Filtering of matter symmetry properties by circularly polarized nonlinear optics

International audienceWe propose a direct readout of symmetry information in matter using nonlinear optics. From combinations of circularly and longitudinally polarized optical fields, we construct irreducible spherical field tensors for second- and third-order nonlinear processes. The coupling of these field tensors to the matter susceptibility tensors allows filtering out of the susceptibility symmetries independently of the sample orientation in the laboratory frame. Experimental demonstrations are conducted on microcrystals, in a microscopy configuration compatible with symmetry order imaging

Microscopic structural study of collagen aging in isolated fibrils using polarized second harmonic generation

International audiencePolarization resolved second harmonic generation (PSHG) is developed to study, at the microscopic scale, the impact of aging on the structure of type I collagen fibrils in two-dimensional coatings. A ribose-glycated collagen is also used to mimic tissue glycation usually described as an indicator of aging. PSHG images are analyzed using a generic approach of the molecular disorder information in collagen fibrils, revealing significant changes upon aging, with a direct correlation between molecular disorder and fibril diameters

Nanoscopic and Photonic Ultrastructural Characterization of Two Distinct Insulin Amyloid States

Two different conformational isoforms or amyloid strains of insulin with different cytotoxic capacity have been described previously. Herein these filamentous and fibrillar amyloid states of insulin were investigated using biophysical and spectroscopic techniques in combination with luminescent conjugated oligothiophenes (LCO). This new class of fluorescent probes has a well defined molecular structure with a distinct number of thiophene units that can adopt different dihedral angles depending on its binding site to an amyloid structure. Based on data from surface charge, hydrophobicity, fluorescence spectroscopy and imaging, along with atomic force microscopy (AFM), we deduce the ultrastructure and fluorescent properties of LCO stained insulin fibrils and filaments. Combined total internal reflection fluorescence microscopy (TIRFM) and AFM revealed rigid linear fibrous assemblies of fibrils whereas filaments showed a short curvilinear morphology which assemble into cloudy deposits. All studied LCOs bound to the filaments afforded more blue-shifted excitation and emission spectra in contrast to those corresponding to the fibril indicating a different LCO binding site, which was also supported by less efficient hydrophobic probe binding. Taken together, the multi-tool approach used here indicates the power of ultrastructure identification applying AFM together with LCO fluorescence interrogation, including TIRFM, to resolve structural differences between amyloid states

Thioflavine-T and Congo Red reveal the polymorphism of insulin amyloid fibrils when probed by polarization-resolved fluorescence microscopy.

International audienceAmyloid fibrils are protein misfolding structures that involve a β-sheet structure and are associated with the pathologies of various neurodegenerative diseases. Here we show that Thioflavine-T and Congo Red, two major dyes used to image fibrils by fluorescence assays, can provide deep structural information when probed by means of polarization-resolved fluorescence microscopy. Unlike fluorescence anisotropy or fluorescence detected linear dichroism imaging, this technique allows to retrieve simultaneously both mean orientation and orientation dispersion of the dye, used here as a reporter of the fibril structure. We have observed that insulin amyloid fibrils exhibit a homogeneous behavior over the fibrils' length, confirming their structural uniformity. In addition, these results reveal the existence of various structures among the observed fibrils' population, in spite of a similar aspect when imaged with conventional fluorescence microscopy. This optical nondestructive technique opens perspectives for in vivo structural analyses or high throughput screening

