dc.description.abstract |
Collagen is the most abundant proteins in soft and hard tissues of the mammals,
and collagen of several types form different hierarchy levels of these tissues by assembling
at various length scales. Due to lack of availability of complete information on the
mechanical characteristics of the individual collagen molecule as well as the assemblies
of collagen molecules, there is presently a dearth of knowledge pertaining to tissue
mechanics and disease progression which is primarily controlled by the structure
of tissues at molecular length scales. These tissues are heterogeneous, non-linear,
hydrated, viscoelastic, and their biochemical characterization is possible through
presently available instrumentation. Since hard and soft tissues are load-bearing,
the characterization of biochemical properties alone is insufficient for assessing the
healthy state and functionality of the tissues. Therefore, the information on the
mechanical characteristics of collagen at small length scales is very important.
Recent developments in the computing power and the availability of advanced
instrumentation have facilitated the mechanical characterization of collagen at small
length scales using computational and experimental methods. Atomistic modeling is a
very useful computational tool which is capable of determining the mechanical characteristics
of different materials at small length scales. However, due to unavailability
of all force-field parameters for various biomolecules and lack of sufficient computing
power, detailed information regarding the mechanical characteristics of collagen at
small length scales could not be determined through atomistic modeling. The advent
of nanoindentation technique has provided a method for estimating quasistatic and
time-dependent mechanical properties of a material, on a size scale compatible with tissue
dimensions in the controlled physiological environments. However, nanoindentation
theory and instrumentation were originally developed for hard, elastic-plastic materials,
and a limited nanoindentation work has been performed in the domain of biological
materials. Though most nanoindentation studies of biological materials have adopted
analytical and experimental methods originally derived for elastic-plastic materials, the
use of these methods for biological materials should only be made by understanding the methodology adopted for the estimation of material property from Load-Displacement
(L-D) data as well as various factors effecting the nanoindentation measurement.
The goal of the thesis is to characterize the mechanical properties of collagen
at small length scales using computational and experimental methods. In the present
work, atomistic modeling through molecular dynamics (MD) method has been used to
investigate the mechanical behaviour of collagen-like-peptides. The mechanical behavior
of individual collagen molecule as well as assemblies of collagen molecules is quantified
by measuring the strains along longitudinal and transverse directions when they are
subjected to various hydrostatic pressure magnitudes. The measurements of compressibility,
bulk modulus, linear compressibility and linear elastic modulus for individual
collagen molecule as well as assemblies of collagen molecules (in the form of micro-fibrils)
have been made by using atomistic model and incorporating continuum model using
linear elasticity theory. These measurements showed that individual collagen molecule
as well as assemblies of collagen molecules have almost similar mechanical response,
and they behave as transversely isotropic materials, and show higher stiffness at larger
strain magnitudes. For experimental work, the assemblies of collagen molecules have
been obtained from demineralization of cortical region of the bovine bone. Here, a well
defined protocol has been used to prepare samples surface with roughness (RMS) of the
order of few nanometers with the use of other complementary techniques like Atomic
force microscope (AFM), Scanning electron microscope (SEM), Energy dispersive X-ray
spectroscopy (EDX). Instrumented indentation has been used to determine the mechanical
characteristics of the assemblies of collagen molecules as well as their dependence on
loading rate, by performing quasistatic and dynamic nanoindentation respectively. The
modulus magnitudes of assemblies of collagen molecules quantified through dynamic
indentation also highlighted that the mechanical response of the assemblies of collagen
molecules is dependent on the loading rate. The modulus magnitudes for collagen at
small length scales obtained by using both computational and experimental approach
showed a good agreement. |
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