Mechanism of Bone Collagen Degradation due to KOH Treatment

BACKGROUND: The mechanisms underlying the effect of alterations in type I collagen on bone mechanical properties are not well defined. In a previous study, male and female emu tibiae were endocortically treated with 1M potassium hydroxide (KOH) solution for 1-14days. This treatment resulted in negligible mass loss (0.5%), collagen loss (0.05%), no differences in geometrical parameters but significant changes in mechanical properties. The objective of this study was to determine the mechanism of collagen degradation due to KOH treatment in order to explain the previously observed mechanical property changes. METHODS: Bone mineral was assessed using x-ray diffraction (XRD), microhardness and backscattered electron imaging (BSE). Bone collagen was assessed using α-chymotrypsin digestion, differential scanning calorimetry (DSC), gel electrophoresis (SDS-PAGE) and polarized light microscopy (PLM). RESULTS: BSE, microhardness and XRD revealed no changes in bone mineral due to KOH treatment. DSC showed an altered curve shape (lower and broader), indicating a change in collagen organization due to KOH treatment. Decreased α-chain band intensity in 14-day KOH treated groups detected using SDS-PAGE indicated α-chain fragmentation due to KOH treatment. PLM images revealed differences in collagen structure in terms of pattern distribution of preferentially oriented collagen between the periosteal and endocortical regions. CONCLUSION: These results suggest that endocortical KOH treatment causes in situ collagen degradation, which explains the previously reported altered mechanical properties. GENERAL SIGNIFICANCE: Compromising the organic component of bone contributes to an increase in bone fragility

Non Destructive Characterization of Cortical Bone MicroDamage by Nonlinear Resonant Ultrasound Spectroscopy

The objective of the study was to evaluate the ability of a nonlinear ultrasound technique, the so-called nonlinear resonant ultrasound spectroscopy (NRUS) technique, for detecting early microdamage accumulation in cortical bone induced by four-point bending fatigue. Small parallelepiped beam-shaped human cortical bone specimens were subjected to cyclic four-point bending fatigue in several steps. The specimens were prepared to control damage localization during four-point bending fatigue cycling and to unambiguously identify resonant modes for NRUS measurements. NRUS measurements were achieved to follow the evolution of the nonlinear hysteretic elastic behavior during fatigue-induced damage. After each fatigue step, a small number of specimens was removed from the protocol and set apart to quantitatively assess the microcrack number density and length using synchrotron radiation micro-computed tomography (SR-µCT). The results showed a significant effect of damage steps on the nonlinear hysteretic elastic behavior. No significant change in the overall length of microcracks was observed in damaged regions compared to the load-free control regions. Only an increased number of shortest microcracks, those in the lowest quartile, was noticed. This was suggestive of newly formed microcracks during the early phases of damage accumulation. The variation of nonlinear hysteretic elastic behavior was significantly correlated to the variation of the density of short microcracks. Our results suggest that the nonlinear hysteretic elastic behavior is sensitive to early bone microdamage. Therefore NRUS technique can be used to monitor fatigue microdamage progression in in vitro experiments.BONUS_07BLAN019