Génération de second harmonique de biomolécules: des acides aminés aux protéines

This thesis presents an experimental study of second-harmonic generation of biological molecules. The coherent nature of this process allows obtaining the symmetries of molecules whose size is less than the wavelengths used. The hyperpolarizabilities of aromatic amino acids were measured in solution and the hyperpolarizability of non-aromatic amino acids was measured indirectly through measurements on the collagen molecule. Thus, all the building blocks of proteins are characterized. Among the biological molecules, collagen has a very strong non-linear response despite the absence of harmonophore. A model of coherent summation of the fields reissued to understand the origin of the very high non-linear efficiency from the rigidity and the spatial arrangement of amino acids in triple helix. In the same way, the study of several peptides with one to four tryptophans has enabled us to quantify the importance of conformation and the ionic environment of proteins in the non-linear response. To provide additional information on nano systems, a new setup has been developed, combining two beams of excitation. Thus, the dipole and quadrupole radiation are differentiated to obtain the symmetry of molecular arrangements. Finally, the great sensitivity of the setup allows mapping in three dimensions, with the Hyper Rayleigh scattering, singles metal nanoparticles catch in a gelatin matrix.Au cours de ce travail, la génération de second harmonique optique des molécules biologiques a été étudiée. Cette technique optique non linéaire possède un caractère cohérent qui permet d'accéder aux propriétés de symétrie des molécules dont la taille est très inférieure aux longueurs d'onde optiques visibles utilisées et l'hyperpolarisabilité quadratique des acides aminés aromatiques a été mesurée en solution par diffusion non linéaire. L'hyperpolarisabilité des acides aminés non aromatiques a été obtenue de manière indirecte grâce à des mesures effectuées sur le collagène, une protéine ne contenant pas d'acide aminé aromatique. Le collagène possède en fait une très forte réponse non linéaire et fait l'objet d'études intenses en microscopie optique non linéaire. Par un modèle de sommation cohérente des champs harmoniques réémis, l'origine de la très forte efficacité non linéaire de cette protéine, liée à sa grande rigidité et à son organisation spatiale en triple hélice, a pu être obtenue. En parallèle, l'étude de plusieurs petits peptides synthétiques possédant de un à quatre tryptophanes a permis de comprendre la construction de la réponse optique non linéaire de ces objets à partir de motifs répétés. Par ailleurs, pour apporter des informations supplémentaires sur les nano systèmes, un nouveau montage expérimental a été développé. La grande sensibilité du montage a permis notamment d'atteindre la sensibilité d'une seule particule dans le volume sondé et de mettre en place un système de cartographie en trois dimensions par diffusion Hyper Rayleigh. La démonstration a été réalisée pour des nanoparticules métalliques uniques d'argent piégées dans une matrice de gélatine

Second Harmonic Generation of biomolecules : from amino acids to proteins

Au cours de ce travail, la génération de second harmonique optique des molécules biologiques a été étudiée. Cette technique optique non linéaire possède un caractère cohérent qui permet d’accéder aux propriétés de symétrie des molécules dont la taille est très inférieure aux longueurs d’onde optiques visibles utilisées et l’hyperpolarisabilité quadratique des acides aminés aromatiques a été mesurée en solution par diffusion non linéaire. L’hyperpolarisabilité des acides aminés non aromatiques a été obtenue de manière indirecte grâce à des mesures effectuées sur le collagène, une protéine ne contenant pas d’acide aminé aromatique. Le collagène possède en fait une très forte réponse non linéaire et fait l’objet d’études intenses en microscopie optique non linéaire. Par un modèle de sommation cohérente des champs harmoniques réémis, l’origine de la très forte efficacité non linéaire de cette protéine, liée à sa grande rigidité et à son organisation spatiale en triple hélice, a pu être obtenue. En parallèle, l’étude de plusieurs petits peptides synthétiques possédant de un à quatre tryptophanes a permis de comprendre la construction de la réponse optique non linéaire de ces objets à partir de motifs répétés. Par ailleurs, pour apporter des informations supplémentaires sur les nano systèmes, un nouveau montage expérimental a été développé. La grande sensibilité du montage a permis notamment d’atteindre la sensibilité d’une seule particule dans le volume sondé et de mettre en place un système de cartographie en trois dimensions par diffusion Hyper Rayleigh. La démonstration a été réalisée pour des nanoparticules métalliques uniques d’argent piégées dans une matrice de gélatineThis thesis presents an experimental study of second-harmonic generation of biological molecules. The coherent nature of this process allows obtaining the symmetries of molecules whose size is less than the wavelengths used. The hyperpolarizabilities of aromatic amino acids were measured in solution and the hyperpolarizability of non-aromatic amino acids was measured indirectly through measurements on the collagen molecule. Thus, all the building blocks of proteins are characterized. Among the biological molecules, collagen has a very strong non-linear response despite the absence of harmonophore. A model of coherent summation of the fields reissued to understand the origin of the very high non-linear efficiency from the rigidity and the spatial arrangement of amino acids in triple helix. In the same way, the study of several peptides with one to four tryptophans has enabled us to quantify the importance of conformation and the ionic environment of proteins in the nonlinear response. To provide additional information on nano systems, a new setup has been developed, combining two beams of excitation. Thus, the dipole and quadrupole radiation are differentiated to obtain the symmetry of molecular arrangements. Finally, the great sensitivity of the setup allows mapping in three dimensions, with the Hyper Rayleigh scattering, singles metal nanoparticles catch in a gelatin matrix

