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3. The effects of tensile-compressive loading mode and microarchitecture on microdamage in human vertebral cancellous bone

Author

Lambers, Floor M, Bouman, Amanda R, Tkachenko, Evgeniy V, Keaveny, Tony M, and Hernandez, Christopher J

Subjects
Bioengineering, Clinical Research, Osteoporosis, Aged, Biomechanical Phenomena, Bone Remodeling, Bone Resorption, Bone and Bones, Elastic Modulus, Female, Humans, Lumbar Vertebrae, Male, Middle Aged, Pressure, Stress, Mechanical, Tensile Strength, Weight-Bearing, Bone mechanics, Microdamage, Cancellous bone, Microarchitecture, Resorption cavities, Biomedical Engineering, Mechanical Engineering, Human Movement and Sports Sciences
Abstract

The amount of microdamage in bone tissue impairs mechanical performance and may act as a stimulus for bone remodeling. Here we determine how loading mode (tension vs. compression) and microstructure (trabecular microarchitecture, local trabecular thickness, and presence of resorption cavities) influence the number and volume of microdamage sites generated in cancellous bone following a single overload. Twenty paired cylindrical specimens of human vertebral cancellous bone from 10 donors (47–78 years) were mechanically loaded to apparent yield in either compression or tension, and imaged in three dimensions for microarchitecture and microdamage (voxel size 0.7×0.7×5.0 μm3). We found that the overall proportion of damaged tissue was greater (p=0.01) for apparent tension loading (3.9±2.4%, mean±SD) than for apparent compression loading (1.9±1.3%). Individual microdamage sites generated in tension were larger in volume (p

Published
2014

10. Influence of limb positioning during image acquisition on femoral torsion measurements: implications for surgical planning.

Author

Guidetti, Martina, Lambers, Floor M., Kohnen, Michael, Malloy, Philip, Mather III, Richard C., Genuario, James W., and Nho, Shane J.

Subjects
ABDUCTION (Kinesiology), IMAGE registration, DIHEDRAL angles, FEMUR, ROTATIONAL motion, TORSION, ADDUCTION, ABDUCTION
Abstract

Femoral torsion is an important parameter to accurately quantify when planning for the correction of structural pathomorphology. The purpose of this study was to quantify the influence of limb positioning during image acquisition and of alignment techniques on femoral torsion measurements, by measuring the change in femoral torsion angle, upon digital rotations that simulate flexion/extension and adduction/abduction positions of the femur. Femoral torsion measurements were reduced up to 1° and increased up to 0.35° per each degree of flexion and abduction, respectively. The estimation of femoral torsion measurements yielded a difference up to 5.8° between the aligned and non-aligned cases. [ABSTRACT FROM AUTHOR]

Published
2023
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17. sj-pdf-1-ajs-10.1177_03635465221097118 – Supplemental material for Outcomes for the Arthroscopic Treatment of Femoroacetabular Impingement Syndrome With Acetabular Retroversion: A 3D Computed Tomography Analysis

Author

Alter, Thomas D., Knapik, Derrick M., Lambers, Floor, Sivasundaram, Lakshmanan, Malloy, Philip, Chahla, Jorge, and Nho, Shane J.

Subjects
FOS: Clinical medicine, 110323 Surgery, 110604 Sports Medicine, FOS: Health sciences, 110314 Orthopaedics
Abstract

Supplemental material, sj-pdf-1-ajs-10.1177_03635465221097118 for Outcomes for the Arthroscopic Treatment of Femoroacetabular Impingement Syndrome With Acetabular Retroversion: A 3D Computed Tomography Analysis by Thomas D. Alter, Derrick M. Knapik, Floor Lambers, Lakshmanan Sivasundaram, Philip Malloy, Jorge Chahla and Shane J. Nho in The American Journal of Sports Medicine

Published
2022
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29. The effects of tensile-compressive loading mode and microarchitecture on microdamage in human vertebral cancellous bone

Author

Lambers, Floor M., Bouman, Amanda R., Tkachenko, Evgeniy V., Keaveny, Tony M., and Christopher John Hernandez

Subjects
Male, Biomedical Engineering, Bioengineering, Stress, Bone and Bones, Weight-Bearing, Clinical Research, Tensile Strength, Elastic Modulus, Pressure, Humans, Bone Resorption, Microarchitecture, Aged, Lumbar Vertebrae, Cancellous bone, Mechanical Engineering, Human Movement and Sports Sciences, Middle Aged, Mechanical, Bone mechanics, Biomechanical Phenomena, Resorption cavities, Microdamage, Osteoporosis, Female, Bone Remodeling
Abstract

