Matthew D. Landrigan scite author profile

Experimental investigations for anatomic variation in the magnitude and anisotropy of elastic constants in human femoral cortical bone tissue have typically focused on a limited number of convenient sites near the mid-diaphysis. However, the proximal and distal ends of the diaphysis are more clinically relevant to common orthopaedic procedures and interesting mechanobiology. Therefore, the objective of this study was to measure anatomic variation in the elastic anisotropy and inhomogeneity of human cortical bone tissue along the entire length (15-85% of the total femur length) and around the periphery (anterior, medial, posterior and lateral quadrants) of the femoral diaphysis using ultrasonic wave propagation in the three orthogonal specimen axes. The elastic symmetry of tissue in the distal and extreme proximal portions of the diaphysis (15-45% and 75-85% of the total femur length, respectively) was, at most, orthotropic. In contrast, the elastic symmetry of tissue near the mid-and proximal mid-diaphysis (50-70% of the total femur length) was reasonably approximated as transversely isotropic. The magnitudes of elastic constants generally reached maxima near the mid-and proximal mid-diaphysis in the lateral and medial quadrants, and decreased toward the epiphyses, as well as the posterior and anterior quadrants. The elastic anisotropy ratio in the longitudinal and radial anatomic axes showed the opposite trends. These variations were significantly correlated with the apparent tissue density, as expected. In summary, the human femur exhibited statistically significant anatomic variation in elastic anisotropy, which may have important implications for whole bone numerical models and mechanobiology.

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Contrast-enhanced micro-computed tomography of fatigue microdamage accumulation in human cortical bone

Landrigan

Turnbull

et al. 2011

Bone

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Detection of dentinal cracks using contrast-enhanced micro-computed tomography

Landrigan

Flatley

Turnbull

et al. 2010

Journal of the Mechanical Behavior of Biomedical Materials

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Performance of a gravitational marrow separator, multidirectional bone marrow aspiration needle, and repeated bone marrow collections on the production of concentrated bone marrow and separation of mesenchymal stem cells in horses

Ishihara¹,

Helbig²,

Sanchez‐Hodge³

et al. 2013

ajvr

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Objective-To determine the efficiency of a novel point-of-care gravitational marrow separator and bone marrow aspiration needle for concentrated bone marrow production and bone marrow-derived mesenchymal stem cell (MSC) separation and assess the effect of repeated bone marrow collections in horses. Animals-8 healthy adult horses. Procedures-Bone marrow aspiration was performed twice (1 month apart) from sternebral bodies with a standard or prototype multidirectional needle. Concentrated bone marrow was obtained by gravitational marrow separation and evaluated for WBC and platelet counts, automated and cytomorphologic cell differential counts, MSCs, and cell viability. Results-Concentrated bone marrow samples obtained with the marrow separator had 5- to 19-fold bone marrow-derived MSC, WBC, and platelet counts, compared with original bone marrow samples. Use of a multidirectional needle increased the frequency of obtaining MSC-richer concentrated bone marrow. Repeating bone marrow aspiration at 1 month yielded greater MSC numbers but slightly lower cell viability after processing. Conclusions and Clinical Relevance-The gravitational bone marrow separator and multidirectional needle were used to effectively harvest bone marrow and improve the quality of concentrated bone marrow. Comparable, or even greater, numbers of bone marrow-derived MSCs were collected by repeated bone marrow aspiration after a 1-month interval from the same aspiration sites. Use of the marrow separator and multidirectional bone marrow aspiration needle can facilitate a 1-step, point-of-care, nonlaboratory method to obtain concentrated bone marrow as a mixture of bone marrow-derived MSCs and growth factors from platelets and plasma.

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Systematic error in mechanical measures of damage during four-point bending fatigue of cortical bone

Landrigan

Roeder

2009

Journal of Biomechanics

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Accumulation of fatigue microdamage in cortical bone specimens is commonly measured by a modulus or stiffness degradation after normalizing tissue heterogeneity by the initial modulus or stiffness of each specimen measured during a preloading step. In the first experiment, the initial specimen modulus defined using linear elastic beam theory (LEBT) was shown to be nonlinearly dependent on the preload level, which subsequently caused systematic error in the amount and rate of damage accumulation measured by the LEBT modulus degradation. Therefore, the secant modulus is recommended for measurements of the initial specimen modulus during preloading. In the second experiment, different measures of mechanical degradation were directly compared and shown to result in widely varying estimates of damage accumulation during fatigue. After loading to 400,000 cycles, the normalized LEBT modulus decreased by 26% and the creep strain ratio decreased by 58%, but the normalized secant modulus experienced no degradation and histology revealed no significant differences in microcrack density. The LEBT modulus was shown to include the combined effect of both elastic (recovered) and creep (accumulated) strain. Therefore, at minimum, both the secant modulus and creep should be measured throughout a test to most accurately indicate damage accumulation and account for different damage mechanisms. Histology further revealed indentation of tissue adjacent to roller supports, with significant sub-surface damage beneath large indentations, accounting for 22% of the creep strain on average. The indentation of roller supports resulted in inflated measures of the LEBT modulus degradation and creep. The results of this study suggest that investigations of fatigue microdamage in cortical bone should avoid the use of four-point bending unless no other option is possible.

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