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Author: Naghmeh Rezaei
Publisher:
ISBN:
Category :
Languages : en
Pages : 97
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Book Description
Collagen is a key component of the extracellular matrix and is the most abundant protein in vertebrates. Collagen is found in almost every connective tissue of the body including skin, bone, tendon, cartilage, arteries and cornea, where it plays a crucial role in providing structural support. Collagen molecules self-assemble to form hierarchical structures, from single molecules to fibrils to fibers and tissues. Structural and mechanical changes at the molecular level may affect self-assembly of the molecules and the resulting tissue. Despite its significance, the mechanics of collagen and its flexibility at the molecular level remain contentious, and collagen has been variously described as a flexible polymer to a semi-rigid rod. In this thesis, I present my work developing and utilizing experimental and analytical tools to study the mechanical proprieties of molecular collagen. I carefully designed and controlled a wide variety of experimental conditions, such as different collagen types and sources, solution pH and salt concentrations, and analysed the results in search of potential reasons for inconsistency in reported results of collagen flexibility at the basic molecular level. Atomic force microscopy (AFM) imaging is used to study effect of environmental factors such as ionic strength and pH on molecular conformations and flexibility of single collagen molecules. In addition, molecular conformations of different types of collagen from different sources are compared using AFM imaging. I measure persistence length of collagen molecules, a measure of flexibility, arising due to the conformational sampling of collagen. My results link the bending energy of collagen molecules to how tightly the helix is wound. In order to analyse AFM images of collagen, I developed an image and statistical analysis algorithm, SmarTrace, optimized for my images of collagen. The program was validated using images of DNA with known persistence length, then applied to collagen molecules. Analysis of different types of collagen in two different solutions and type I collagen in solutions of different ionic strength and pH show that collagen's flexibility depends strongly on ionic strength and pH. In addition, it shows that different types of collagen show similar average conformational characteristics in a given solution environment. In addition, mechanical properties and force-response of single collagen and procollagen molecules are studied using optical tweezers. I discuss the challenges of stretching single collagen proteins, whose length is much less than the size of the microspheres used as manipulation handles, and show how instrumental design and biochemistry can be used to overcome these challenges. The result of this work is an improved understanding of the sensitivity of molecular flexibility, stability and response of collagen to environmental factors. This can shed light on identifying underlying mechanisms of collagen-related diseases as well as designing and producing improved engineered biomaterials with tunable properties.
Author: Naghmeh Rezaei
Publisher:
ISBN:
Category :
Languages : en
Pages : 97
Get Book Here
Book Description
Collagen is a key component of the extracellular matrix and is the most abundant protein in vertebrates. Collagen is found in almost every connective tissue of the body including skin, bone, tendon, cartilage, arteries and cornea, where it plays a crucial role in providing structural support. Collagen molecules self-assemble to form hierarchical structures, from single molecules to fibrils to fibers and tissues. Structural and mechanical changes at the molecular level may affect self-assembly of the molecules and the resulting tissue. Despite its significance, the mechanics of collagen and its flexibility at the molecular level remain contentious, and collagen has been variously described as a flexible polymer to a semi-rigid rod. In this thesis, I present my work developing and utilizing experimental and analytical tools to study the mechanical proprieties of molecular collagen. I carefully designed and controlled a wide variety of experimental conditions, such as different collagen types and sources, solution pH and salt concentrations, and analysed the results in search of potential reasons for inconsistency in reported results of collagen flexibility at the basic molecular level. Atomic force microscopy (AFM) imaging is used to study effect of environmental factors such as ionic strength and pH on molecular conformations and flexibility of single collagen molecules. In addition, molecular conformations of different types of collagen from different sources are compared using AFM imaging. I measure persistence length of collagen molecules, a measure of flexibility, arising due to the conformational sampling of collagen. My results link the bending energy of collagen molecules to how tightly the helix is wound. In order to analyse AFM images of collagen, I developed an image and statistical analysis algorithm, SmarTrace, optimized for my images of collagen. The program was validated using images of DNA with known persistence length, then applied to collagen molecules. Analysis of different types of collagen in two different solutions and type I collagen in solutions of different ionic strength and pH show that collagen's flexibility depends strongly on ionic strength and pH. In addition, it shows that different types of collagen show similar average conformational characteristics in a given solution environment. In addition, mechanical properties and force-response of single collagen and procollagen molecules are studied using optical tweezers. I discuss the challenges of stretching single collagen proteins, whose length is much less than the size of the microspheres used as manipulation handles, and show how instrumental design and biochemistry can be used to overcome these challenges. The result of this work is an improved understanding of the sensitivity of molecular flexibility, stability and response of collagen to environmental factors. This can shed light on identifying underlying mechanisms of collagen-related diseases as well as designing and producing improved engineered biomaterials with tunable properties.
