Fibril

Fibrils (from the Latin fibra) are structural biological materials found in nearly all living organisms. Not to be confused with fibers or filaments, fibrils tend to have diameters ranging from 10-100 nanometers (whereas fibers are micro to milli-scale structures and filaments have diameters approximately 10-50 nanometers in size). Fibrils are not usually found alone but rather are parts of greater hierarchical structures commonly found in biological systems. Due to the prevalence of fibrils in biological systems, their study is of great importance in the fields of microbiology, biomechanics, and materials science. Fibrils (from the Latin fibra) are structural biological materials found in nearly all living organisms. Not to be confused with fibers or filaments, fibrils tend to have diameters ranging from 10-100 nanometers (whereas fibers are micro to milli-scale structures and filaments have diameters approximately 10-50 nanometers in size). Fibrils are not usually found alone but rather are parts of greater hierarchical structures commonly found in biological systems. Due to the prevalence of fibrils in biological systems, their study is of great importance in the fields of microbiology, biomechanics, and materials science. Fibrils are composed of linear biopolymers, and are characterized by rod-like structures with high length-to-diameter ratios. Oftentimes, they spontaneously arrange into helical structures. In biomechanics problems, fibrils can be characterized as classical beams with a roughly circular cross-sectional area on the nanometer scale. As such, simple beam bending equations can be applied to calculate flexural strength of fibrils under ultra-low loading conditions. Like most biopolymers, stress-strain relationships of fibrils tend to show a characteristic toe-heel region before a linear, elastic region. Unlike biopolymers, fibrils do not behave like homogeneous materials, as yield strength has been shown to vary with volume, indicating structural dependencies. Differences in structure between fibrils of different origin is typically determined by x-ray diffraction. A scanning electron microscope (SEM) can be used to observe specific details on larger fibril species such as the characteristic 67 nm bands in collagen, but often is not fine enough to determine the full structure. Hydration has been shown to produce a noticeable effect in the mechanical properties of fibrillar materials. The presence of water has been shown to decrease the stiffness of collagen fibrils, as well as increase their rate of stress relaxation and strength. From a biological standpoint, water content acts as a toughening mechanism for fibril structures, allowing for higher energy absorption and greater straining capabilities. Fibrillogenesis is the expansion of fine fibrils which is common in collagen fibers of connective tissue. The definite mechanisms of fibrillogenesis are still unknown, although many hypotheses resulting from basic research help discover many possible mechanisms. In early experiments, collagen I could be distilled from tissues and recombined into fibrils with controlling the solutions. Later studies help understand the composition and structure of binding sites on the collagen monomers. Collagen is synthesized as a soluble precursor, procollagen, which supports collagen self-assembly. Since collagen fibrils have almost 50 binding components in vivo, the definite requirement to generate fibrillogenesis in vivo is still cryptic. With acidic or saline solution, collagen can be extracted from tissues and rearrange into fibril by changing temperature or pH value. Experiments discovered attractive force between collagen monomers which helps the rearrangement. Collagen serves as a precursor, procollagen, in synthesizing reaction, which identifies self-polymerization of collagen. There are over 30 collagens in nature that are similar in chemical composition but differ in terms of crystal structure. By far, collagen I and II are the most abundant. They initiatively form fibrils in vitro, while fibronectin, fibronectin-binding, collagen-binding integrins and collagen V are essential for collagen I forming and collagen XI for collagen II forming. Therefore, cellular mechanisms play key role in the protein self-assembly process. Collagen is the major structural protein outside cells in many connective tissues of animals. As the primary component of connective tissue, it has the largest amount among protein in mammals, occupying 25% to 35% of all protein content in the body.