Your search keyword '"Bertinetti L"' showing total 6 results

1. Effect of collagen packing and moisture content on leather stiffness.

Author

Kelly SJR, Weinkamer R, Bertinetti L, Edmonds RL, Sizeland KH, Wells HC, Fratzl P, and Haverkamp RG

Subjects

Animals, Biomechanical Phenomena, Elastic Modulus, Tensile Strength, Collagen metabolism, Mechanical Phenomena, Skin metabolism

Abstract

Applications for skin derived collagen materials, such as leather and acellular dermal matrices, usually require both strength and flexibility. In general, both the tensile modulus (which has an impact on flexibility) and strength are known to increase with fiber alignment, in the tensile direction, for practically all collagen-based tissues. The structural basis for flexibility in leather was investigated and the moisture content was varied. Small angle X-ray scattering was used to determine collagen fibril orientation, elongation and lateral intermolecular spacing in leather conditioned by different controlled humidity environments. Flexibility was measured by a three point bending test. Leather was prepared by tanning under biaxial loading to create leather with increased fibril alignment and thus strength, but this treatment also increased the stiffness. As collagen aligns, it not only strengthens the material but it also stiffens because tensile loading is then applied along the covalent chain of the collagen molecules, rather than at an angle to it. Here it has been shown that with higher moisture content greater flexibility of the material develops as water absorption inside collagen fibrils produces a larger lateral spacing between collagen molecules. It is suggested that water provides a lubricating effect in collagen fibrils, enabling greater freedom of movement and therefore greater flexibility. When collagen molecules align in the strain direction during tanning, leather stiffens not only by the fiber alignment itself but also because collagen molecules pack closer together, reducing the ability of the molecules to move relative to each other., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2019

2. Osmotically driven tensile stress in collagen-based mineralized tissues.

Author

Bertinetti L, Masic A, Schuetz R, Barbetta A, Seidt B, Wagermaier W, and Fratzl P

Subjects

Air, Animals, Calcification, Physiologic, Cattle, Collagen chemistry, Compressive Strength, Male, Polyethylene Glycols chemistry, Tendons metabolism, Turkeys, Water chemistry, Water metabolism, Collagen metabolism, Minerals metabolism, Osmotic Pressure, Stress, Mechanical, Tensile Strength

Abstract

Collagen is the most abundant protein in mammals and its primary role is to serve as mechanical support in many extracellular matrices such as those of bones, tendons, skin or blood vessels. Water is an integral part of the collagen structure, but its role is still poorly understood, though it is well-known that the mechanical properties of collagen depend on hydration. Recently, it was shown that the conformation of the collagen triple helix changes upon water removal, leading to a contraction of the molecule with considerable forces. Here we investigate the influence of mineralization on this effect by studying bone and turkey leg tendon (TLT) as model systems. Indeed, TLT partially mineralizes so that well-aligned collagen with various mineral contents can be found in the same tendon. We show that water removal leads to collagen contraction in all cases generating tensile stresses up to 80MPa. Moreover, this contraction of collagen puts mineral particles under compression leading to strains of around 1%, which implies localized compressive loads in mineral of up to 800MPa. This suggests that collagen dehydration upon mineralization is at the origin of the compressive pre-strains commonly observed in bone mineral., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

3. Osmotic pressure induced tensile forces in tendon collagen.

Author

Masic A, Bertinetti L, Schuetz R, Chang SW, Metzger TH, Buehler MJ, and Fratzl P

Subjects

Animals, Bone and Bones pathology, Female, Molecular Dynamics Simulation, Muscle Contraction, Osmosis, Pressure, Rats, Rats, Sprague-Dawley, Scattering, Radiation, Spectrum Analysis, Raman, Stress, Mechanical, Temperature, Tensile Strength, Water chemistry, X-Ray Diffraction, X-Rays, Collagen chemistry, Osmotic Pressure, Tendons pathology

Abstract

Water is an important component of collagen in tendons, but its role for the function of this load-carrying protein structure is poorly understood. Here we use a combination of multi-scale experimentation and computation to show that water is an integral part of the collagen molecule, which changes conformation upon water removal. The consequence is a shortening of the molecule that translates into tensile stresses in the range of several to almost 100 MPa, largely surpassing those of about 0.3 MPa generated by contractile muscles. Although a complete drying of collagen would be relevant for technical applications, such as the fabrication of leather or parchment, stresses comparable to muscle contraction already occur at small osmotic pressures common in biological environments. We suggest, therefore, that water-generated tensile stresses may play a role in living collagen-based materials such as tendon or bone.