The amount of microdamage in bone tissue impairs mechanical performance and may act as a stimulus for bone remodeling. Here we determine how loading mode (tension vs. compression) and microstructure (trabecular microarchitecture, local trabecular thickness, and presence of resorption cavities) influence the number and volume of microdamage sites generated in cancellous bone following a single overload. Twenty paired cylindrical specimens of human vertebral cancellous bone from 10 donors (47–78 years) were mechanically loaded to apparent yield in either compression or tension, and imaged in three dimensions for microarchitecture and microdamage (voxel size 0.7×0.7×5.0 μm3). We found that the overall proportion of damaged tissue was greater (p=0.01) for apparent tension loading (3.9±2.4%, mean±SD) than for apparent compression loading (1.9±1.3%). Individual microdamage sites generated in tension were larger in volume (p

Published
2014

30. Local Mechanical Stimuli Regulate Bone Formation and Resorption in Mice at the Tissue Level

Author

Schulte, Friederike A., Ruffoni, Davide, Lambers, Floor M., Christen, David, Webster, Duncan J., Kuhn, Gisela, and Müller, Ralph

Subjects
Science, Image Processing, Osteopenia and Osteoporosis, Biomedical Engineering, Biophysics, Bioengineering, Models, Biological, Bone and Bones, Weight-Bearing, Mice, Engineering, Osteogenesis, Biological Systems Engineering, Animals, Biomechanics, Sports and Exercise Medicine, Bone Resorption, Biology, Computerized Simulations, Physics, Bone and Joint Mechanics, Computational Biology, Metabolic Disorders, Computer Science, Signal Processing, Medicine, Women's Health, Biophysic Al Simulations, Female, Bone Remodeling, Stress, Mechanical, Tomography, X-Ray Computed, Research Article, Computer Modeling
Abstract

Bone is able to react to changing mechanical demands by adapting its internal microstructure through bone forming and resorbing cells. This process is called bone modeling and remodeling. It is evident that changes in mechanical demands at the organ level must be interpreted at the tissue level where bone (re)modeling takes place. Although assumed for a long time, the relationship between the locations of bone formation and resorption and the local mechanical environment is still under debate. The lack of suitable imaging modalities for measuring bone formation and resorption in vivo has made it difficult to assess the mechanoregulation of bone three-dimensionally by experiment. Using in vivo micro-computed tomography and high resolution finite element analysis in living mice, we show that bone formation most likely occurs at sites of high local mechanical strain (p, PLoS ONE, 8 (4), ISSN:1932-6203

Published
2013

31. Customized mandibular reconstruction plates improve mechanical performance in a mandibular reconstruction model.

Author

Gutwald, Ralf, Jaeger, Raimund, and Lambers, Floor M.

Subjects
MANDIBULAR fractures, BIOMECHANICS, SENSITIVITY analysis, MANDIBLE, FATIGUE (Physiology)
Abstract

The purpose of this paper was to analyze the biomechanical performance of customized mandibular reconstruction plates with optimized strength. The best locations for increasing bar widths were determined with a sensitivity analysis. Standard and customized plates were mounted on mandible models and mechanically tested. Maximum stress in the plate could be reduced from 573 to 393 MPa (−31%) by increasing bar widths. The median fatigue limit was significantly greater (p < 0.001) for customized plates (650 ± 27 N) than for standard plates (475 ± 27 N). Increasing bar widths at case-specific locations was an effective strategy for increasing plate fatigue performance. [ABSTRACT FROM AUTHOR]

Published
2017
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42. Image interpolation allows accurate quantitative bone morphometry in registered micro-computed tomography scans.

