displayed)
- 2023In situ mapping of biomineral skeletal proteins by molecular recognition imaging with antibody-functionalized AFM tipscitations
- 2023Evidence for liquid-liquid phase separation during the early stages of Mg-struvite formationcitations
- 2023The Impact of the Cellular Environment and Aging on Modeling Alzheimer's Disease in 3D Cell Culture Modelscitations
- 2022Influence of Taylor Vortex Flow on the Crystallization of l-Glutamic Acid as an Organic Model Compoundcitations
- 2022Correction: Progressive changes in crystallographic textures of biominerals generate functionally graded ceramics
- 2022Progressive changes in crystallographic textures of biominerals generate functionally graded ceramicscitations
- 2020The multiple stages towards crystal formation of L-glutamic acidcitations
- 2020From solutes to solids: towards a supramolecular view on mineralization processes
- 2019Bioinspired Materials: From Living Systems to New Concepts in Materials Chemistrycitations
- 2019Polymer-Functionalised Nanograins of Mg-Doped Amorphous Calcium Carbonate via a Flow-Chemistry Approachcitations
- 2019Phase-specific bioactivity and altered Ostwald ripening pathways of calcium carbonate polymorphs in simulated body fluidcitations
- 2019Nanoscale deformation mechanics reveal resilience in nacre of Pinna nobilis shellcitations
- 2019Mechanical improvement of calcium carbonate cements by in situ HEMA polymerization during hardeningcitations
- 2019Ultra-smooth and space-filling mineral films generated via particle accretion processescitations
- 2019Conical Nanoindentation Allows Azimuthally Independent Hardness Determination in Geological and Biogenic Mineralscitations
- 2019Designing Solid Materials from Their Solute State: A Shift in Paradigms toward a Holistic Approach in Functional Materials Chemistrycitations
- 2018Nanostructure, osteopontin, and mechanical properties of calcitic avian eggshellcitations
- 2017Desiccator Volume: A Vital Yet Ignored Parameter in CaCO<sub>3</sub> Crystallization by the Ammonium Carbonate Diffusion Methodcitations
- 2017Universal structure motifs in biominerals: a lesson from nature for the efficient design of bioinspired functional materialscitations
- 2016Nonclassical Crystallization in vivo et in vitro (I): Process-Structure-Property relationships of nanogranular biomineralscitations
- 2015Nanoscale assembly processes revealed in the nacroprismatic transition zone of Pinna nobilis mollusc shells.citations
- 2015Nanoscale assembly processes revealed in the nacroprismatic transition zone of Pinna nobilis mollusc shellscitations
- 2015Pseudomorphic transformation of amorphous calcium carbonate films follows spherulitic growth mechanisms and can give rise to crystal lattice tiltingcitations
- 2015Single nanogranules preserve intracrystalline amorphicity in biomineralscitations
- 2014Synthesis of Calcium Carbonate Biological Materials: How Many Proteins are Needed?citations
- 2013Synthesis of calcium carbonate biological materials: how many proteins are needed?citations
- 2012Merging models of biomineralisation with concepts of nonclassical crystallisation: is a liquid amorphous precursor involved in the formation of the prismatic layer of the Mediterranean Fan Mussel Pinna nobilis?citations
- 2011Strong Stabilization of Amorphous Calcium Carbonate Emulsion by Ovalbumin: Gaining Insight into the Mechanism of 'Polymer-Induced Liquid Precursor' Processescitations
- 2011Strong stabilization of amorphous calcium carbonate emulsion by ovalbumin: gaining insight into the mechanism of 'polymer-induced liquid precursor' processes.citations
- 2011Carbonate-coordinated metal complexes precede the formation of liquid amorphous mineral emulsions of divalent metal carbonatescitations
- 2010Formation of silicones mediated by the sponge enzyme silicatein-alphacitations
- 2009Evidence for biogenic processes during formation of ferromanganese crusts from the Pacific Oceancitations
- 2008Early homogenous amorphous precursor stages of calcium carbonate and subsequent crystal growth in levitated dropletscitations
- 2008Bioencapsulation of living bacteria (Escherichia coli) with poly(silicate) After transformation with silicatein-alpha genecitations
- 2008Reply to "Mirror Symmetry Breaking" of the centrosymmetric CaCO3 crystals with amino acidscitations
- 2008Nucleation and growth of CaCO(3) mediated by the egg-white protein ovalbumin: A time-resolved in situ study using small-angle neutron scatteringcitations
- 2008Poly(silicate)-metabolizing silicatein in siliceous spicules and silicasomes of demosponges comprises dual enzymatic activities (silica polymerase and silica esterase)citations
- 2007Phase selection of calcium carbonate through the chirality of adsorbed amino acidscitations
- 2007Analysis of the axial filament in spicules of the demosponge Geodia cydonium: Different silicatein composition in microscleres (asters) and megascleres (oxeas and triaenes)citations
- 2007Formation of giant spicules in the deep-sea hexactinellid Monorhaphis chuni (Schulze 1904): electron-microscopic and biochemical studiescitations
- 2007Phasenselektion von Calciumcarbonat durch die Chiralität adsorbierter Aminosäurencitations
Places of action
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article
Synthesis of Calcium Carbonate Biological Materials: How Many Proteins are Needed?
Abstract
In Nature, calcium carbonate biomineralizations are the most abundant mineralized structures of biological origin. Because many exhibit remarkable characteristics, several attempts have been made to use them as substitution materials for bone reconstruction or as models for generating biomimetic composites that exhibit tailored properties. CaCO3 biomineralizations contain small amounts of amalgamate of proteins and polysaccharides that are secreted during the calcification process. They contribute to control the morphology of the crystallites and to spatially organize them in well-defined microstructures. These macromolecules, collectively defined as the skeletal matrix, have been the focus of a large number of studies aiming at synthesizing in vitro ‘biomimetic’ materials, according to a bottom-up approach. However, recent proteomic investigations performed on the organic matrices associated to mollusc shells or to coral skeletons have quashed our hopes to generate, with only few ‘macromolecular ingredients’, biomimetic materials with properties approaching to those of natural biominerals. As a mean value, each matrix comprises a minimum of few tens of different proteins that seem to be strictly associated to calcium carbonate biominerals. Among the proteins that are currently detected, one finds RLCDs-containing proteins (Repetitive-Low-Complexity Domains), enzymes, proteins with protease inhibitors domains and at last, proteins that contains typical ECM (ExtraCellular Matrix) domains. Today, we still do not understand how the skeletal matrix works, and unveiling its complex functioning is one of the challenges for the coming decade, both from fundamental and applied viewpoints. Is it realistic to attempt generating ‘abiotically’, in a test tube at room temperature, biomimetic composites that mimic natural biomineralizations in their properties? If so, and by supposing that we know the individual functions of all the components of the matrix, is there a minimal number of proteins required for producing in vitro calcium carbonate biomaterials that ‘approximate’ natural biominerals? These issues are of importance for the future research directions in biomaterials science.