Agathe C. Fournier scite author profile

Proteins are the most specific yet versatile biological self-assembling agents with a rich chemistry. Nevertheless, the design of new proteins with recognition capacities is still in its infancy and has seldom been exploited for the self-assembly of functional inorganic nanoparticles. Here, we report on the protein-directed assembly of gold nanoparticles using purpose-designed artificial repeat proteins having a rigid but modular 3D architecture. αRep protein pairs are selected for their high mutual affinity from a library of 10(9) variants. Their conjugation onto gold nanoparticles drives the massive colloidal assembly of free-standing, one-particle thick films. When the average number of proteins per nanoparticle is lowered, the extent of self-assembly is limited to oligomeric particle clusters. Finally, we demonstrate that the aggregates are reversibly disassembled by an excess of one free protein. Our approach could be optimized for applications in biosensing, cell targeting, or functional nanomaterials engineering.

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Interactions of aluminium hydrolytic species with biomolecules

Deschaume

Fournier

Shafran

et al. 2008

New J. Chem.

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Potentiometric determination of the ‘formal’ hydrolysis ratio of aluminium species in aqueous solutions

Fournier¹,

Shafran²,

Perry³

2008

Analytica Chimica Acta

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Assembly of two- and three-dimensionally patterned silicate materials using responsive soft templates

2010

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We report a soft and straightforward method for synthesizing two- and three-dimensionally patterned silicate materials by phase separation using nonionic emulsion templates. Our liquid-state method involves, under controlled atmosphere, the mixing of a condensed silica solution with an oil-in-water emulsion in the presence of a solution of a nonionic emulsifier, Triton X-100. The preparation is stabilized using an organic solvent. The morphology of the silicate materials is significantly modified by changing the reaction conditions or the concentration of the reagents. Three-dimensionally macro and nanoporous continuous films and nanoporous individual spherical particles, both made of amorphous silica, are obtained. The structure of the films and particles is defined by the emulsion template. Films were on average 20 microm thick with a volume-based porosity of approximately 7 x 10(-2) cm(3) g(-1), with pore size correlating well with the size of the oil droplets in the templating emulsion. The siliceous films are bicontinuous leading to large surface areas and openly accessible pores. Individual spheres ranged in size from approximately 1 to 6 microm in diameter with nanoporous openings of 300 nm in diameter. The porosity and integrity of all materials are maintained upon calcination.

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