Your search keyword '"Dolbnya IP"' showing total 2 results

1. Hierarchical modelling of elastic behaviour of human enamel based on synchrotron diffraction characterisation.

Author

Sui T, Sandholzer MA, Baimpas N, Dolbnya IP, Landini G, and Korsunsky AM

Subjects

Algorithms, Dental Enamel diagnostic imaging, Durapatite chemistry, Humans, Models, Molecular, Molar chemistry, Molar diagnostic imaging, Scattering, Small Angle, Synchrotrons, X-Ray Diffraction, X-Ray Microtomography, Dental Enamel chemistry, Elastic Modulus

Abstract

Human enamel is a hierarchical mineralized tissue with a two-level composite structure. Few studies have focused on the structure-mechanical property relationship and its link to the multi-scale architecture of human enamel, whereby the response to mechanical loading is affected not only by the rod distribution at micro-scale, but also strongly influenced by the mineral crystallite shape, and spatial arrangement and orientation. In this study, two complementary synchrotron X-ray diffraction techniques, wide and small angle X-ray scattering (WAXS/SAXS) were used to obtain multi-scale quantitative information about the structure and deformation response of human enamel to in situ uniaxial compressive loading. The apparent modulus was determined linking the external load and the internal strain in hydroxyapatite (HAp) crystallites. An improved multi-scale Eshelby model is proposed taking into account the two-level hierarchical structure of enamel. This framework has been used to analyse the experimental data for the elastic lattice strain evolution within the HAp crystals. The achieved agreement between the model prediction and experiment along the loading direction validates the model and suggests that the new multi-scale approach reasonably captures the structure-property relationship for the human enamel. The ability of the model to predict multi-directional strain components is also evaluated by comparison with the measurements. The results are useful for understanding the intricate relationship between the hierarchical structure and the mechanical properties of enamel, and for making predictions of the effect of structural alterations that may occur due to the disease or treatment on the performance of dental tissues and their artificial replacements., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

2. The structural principles of multidomain organization of the giant polypeptide chain of the muscle titin protein: SAXS/WAXS studies during the stretching of oriented titin fibres.

Author

Vazina AA, Lanina NF, Alexeev DG, Bras W, and Dolbnya IP

Subjects

Animals, Connectin, Elasticity, Models, Biological, Models, Theoretical, Muscle Proteins isolation & purification, Muscle Proteins metabolism, Peptides chemistry, Peptides metabolism, Protein Conformation, Protein Kinases isolation & purification, Protein Kinases metabolism, Rabbits, Muscle Proteins chemistry, Muscles metabolism, Protein Kinases chemistry, X-Ray Diffraction methods

Abstract

Elasticity of titin is a key parameter that determines the mechanical properties of muscle. These include reversibility, i.e., the muscle's capacity to change its length many-fold and return to its original state, and the transduction of passive tension generated by the stretched muscle. The morphology and elastic properties of oriented fibres of titin molecules were studied using SAXS and WAXS (small- and wide-angle X-ray scattering, respectively) and mechanical techniques. We succeeded in obtaining oriented filaments of purified titin suitable for diffraction measurements. Our X-ray data suggest a model of titin as a nanoscale, morphological, and aperiodical array of rigid Ig- and Fn3-type domains covalently connected by conformationally variable short loops. The line group symmetry of the model can be defined as SM with axial translation tau(infinity). Both tension transduction and high elasticity of titin can be explained in terms of crystalline polymer physics. Titin stretching experiments show that each individual titin macromolecule can adopt a novel two-phase state within the fibre. Conversion between high elasticity and strength can be explained as a phase transition under external tension. In the terms of the concept of orientational melting the origin of the functional heterogeneity along the titin strand becomes interpretable.

Published

2006