Image-guided Computational and Experimental Analyses of Fractured Patient's Bone (GAP)

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The study of the mechanisms of bone damage, which occur at the multiscale, is of fundamental importance for the understanding of fracture processes. In particular, age-related fractures are continuously increasing due to the increase in average age and widespread diseases such as osteoporosis. They ...

The study of the mechanisms of bone damage, which occur at the multiscale, is of fundamental importance for the understanding of fracture processes. In particular, age-related fractures are continuously increasing due to the increase in average age and widespread diseases such as osteoporosis. They result in high economic burdens, morbidity (including psychological, e.g., frailty), and increased mortality. In order to reduce the impact of bone fractures on health and economy, early diagnosis is the key. In this context, one must consider that bone is characterized by a complex hierarchical structure. Both the cortical and trabecular sections consist of micrometric lamellae, composed of collagen fibrils, within which osteocytes are found. They reside in sub-micrometer cavities called lacunae, which are connected by a dense network of canaliculi. At the nanoscale, the fibrils consist primarily of collagen and hydroxyapatite crystals. This complex architecture is reflected in fracture patterns: damage, in fact, occurs at the multiscale. However, fracture patterns and their associated physical phenomena are still not understood, especially at the microscale. Recently, microscale imaging techniques have been combined with subject-specific numerical models, which are able to calculate local values of bone stress and strain. Preliminary studies have focused on evaluating a possible interaction between micro-cracks and microstructural porosity. This particular research focuses on the lacunar network, which is presumed to significantly affect bone resistance to fracture although the actual role of the lacunar network is not yet elucidated. First, lacunae are areas of stress concentration, which apparently lead to weakening of the bone structure. However, in most cases, the lacunae make a positive contribution to toughness by deflecting the crack front. The connection between the lacunae, determined by the network of canaliculi, is also reduced in osteoporotic subjects, preventing the slowing of damage. In this sense, bone can be considered a damage tolerant material. Donaldson et al developed computational models and estimated a threshold for microdamage initiation and propagation. They used computerized micro-tomography of murine femurs and evaluated the influence of different algorithms on the propagation of in-silico damage. Further results showed that the damage always occurs on the surfaces of blood vessels or porosities and does not instead start from the lacunae. However, further simulations and models would be needed to verify the effectiveness of the damage models. Computational damage models also require experimental validation. Preliminary studies have been conducted in two main directions: in-vivo imaging and image-guided failure assessment (IGFA) techniques. The first approach allows nondestructive monitoring of bone damage in living animals. The second approach, implemented by A. Levchuk et al. (8), shows enormous potential by allowing the study of microcrack initiation and propagation with sub-micrometer resolution, but only on small animals. The current research for the first time wants to perform tests on human bone samples applying IGFA techniques. Despite several studies on the characterization of damage models at the micro-scale, a validation of computational models of fracture on human subjects is still lacking. In addition, the role of morphological features at the micro-scale in samples is still unknown. These micro-scale studies could improve clinical understanding of bone fracture and prediction of fracture risk. Currently, clinicians use bone mineral density, which is a macro-scale parameter, as the most common predictor of bone fracture. However, recent studies demonstrate the importance of a thorough characterization of the geometric and morphologic characteristics of the microarchitecture. OBJECTIVES General Objective The study aims at the experimental validation of computational models of bone damage at the micro-scale. The general objective is pursued by controlled damage in a micro-compression machine on human bone samples from femoral head. The machinery is placed inside a synchrotron. Primary Objective The primary objective of the present study is to evaluate the difference in the attraction of bone damage with respect to gaps in the two groups considered (osteoporotic and non-osteoporotic) following micro-compression testing. The discriminating parameter chosen turns out to be the number of bone gaps encountered by micro-damage. We expect to observe an effect size of 0.4 between the two groups with respect to the chosen parameter. Secondary Objectives Determination of the role of gaps, canaliculi and other bone microstructures in damage. Human bone samples are scanned by micro-tomograph for the definition of microstructural morphological parameters and the realization and analysis of numerical models. Validation of these numerical models of damage by micro-compression tests carried out in situ in a synchrotron of adequate resolution Quantification of damage in human bone samples affected by osteoporosis Definition of micro-scale fracture indices, useful for the early diagnosis of osteoporosis

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