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Author: Bin Xu
Publisher:
ISBN:
Category :
Languages : en
Pages : 266
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Book Description
Abstract: Collagen is the most abundant protein in the body. It plays critical roles in many supporting and connecting tissues. Collagen matrices prepared from commercially available collagen solution have been broadly used as a biomaterial in tissue engineering, drug delivery, and wound healing for its biocompatibility, low toxicity, and well-documented physical, chemical, and immunological properties. Collagen matrices are also used as three-dimensional model systems of extracellular matrix (ECM) in numerous studies of cell-ECM interactions under physiological and pathological conditions. As a biphasic material, collagen matrices contain a solid phase representing by collagen network and an interstitial fluid phase. This special structure makes collagen a viscoelastic material. The overall research goal of this thesis is to characterize the macroscopic elastic and viscoelastic properties of collagen matrices in both the frequency and time domain and to understand the deformation mechanisms using a coupled experimental and modeling approach. Hydrated collagen gel and dehydrated collagen thin film are exploited as two different hydration levels of collagen matrices. Genipin solution is used to induce crosslinking in collagen matrices.Biaxial tensile stress relaxation results show that the rate of stress relaxation of both hydrated and dehydrated collagen matrices shows a linear initial stress level dependency. Increased crosslinking reduces viscosity in collagen gel, but the effect is negligible for thin film. Relaxation time distribution spectrum was obtained from the stress relaxation data by inverse Laplace transform. For most of the collagen matrices, three peaks at the short (0.3s ∼ 1s), medium (3s ∼ 90s), and long relaxation time (>200s) were observed in the continuous spectrum, which corresponds with relaxation mechanisms involve fiber, inter-fibril, and fibril sliding. The intensity of the long-term peaks increases with higher initial stress levels indicates the engagement of collagen fibrils at higher levels of tissue strain. Splitting of the middle peak was observed at higher initial stress levels suggesting increased structural heterogeneity at the fibril level with mechanical loading. A viscoelastic constitutive model combining hyperelastic and generalized Maxwell model was established with viscous material parameters obtained directly from analysis of the relaxation time spectrum.Rheological shear relaxation and dynamic rheological tests were performed on collagen gel. Crossover of storage and loss modulus was observed from frequency sweep tests. The crossover frequency shows both strain amplitude and crosslinking dependency. Both dynamic moduli and shear relaxation modulus demonstrate strain-softening behavior. Conversion from frequency domain measurements to time domain properties was achieved through relaxation spectrum obtained by Tikhonov regularization method. The relaxation spectrum shows two obvious peaks between 0.01s∼0.1s and between 10s∼40s, which indicate the existence of fast and slow dominant relaxation processes. The peak between 0.01∼0.1s correspond is likely due to the collagen fiber-interstitial fluid sliding. In shear deformation both collagen fiber network and interstitial fluid play important roles, which contribute to the differences in relaxation mechanisms between rheological shear and tensile relaxation tests.
Author: Bin Xu
Publisher:
ISBN:
Category :
Languages : en
Pages : 266
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Book Description
Abstract: Collagen is the most abundant protein in the body. It plays critical roles in many supporting and connecting tissues. Collagen matrices prepared from commercially available collagen solution have been broadly used as a biomaterial in tissue engineering, drug delivery, and wound healing for its biocompatibility, low toxicity, and well-documented physical, chemical, and immunological properties. Collagen matrices are also used as three-dimensional model systems of extracellular matrix (ECM) in numerous studies of cell-ECM interactions under physiological and pathological conditions. As a biphasic material, collagen matrices contain a solid phase representing by collagen network and an interstitial fluid phase. This special structure makes collagen a viscoelastic material. The overall research goal of this thesis is to characterize the macroscopic elastic and viscoelastic properties of collagen matrices in both the frequency and time domain and to understand the deformation mechanisms using a coupled experimental and modeling approach. Hydrated collagen gel and dehydrated collagen thin film are exploited as two different hydration levels of collagen matrices. Genipin solution is used to induce crosslinking in collagen matrices.Biaxial tensile stress relaxation results show that the rate of stress relaxation of both hydrated and dehydrated collagen matrices shows a linear initial stress level dependency. Increased crosslinking reduces viscosity in collagen gel, but the effect is negligible for thin film. Relaxation time distribution spectrum was obtained from the stress relaxation data by inverse Laplace transform. For most of the collagen matrices, three peaks at the short (0.3s ∼ 1s), medium (3s ∼ 90s), and long relaxation time (>200s) were observed in the continuous spectrum, which corresponds with relaxation mechanisms involve fiber, inter-fibril, and fibril sliding. The intensity of the long-term peaks increases with higher initial stress levels indicates the engagement of collagen fibrils at higher levels of tissue strain. Splitting of the middle peak was observed at higher initial stress levels suggesting increased structural heterogeneity at the fibril level with mechanical loading. A viscoelastic constitutive model combining hyperelastic and generalized Maxwell model was established with viscous material parameters obtained directly from analysis of the relaxation time spectrum.Rheological shear relaxation and dynamic rheological tests were performed on collagen gel. Crossover of storage and loss modulus was observed from frequency sweep tests. The crossover frequency shows both strain amplitude and crosslinking dependency. Both dynamic moduli and shear relaxation modulus demonstrate strain-softening behavior. Conversion from frequency domain measurements to time domain properties was achieved through relaxation spectrum obtained by Tikhonov regularization method. The relaxation spectrum shows two obvious peaks between 0.01s∼0.1s and between 10s∼40s, which indicate the existence of fast and slow dominant relaxation processes. The peak between 0.01∼0.1s correspond is likely due to the collagen fiber-interstitial fluid sliding. In shear deformation both collagen fiber network and interstitial fluid play important roles, which contribute to the differences in relaxation mechanisms between rheological shear and tensile relaxation tests.
