Aurélien Tidu scite author profile

This work aims at characterizing the three-dimensional organization of liquid crystals composed of collagen, in order to determine the physico-chemical conditions leading to highly organized structures found in biological tissues such as cornea. To that end, we use second-harmonic generation (SHG) microscopy, since aligned collagen structures have been shown to exhibit intrinsic SHG signals. We combine polarization-resolved SHG experiments (P-SHG) with the theoretical derivation of the SHG signal of collagen molecules tilted with respect to the focal plane. Our P-SHG images exhibit striated patterns with variable contrast, as expected from our analytical and numerical calculations for plywood-like nematic structures similar to the ones found in the cornea. This study demonstrates the benefits of P-SHG microscopy for in situ characterization of highly organized biopolymers at micrometer scale, and the unique sensitivity of this nonlinear optical technique to the orientation of collagen molecules.

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Highly concentrated collagen solutions leading to transparent scaffolds of controlled three-dimensional organizations for corneal epithelial cell colonization

Tidu

Ghoubay-Benallaoua

Teulon

et al. 2018

Biomater. Sci.

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This study aimed at controlling both the organization and the transparency of dense collagen scaffolds making use of the lyotropic mesogen properties of collagen. Cholesteric or plywood-like liquid crystal phases were achieved using mixtures of acetic and hydrochloric acids as solvents. The critical pH at which the switch between the two phases occurred was around pH = 3. The use of the two acids led to fibrillated collagen I scaffolds, whose visual aspect ranged from opaque to transparent. Rheological investigations showed that viscoelastic properties of the plywood-like solutions were optimized for molding due to faster recovery. They also confirmed the correlation between the elastic modulus and the diameter of collagen fibrils obtained after fibrillogenesis under ammonia vapor. Human corneal epithelial cells, grown from donor limbal explants, were cultured both on transparent plywood-like matrices and on human amniotic membranes for 14 days. The development of corneal epithelium and the preservation of epithelial stem cells were checked by optical microscopy, colony formation assay, immuno-fluorescence and quantitative polymerase chain reaction. A higher level of amplification of limbal stem cells was obtained with collagen matrices compared with amniotic membranes, showing the high biocompatibility of our scaffolds. We therefore suggest that collagen solutions presenting both plywood-like organization and transparency might be of interest for biomedical applications in ophthalmology.

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Development, structure, and bioengineering of the human corneal stroma: A review of collagen-based implants

Tidu

Schanne-Klein

Borderie

2020

Experimental Eye Research

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Microstructure evolution in polyamide PA11 under small uniaxial extension

Jolly

Tidu

Heizmann

et al. 2002

Polymer

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Study of CuAlBe Shape Memory Alloy by X-Ray Diffraction

Moreau¹,

Tidu²,

Barbe³

et al. 1995

J. Phys. IV France

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A complete study of Ms-30°C polycrystalline CuAlBe shape memory alloy is made by X Ray diffraction using a texture goniometer equipped with a curved position sensitive detector. Austenite and martensite unit cells parameters are measured. Measured indexes and orientation of the habit plane are compared to those expected by the lattice parameters. Austenite after extrusion shows a strong fiber texture, volumic fraction of austenite and martensite are measured according to the deformation. Internal deformations of three grains of a Ms-100°C CuALBe sample are followed during their macroscopic deformation.

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Processing and characterisation of nanocrystalline iron aluminide coatings prepared by thermal spraying of milled powders

Grosdidier

Liao

Lenhard³

et al. 2001

J. Phys. IV France

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Surface engineering by thermal spraying nanocrystalline coatings: X-ray and TEM characterisation of As-deposited iron aluminide structure

Morniroli

Tidu

et al. 2002

J. Phys. IV France

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Aurélien Tidu

Development of human corneal epithelium on organized fibrillated transparent collagen matrices synthesized at high concentration

Probing the 3D structure of cornea-like collagen liquid crystals with polarization-resolved SHG microscopy

Highly concentrated collagen solutions leading to transparent scaffolds of controlled three-dimensional organizations for corneal epithelial cell colonization

Development, structure, and bioengineering of the human corneal stroma: A review of collagen-based implants

Microstructure evolution in polyamide PA11 under small uniaxial extension

Study of CuAlBe Shape Memory Alloy by X-Ray Diffraction

Processing and characterisation of nanocrystalline iron aluminide coatings prepared by thermal spraying of milled powders

Surface engineering by thermal spraying nanocrystalline coatings: X-ray and TEM characterisation of As-deposited iron aluminide structure

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