Bone fibrillogenesis and mineralization: Quantitative analysis and implications for tissue elasticity

• Published in: Journal of theoretical biology Vol. 287; pp. 115 - 130
• Main Authors: Vuong, Jenny, Hellmich, Christian
• Format: Journal Article
• Language: English
• Published: England Elsevier Ltd 21.10.2011; Elsevier
• Subjects: adulthood; Aging - physiology; Animals; Body Water; Bone; Bone and Bones - chemistry; Bone and Bones - diagnostic imaging; Bone and Bones - physiology; Bone Density - physiology; Bone Development - physiology; Calcification, Physiologic - physiology; childhood; collagen; Computer tomography; Continuum micromechanics; Desiccation; drying; Durapatite - analysis; Elasticity; Extracellular Matrix - physiology; hydroxyapatite; Life Sciences; mineral content; Mineralization; Minerals - analysis; osteoblasts; osteoclasts; quantitative analysis; Species Specificity; tissue engineering; Ultrasonography; Elasticity; Bone; Computer tomography; Mineralization; Continuum micromechanics; Fibrillogenesis; Computer Tomography; Tissue engineering; Biomaterials
• ISSN: 0022-5193; 1095-8541
• DOI: 10.1016/j.jtbi.2011.07.028

Data from bone drying, demineralization, and deorganification tests, collected over a time span of more than 80 years, evidence a myriad of different chemical compositions of different bone materials. However, careful analysis of the data, as to extract the chemical concentrations of hydroxyapatite, of water, and of organic material (mainly collagen) in the extracellular bone matrix, reveals an astonishing fact: it appears that there exists a unique bilinear relationship between organic concentration and mineral concentration, across different species, organs, and age groups, from early childhood to old age: During organ growth, the mineral concentration increases linearly with the organic concentration (which increases during fibrillogenesis), while from adulthood on, further increase of the mineral concentration is accompanied by a decrease in organic concentration. These relationships imply unique mass density-concentration laws for fibrillogenesis and mineralization, which – in combination with micromechanical models – deliver ‘universal’ mass density–elasticity relationships in extracellular bone matrix—valid across different species, organs, and ages. They turn out as quantitative reflections of the well-instrumented interplay of osteoblasts, osteoclasts, osteocytes, and their precursors, controlling, in a fine-tuned fashion, the chemical genesis and continuous transformation of the extracellular bone matrix. Consideration of the aforementioned rules may strongly affect the potential success of tissue engineering strategies, in particular when translating, via micromechanics, the aforementioned growth and mineralization characteristics into tissue-specific elastic properties. ► Organic and mineral concentrations in bone tissue follow bilinear relationship. ► Micromechanics provides experimentally validated mass density–elasticity relationships. ► This opens new routes for evaluation of Computer tomographic data.