Author: F. Henry M. Nestler
Publisher:
ISBN:
Category : Collagen
Languages : en
Pages : 206
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Book Description
Author: Stanley Kalsner
Publisher: Oxford University Press, USA
ISBN:
Category : Medical
Languages : en
Pages : 792
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Book Description
Author: Diana Marie Bordon
Publisher:
ISBN:
Category :
Languages : en
Pages : 88
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Book Description
Author: Roderic S. Lakes
Publisher: CRC Press
ISBN: 1351355643
Category : Technology & Engineering
Languages : en
Pages : 476
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Book Description
Viscoelastic Solids covers the mathematical theory of viscoelasticity and physical insights, causal mechanisms, and practical applications. The book: presents a development of the theory, addressing both transient and dynamic aspects as well as emphasizing linear viscoelasticity synthesizes the structure of the theory with the aim of developing physical insight illustrates the methods for the solution of stress analysis problems in viscoelastic objects explores experimental methods for the characterization of viscoelastic materials describes the phenomenology of viscoelasticity in a variety of materials, including polymers, metals, high damping alloys, rock, piezoelectric materials, cellular solids, dense composite materials, and biological materials analyzes high damping and extremely low damping provides the theory of viscoelastic composite materials, including examples of various types of structure and the relationships between structure and mechanical properties contains examples on the use of viscoelastic materials in preventing and alleviating human suffering Viscoelastic Solids also demonstrates the use of viscoelasticity for diverse applications, such as earplugs, gaskets, computer disks, satellite stability, medical diagnosis, injury prevention, vibration abatement, tire performance, sports, spacecraft explosions, and music.
Author: Seyed Hossein Ghodsi
Publisher:
ISBN:
Category :
Languages : en
Pages : 104
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Book Description
Collagen is the most abundant protein in mammals and has special mechanical behavior that enables it to play an important role in the structural integrity of many tissues, e.g., skin, tendon, bone, cartilage and blood vessels. The mechanical properties of collagen are governed by hierarchical mechanisms in different length-scales from molecule to tissue level. Currently, there is no multi-scale model that can predict the mechanical properties of collagen at macroscopic length scales from the behavior of microstructural elements at smaller length scales. This dissertation aimed at developing a multi-scale model using a bottom-up approach to predict the elastic and viscoelastic behaviors of collagen at length scales spanning from nano to microscale. Creep simulations were performed using steered molecular dynamics (SMD) method on collagen molecules, cross-link, and micro-fibrils with various lengths. A micro-fibril is considered as a combination of two collagen molecules connected by a cross-link. The strain time histories for force levels in the range of 10 to 4000 pN were characterized using quasilinear viscoelastic models. These models were utilized to make a reduced model of a micro-fibril and the reduced models, in turn, were combined to make a model of a fibril up to 300 micrometers in length. The micro-fibril and fibril models were validated with available experimental measurements. Hydrogen bonds rupture and formation of collagen molecule played a central role in its viscoelastic behavior and were used to estimate the creep growth rate. The propagation of force wave in the molecule was shown to be an important factor in providing the time-dependent properties of the fibrils. This propagation was modeled with delay elements and this allowed reducing the micro-fibril model to only three degrees of freedom. In conclusion, the results confirmed that the combination of molecular dynamics simulations and viscoelastic theory could be successfully utilized to investigate the viscoelastic behavior of collagen at small scales. The model reported in this dissertation, lays the groundwork for future studies on collagen, particularly in elucidating how each particular level of hierarchy affects the overall tissue behavior.