Salt-induced Long-to-Short Range Orientational Transition in Water

International audienceWe report the long-range orientational organization of water using polarization-resolved second harmonic scattering operated in a right-angle configuration. A transition is observed between the neat water orientational organization involving an azimuthal molecular orientation distribution towards a radial molecular orientation distribution when salt is added. These two orientational phases are quantitatively described using a molecular model of the second harmonic scattering response. It is observed that the long-range correlation present in the neat water phase abruptly disappears and is replaced by a shorter range correlation centered around the ions as the salt concentration is increased

Second Harmonic Scattering Defined Topological Classes for Nano-Objects

International audienceNano-objects topology determination is a central question in nano-science and remains a challenge to achieve in absence of supporting substrate and atomic resolution techniques. In this work, we demonstrate how second harmonic scattering is sensitive to the balance between the nano-objects shape symmetry and size, thereby allowing for a second harmonic scattering defined topological definition. Although many data on nano-objects have been reported with this method so far, in most cases dispersed in liquid suspensions, no topological retrieval has been proposed. To reach this task, we have measured the second harmonic scattered light from a series of representative nano-objects along two collection directions for well-defined polarization states. The experimental results are then recast within a general framework involving nonlinear emitting sources and the size as critical elements. This analysis leads to the classification of the nano-objects according to the topology defined by their second harmonic scattering response. Current Size (2726 words) Nano-objects topology determination is a central question in nano-science and remains a challenge to achieve in absence of supporting substrate and an atomic resolution techniques like electron microscopy [1, 2]. With the fast development of the design and engineering of nano-objects aiming for many different applications, from functional materials to sensors, nanoprobes for microscopy or nanocapsules for drug delivery, the fine physical details of these nano-objects must be determined precisely [3]. Among these structure parameters, one may identify the material nature, the size, the shape or the morphology. In the latter case, plain solid or core-shell nanostructures for example can yield very different properties with great variety, notably in nano-optics. The shape of the nano-objects is likewise also a critical parameter

Generic model of the molecular orientational distribution probed by polarization-resolved second-harmonic generation

International audienceIn this work we investigate a generic method able to extract information on molecular organization in biological samples from polarized second harmonic generation (SHG) microscopy, without the need to infer an a priori model for the molecular orientational distribution. The mean orientation of this distribution, as well as its first and third orders of symmetry, are estimated by monitoring SHG intensity signals under a varying incident polarization. We introduce, in particular, a reduction of the problem to a two-dimensional approach appropriate to the microscopy geometry. This method allows us to retrieve determining information which is not available in the traditional model-oriented methods, as illustrated in molecular-order imaging in collagen fibrils. The precision of the parameters estimation is evaluated by a Monte Carlo analysis, based on the Poisson noise statistics of the measured signal