Author

Schulte, Friederike A., Lambers, Floor M., Mueller, Thomas L., Stauber, Martin, and Müller, Ralph

Subjects
*MORPHOMETRICS, *BONE mechanics, *COMPUTED tomography, *SPLINES, *INTERPOLATION
Abstract

Time-lapsedin vivomicro-computed tomography is a powerful tool to analyse longitudinal changes in the bone micro-architecture. Registration can overcome problems associated with spatial misalignment between scans; however, it requires image interpolation which might affect the outcome of a subsequent bone morphometric analysis. The impact of the interpolation error itself, though, has not been quantified to date. Therefore, the purpose of thisex vivostudy was to elaborate the effect of different interpolator schemes [nearest neighbour, tri-linear and B-spline (BSP)] on bone morphometric indices. None of the interpolator schemes led to significant differences between interpolated and non-interpolated images, with the lowest interpolation error found for BSPs (1.4%). Furthermore, depending on the interpolator, the processing order of registration, Gaussian filtration and binarisation played a role. Independent from the interpolator, the present findings suggest that the evaluation of bone morphometry should be done with images registered using greyscale information. [ABSTRACT FROM AUTHOR]

Published
2014
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43. Longitudinal Assessment of In Vivo Bone Dynamics in a Mouse Tail Model of Postmenopausal Osteoporosis

Author

Lambers, Floor, Kuhn, Gisela, Schulte, Friederike, Koch, Kathleen, Müller, Ralph, Lambers, Floor, Kuhn, Gisela, Schulte, Friederike, Koch, Kathleen, and Müller, Ralph

Abstract

Recently, it has been shown that transient bone biology can be observed in vivo using time-lapse micro-computed tomography (μCT) in the mouse tail bone. Nevertheless, in order for the mouse tail bone to be a model for human disease, the hallmarks of any disease must be mimicked. The aim of this study was to investigate whether postmenopausal osteoporosis could be modeled in caudal vertebrae of C57Bl/6mice, considering static and dynamic bone morphometry as well as mechanical properties, and to describe temporal changes in bone remodeling rates. Twenty C57Bl/6mice were ovariectomized (OVX, n=11) or sham-operated (SHM, n=9) and monitored with in vivo μCT on the day of surgery and every 2weeks after, up to 12weeks. There was a significant decrease in bone volume fraction for OVX (−35%) compared to SHM (+16%) in trabecular bone (P<0.001). For OVX, high-turnover bone loss was observed, with the bone resorption rate exceeding the bone formation rate (P<0.001). Furthermore there was a significant decrease in whole-bone stiffness for OVX (−16%) compared to SHM (+11%, P<0.001). From these results we conclude that the mouse tail vertebra mimics postmenopausal bone loss with respect to these parameters and therefore might be a suitable model for postmenopausal osteoporosis. When evaluating temporal changes in remodeling rates, we found that OVX caused an immediate increase in bone resorption rate (P<0.001) and a delayed increase in bone formation rate (P<0.001). Monitoring transient bone biology is a promising method for future research

44. Functional bone imaging in an in vivo mouse model of bone adaptation, aging and disease

Author

Lambers, Floor M.

Subjects
KNOCHEN, SKELETT, OSTEOLOGIE (ANATOMIE UND PHYSIOLOGIE), TIERISCHE MODELLE IN DER MEDIZIN, MURIDAE (ZOOLOGIE), ABBILDUNGS- UND VISUALISIERUNGSVERFAHREN (BIOLOGISCHE TECHNIKEN), TOMOGRAPHIE + COMPUTERTOMOGRAPHIE (MEDIZINISCHE DIAGNOSTIK), MEDIZINISCHE IN-VIVO UNTERSUCHUNGEN, BIOPHYSIKALISCHE METHODEN UND TECHNIKEN, OSTEOPOROSE (PATHOLOGIE), OSTEOGENESE (CYTOLOGIE, HISTOLOGIE), ALTERSABHÄNGIGE EIGENSCHAFTEN + ALTERN (ANATOMIE UND PHYSIOLOGIE), BONES, SKELETON, OSTEOLOGY (ANATOMY AND PHYSIOLOGY), ANIMAL MODELS IN MEDICINE, MURIDAE (ZOOLOGY), IMAGING AND VISUALIZATION TECHNIQUES (BIOLOGICAL TECHNIQUES), TOMOGRAPHY + COMPUTER TOMOGRAPHY (MEDICAL DIAGNOSTICS), MEDICAL IN VIVO STUDIES, BIOPHYSICAL METHODS AND TECHNIQUES, OSTEOPOROSIS (PATHOLOGY), OSTEOGENESIS (CYTOLOGY, HISTOLOGY), AGE-DEPENDENT CHARACTERISTICS + AGEING (ANATOMY AND PHYSIOLOGY), Medical sciences, medicine
Published
2011

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