Author: Bela Suki
Publisher: Academic Press
ISBN: 0128226056
Category : Technology & Engineering
Languages : en
Pages : 284
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Book Description
Structure and Function of the Extracellular Matrix: A Multiscale Quantitative Approach introduces biomechanics and biophysics with applications to understand the biological function of the extracellular matrix in health and disease. A general multiscale approach is followed by investigating behavior from the scale of single molecules, through fibrils and fibers, to tissues of various organ systems. Through mathematical models and structural information, quantitative description of the extracellular matrix function is derived with tissue specific details. The book introduces the properties and organization of extracellular matrix components and quantitative models of the matrix, and guides the reader through predicting functional properties. This book integrates evolutionary biology with multiscale structure to quantitatively understand the function of the extracellular matrix. This approach allows a fresh look into normal functioning as well as the pathological alterations of the extracellular matrix. Professor Suki's book is written to be useful to undergraduates, graduate students, and researchers interested in the quantitative aspects of the extracellular matrix. Researchers working in mechanotransduction, respiratory and cardiovascular mechanics, and multiscale biomechanics of tendon, cartilage, skin, and bone may also be interested in this book. - Examines the evolutionary origins and consequences of the extracellular matrix - Delivers the first book to quantitatively treat the extracellular matrix as a multiscale system - Presents problems and a set of computational laboratory projects in various chapters to aid teaching and learning - Provides an introduction to the properties and organization of the extracellular matrix components
Author: Marjan Shayegan
Publisher:
ISBN:
Category :
Languages : en
Pages : 160
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Book Description
In this work, I aimed to develop and apply a technique capable of measuring the viscoelastic properties of collagen at different levels of hierarchy. Collagen is the predominant structural protein in vertebrates, and its self-assembly into well-defined structures including fibrils underlies the formation of a wide variety of biological structures with a broad range of functions. Here, in order to understand the correlation between collagen's structure and its mechanical properties, the viscoelastic properties of different collagen systems were characterized, ranging from solutions of molecules to self-assembled forms of fibrillar gels and gelatin. To determine rheological properties, optical tweezers were used to trap and monitor thermal fluctuations of an embedded micron-sized particle, producing measurements of viscoelastic response of collagen systems at a high bandwidth (> 10̂4 Hz). To validate these measurements, I reproduced results on a previously characterized system (polyethylene oxide). The obtained viscoelastic response is affected by the timescales of the interactions between polymers, which play a critical role in conferring elasticity to the system. To provide guidance to the microrheology experiments, the structure of collagen in acidic solution was probed using dynamic light scattering. My microrheology studies of collagen molecules in acidic solution showed that elastic response becomes comparable to viscous response at the highest concentration studied here, 5 mg/ml. Here, the significant elasticity observed at frequencies above ̃200 Hz is due to collagens' intermolecular interactions, which I found were not due to electrostatic interactions. However, elasticity was found to decrease following the removal of collagen's telopeptides, consistent with their role in facilitating fibril formation. At the fibrillar level, unlike in solutions of collagen, I observed spatial heterogeneity in viscoelastic properties. The elastic modulus varies by an order of magnitude at different locations within fibrillar collagen gels. By making measurements over 100-minute timescales as collagen self-assembled into fibrils, I probed the development of microscale heterogeneity and concluded that heterogeneity appears during early phases of fibrillar growth and continues to develop further during this growth phase.
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: Benno Maurus Nigg
Publisher:
ISBN:
Category : Medical
Languages : en
Pages : 696
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Book Description
The latest edition of this well organised and authoritative book provides a comprehensive account of the mechanics of the neuro-musculo-skeletal system. Covering the key areas including the properties of biomaterials, common measuring techniques and modelling, Biomechanics of the Musculo-skeletal System, Third Edition also integrates historical aspects thus building a bridge between old and familiar knowledge and the latest developments in biomechanics. As with the previous edition there are numerous applications and extensive questions and answers at the end of sections. Specific changes for this edition include: Major revision of the section on biological materials including bone, cartilage, ligament, tendon, muscle and joints and new discussion of failure and healing Extensive updating of material covering force, pressure distribution, optical methods and simulation Increase in the number and type of applications across a broad range of disciplines Biomechanics of the Musculo-skeletal System, Third Edition is an invaluable resource for all students, professionals and researchers concerned with biomechanical aspects of the human or animal body.