Author: Peter Fratzl
Publisher: Springer Science & Business Media
ISBN: 0387739068
Category : Technology & Engineering
Languages : en
Pages : 516
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Book Description
Not only does this book provide a comprehensive review of current research advances in collagen structure and mechanics, it also explores this biological macromolecule’s many applications in biomaterials and tissue engineering. Readers gain an understanding of the structure and mechanical behavior of type I collagen and collagen-based tissues in vertebrates across all length scales, from the molecular (nano) to the organ (macro) level.
Author: Aleksandr Noy
Publisher: Springer Science & Business Media
ISBN: 038749989X
Category : Science
Languages : en
Pages : 311
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Book Description
Researchers in academia and industry who are interested in techniques for measuring intermolecular forces will find this an essential text. It presents a review of modern force spectroscopy, including fundamentals of intermolecular forces, technical aspects of the force measurements, and practical applications. The handbook begins with a review of the fundamental physics of loading single and multiple chemical bonds on the nanometer scale. It contains a discussion of thermodynamic and kinetic models of binding forces and dissipation effects in nanoscale molecular contacts, covers practical aspects of modern single-molecule level techniques, and concludes with applications of force spectroscopy to chemical and biological processes. Computer modeling of force spectroscopy experiments is also addressed.
Author: Corey P. Neu
Publisher: CRC Press
ISBN: 1466588144
Category : Medical
Languages : en
Pages : 556
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Book Description
Emerging imaging techniques have opened new fronts to investigate tissues, cells, and proteins. Transformative technologies such as microCT scans, super-resolution microscopy, fluorescence-based tools, and other methods now allow us to study the mechanics of cancer, dissect the origins of cellular force regulation, and examine biological specimens
Author: Josephine Adams
Publisher: Academic Press
ISBN: 0080524966
Category : Science
Languages : en
Pages : 478
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Book Description
Critically acclaimed for more than 25 years, the Methods in Cell Biology series provides an indispensable tool for the researcher. Each volume is carefully edited by experts to contain state-of-the-art reviews and step-by-step protocols. Techniques are described completely so that methods are made accessible to users. This volume, Methods of Cell-Matrix Adhesion, contains integrated coverage on cell-matrix adhesion methods. It brings the classical methodologies and the latest techniques together in one concise volume. This coverage includes experimental protocols and their conceptual background for all aspects of cell-matrix adhesion research: the extracellular matrix, adhesion receptors, and the growing number of functional applications of matrix-adhesion in molecular cell biology. Also covered is the purification of the extracellular matrix to functional analyses of cellular responses.
Author: T.S.L Radhika
Publisher: CRC Press
ISBN: 1466588136
Category : Mathematics
Languages : en
Pages : 584
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Book Description
Approximate Analytical Methods for Solving Ordinary Differential Equations (ODEs) is the first book to present all of the available approximate methods for solving ODEs, eliminating the need to wade through multiple books and articles. It covers both well-established techniques and recently developed procedures, including the classical series solution method, diverse perturbation methods, pioneering asymptotic methods, and the latest homotopy methods. The book is suitable not only for mathematicians and engineers but also for biologists, physicists, and economists. It gives a complete description of the methods without going deep into rigorous mathematical aspects. Detailed examples illustrate the application of the methods to solve real-world problems. The authors introduce the classical power series method for solving differential equations before moving on to asymptotic methods. They next show how perturbation methods are used to understand physical phenomena whose mathematical formulation involves a perturbation parameter and explain how the multiple-scale technique solves problems whose solution cannot be completely described on a single timescale. They then describe the Wentzel, Kramers, and Brillown (WKB) method that helps solve both problems that oscillate rapidly and problems that have a sudden change in the behavior of the solution function at a point in the interval. The book concludes with recent nonperturbation methods that provide solutions to a much wider class of problems and recent analytical methods based on the concept of homotopy of topology.