Published

2015

4. Quantifying degradation of collagen in ancient manuscripts: the case of the Dead Sea Temple Scroll.

Author

Schütz R, Bertinetti L, Rabin I, Fratzl P, and Masic A

Subjects

Animals, History, Ancient, Collagen analysis, Manuscripts as Topic history, Skin chemistry, Spectrum Analysis, Raman methods

Abstract

Since their discovery in the late 1940s, the Dead Sea Scrolls, some 900 ancient Jewish texts, have never stopped attracting the attention of scholars and the broad public alike, because they were created towards the end of the Second Temple period and the "time of Christ". Most of the work on them has been dedicated to the information contained in the scrolls' text, leaving physical aspects of the writing materials unexamined. They are, however, crucial for both historical insight and preservation of the scrolls. Although scientific analysis requires handling, it is essential to establish the state of degradation of these valued documents. Polarized Raman Spectroscopy (PRS) is a powerful tool for obtaining information on both the composition and the level of disorder of molecular units. In this study, we developed a non-invasive and non-destructive methodology that allows a quantification of the disorder (that can be related to the degradation) of protein molecular units in collagen fibers. Not restricted to collagen, this method can be applied also to other protein-based fibrous materials such as ancient silk, wool or hair. We used PRS to quantify the degradation of the collagen fibers in a number of fragments of the Temple Scroll (11Q19a). We found that collagen fibers degrade heterogeneously, with the ones on the surface more degraded than those in the core.

Published

2013

5. Ion-association complexes unite classical and non-classical theories for the biomimetic nucleation of calcium phosphate

Author

Habraken, W.J.E.M., Tao, J., Brylka, L.J., Friedrich, H., Bertinetti, L., Schenk, A.S., Verch, A., Dmitrovic, V., Bomans, P.H.H., Frederik, P.M., Laven, J., van der Schoot, P. P. A. M., Aichmayer, B., de With, G., DeYoreo, J.J., Sommerdijk, N.A.J.M., Theoretical Physics, Sub Inorganic Chemistry and Catalysis, Afd Theoretical Physics (ITF), Theoretical Physics, Sub Inorganic Chemistry and Catalysis, Afd Theoretical Physics (ITF), Materials and Interface Chemistry, and Soft Matter and Biological Physics

Subjects

Calcium Phosphates, Models, Molecular, Polymers, Static Electricity, Nucleation, General Physics and Astronomy, chemistry.chemical_element, Mineralogy, Crystal structure, Calcium, Microscopy, Atomic Force, General Biochemistry, Genetics and Molecular Biology, Apatite, law.invention, chemistry.chemical_compound, X-Ray Diffraction, Biomimetic Materials, law, Spectroscopy, Fourier Transform Infrared, Animals, Amorphous calcium phosphate, Particle Size, Crystallization, Octacalcium phosphate, Ions, Supersaturation, Multidisciplinary, Cryoelectron Microscopy, General Chemistry, Hydrogen-Ion Concentration, Kinetics, Durapatite, Models, Chemical, chemistry, Chemical engineering, visual_art, visual_art.visual_art_medium, Nanoparticles, Thermodynamics, Cattle, Collagen, Synchrotrons

Abstract

Despite its importance in many industrial, geological and biological processes, the mechanism of crystallization from supersaturated solutions remains a matter of debate. Recent discoveries show that in many solution systems nanometre-sized structural units are already present before nucleation. Still little is known about the structure and role of these so-called pre-nucleation clusters. Here we present a combination of in situ investigations, which show that for the crystallization of calcium phosphate these nanometre-sized units are in fact calcium triphosphate complexes. Under conditions in which apatite forms from an amorphous calcium phosphate precursor, these complexes aggregate and take up an extra calcium ion to form amorphous calcium phosphate, which is a fractal of Ca(2)(HPO(4))(3)(2-) clusters. The calcium triphosphate complex also forms the basis of the crystal structure of octacalcium phosphate and apatite. Finally, we demonstrate how the existence of these complexes lowers the energy barrier to nucleation and unites classical and non-classical nucleation theories.

Published

2013

6. In vitro bio-mineralization process

Author

Sandri, M., Tampieri, A., Bertinetti, L., and Adele Boskey

Subjects

Bone substitution, Bio-hybrid composites, Collagen, Hydroxyapatite