Author: Susanta K Sarkar
Publisher: Morgan & Claypool Publishers
ISBN: 1681741806
Category : Science
Languages : en
Pages : 64
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Book Description
This is an overview of single molecule physics, the study of both equilibrium and non-equilibrium properties at the single molecule level. It begins with an introduction to this fascinating science and includes a chapter on how to build the most popular instrument for single molecule biophysics, the total internal reflection fluorescence (TIRF) microscope. It concludes with the Poisson process approach to statistical mechanics, explaining how to relate the process to diverse areas and see how data analysis and error bars are integral parts of science.
Author: Shu-Wei Chang (Ph. D.)
Publisher:
ISBN:
Category :
Languages : en
Pages : 155
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Book Description
Collagen is a crucial structural protein, formed through a hierarchical assembly of molecules, arranged in collagen fibrils, which constitutes the basis for larger-scale fibers. Normal type I collagen is a heterotrimer triple-helical molecule consisting of two alpha-1 chains and one alpha-2 chain. A mouse model of the genetic brittle bone disease, osteogenesis imperfecta, oim, is characterized by a replacement of the alpha-2 chain by an alpha-1 chain, resulting in a homotrimer collagen molecule. Experimental studies of oim mice tendon and bone have shown reduced mechanical strength compared to normal mice. The relationship between the molecular content and the decrease in strength is, however, still unknown. In this thesis, we use a bottom-up molecular simulation approach to examine the role of type I normal collagen and oim collagen from a single collagen molecule to collagen microfibril to mineralized collagen microfibril. At the molecular level, we find that the replacement of the alpha-2 chain results in a collagen molecule with more kinks and a more thermally stable cleavage site. The higher thermal stability of the cleavage site of the homotrimer explains the enzyme resistances of homotrimers. Furthermore, we reveal a molecular mechanism of force induced stabilization of collagen against enzymatic breakdown for the heterotrimer. At the fibril level, we find that the kinks affect the packing of collagen molecules. The homotrimer microfibril has a less dense packing of collagen molecules which leads to a reduced modulus. The alterations on the assembly of collagen molecules further alter the space for mineral deposition at the mineralized collagen fibril level. We find that the mineralized homotrimer collagen fibril has more space for mineral deposition but the mineral size is smaller because the kinks at the molecular level result in a more discontinuous space for mineral deposition. The mineralized oim collagen microfibril has a reduced modulus due to the alterations on the collagen assembly and mineral deposition. Our results provide fundamental insight into the effect of the loss of alpha-2 chain at the molecular level and help understanding the molecular origin of many diseases such as the brittle bone at much larger length-scales.
Author: Bharat Bhushan
Publisher: Springer
ISBN: 3319514334
Category : Technology & Engineering
Languages : en
Pages : 930
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Book Description
This textbook and comprehensive reference source and serves as a timely, practical introduction to the principles of nanotribology and nanomechanics. This 4th edition has been completely revised and updated, concentrating on the key measurement techniques, their applications, and theoretical modeling of interfaces. It provides condensed knowledge of the field from the mechanics and materials science perspectives to graduate students, research workers, and practicing engineers.
Author: Anne-Sophie Duwez
Publisher: CRC Press
ISBN: 1439809674
Category : Science
Languages : en
Pages : 285
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Book Description
With the invention of scanning probe techniques in the early 1980s, scientists can now play with single atoms, single molecules, and even single bonds. Force, dynamics, and function can now be probed at the single-molecule level. Molecular Manipulation with Atomic Force Microscopy (AFM) presents a series of topics that discuss concepts and methodol
