Your search keyword '"van Rietbergen B"' showing total 39 results

1. Image-based goal-oriented adaptive isogeometric analysis with application to the micro-mechanical modeling of trabecular bone

Author

Verhoosel, C.V., van Zwieten, G.J., van Rietbergen, B., and de Borst, R.

Published

2015

2. The Feasibility of High-Resolution Peripheral Quantitative Computed Tomography (HR-pQCT) in Patients with Suspected Scaphoid Fractures.

Author

Bevers, M.S.A.M., Daniels, A.M., Wyers, C.E., van Rietbergen, B., Geusens, P.P.M.M., Kaarsemaker, S., Janzing, H.M.J., Hannemann, P.F.W., Poeze, M., and van den Bergh, J.P.W.

Abstract

Introduction: Diagnosing scaphoid fractures remains challenging. High-resolution peripheral quantitative computed tomography (HR-pQCT) might be a potential imaging technique, but no data are available on its feasibility to scan the scaphoid bone in vivo. Methodology : Patients (≥18 years) with a clinically suspected scaphoid fracture received an HR-pQCT scan of the scaphoid bone (three 10.2-mm stacks, 61-μm voxel size) with their wrist immobilized with a cast. Scan quality assessment and bone contouring were performed using methods originally developed for HR-pQCT scans of radius and tibia. The contouring algorithm was applied on coarse hand-drawn pre-contours of the scaphoid bone, and the resulting contours (AUTO) were manually corrected (sAUTO) when visually deviating from bone margins. Standard morphologic analyses were performed on the AUTO- and sAUTO-contoured bones. Results : Ninety-one patients were scanned. Two out of the first five scans were repeated due to poor scan quality (40%) based on standard quality assessment during scanning, which decreased to three out of the next 86 scans (3.5%) when using an additional thumb cast. Nevertheless, after excluding one scan with an incompletely scanned scaphoid bone, post hoc grading revealed a poor quality in 14.9% of the stacks and 32.9% of the scans in the remaining 85 patients. After excluding two scans with contouring problems due to scan quality, bone indices obtained by AUTO- and sAUTO-contouring were compared in 83 scans. All AUTO-contours were manually corrected, resulting in significant but small differences in densitometric and trabecular indices (<1.0%). Conclusions : In vivo HR-pQCT scanning of the scaphoid bone is feasible in patients with a clinically suspected scaphoid fracture when using a cast with thumb part. The proportion of poor-quality stacks is similar to radius scans, and AUTO-contouring appears appropriate in good- and poor-quality scans. Thus, HR-pQCT may be promising for diagnosis of and microarchitectural evaluations in suspected scaphoid fractures. [ABSTRACT FROM AUTHOR]

Published

2020

3. Composition dependent mechanical behaviour of S53P4 bioactive glass putty for bone defect grafting.

Author

Van Gestel, N.A.P., Hulsen, D.J.W., Geurts, J., Hofmann, S., Ito, K., Arts, J.J., and Van Rietbergen, B.

Subjects

BIOACTIVE glasses, TRAUMATIC bone defects, BONE grafting, PUTTY, MECHANICAL behavior of materials

Abstract

To improve the handling properties of S53P4 bioactive glass granules for clinical applications, bioactive glass putty formulations were developed. These formulations contain both granules and a synthetic binder to form an injectable material that is easy to shape. To explore its applicability in load-bearing bone defect grafting, the relation between the putty composition and its mechanical behaviour was assessed in this study. Five putty formulations with variations in synthetic binder and granule content were mechanically tested in confined compression. The results showed that the impaction strains significantly decreased and the residual strains significantly increased with an increasing binder content. The stiffness of all tested formulations was found to be in the same range as the reported stiffness of cancellous bone. The measured creep strains were low and no significant differences between formulations were observed. The stiffness significantly increased when the samples were subjected to a second loading stage. The residual strains calculated from this second loading stage were also significantly different from the first loading stage, showing an increasing difference with an increasing binder content. Since residual strains are detrimental for graft layer stability in load-bearing defects, putty compositions with a low binder content would be most beneficial for confined, load-bearing bone defect grafting. [ABSTRACT FROM AUTHOR]

Published

2017

4. A computational spinal motion segment model incorporating a matrix composition-based model of the intervertebral disc.

Author

Barthelemy, V.M.P., van Rijsbergen, M.M., Wilson, W., Huyghe, J.M., van Rietbergen, B., and Ito, K.

Subjects

SPINE physiology, INTERVERTEBRAL disk, EXTRACELLULAR matrix, DEGENERATION (Pathology), BIOMECHANICS, FINITE element method

Abstract

The extracellular matrix of the intervertebral disc is subjected to changes with age and degeneration, affecting the biomechanical behaviour of the spine. In this study, a finite element model of a generic spinal motion segment that links spinal biomechanics and intervertebral disc biochemical composition was developed. The local mechanical properties of the tissue were described by the local matrix composition, i.e. fixed charge density, amount of water and collagen and their organisation. The constitutive properties of the biochemical constituents were determined by fitting numerical responses to experimental measurements derived from literature. This general multi-scale model of the disc provides the possibility to evaluate the relation between local disc biochemical composition and spinal biomechanics. [ABSTRACT FROM AUTHOR]

Published

2016

5. A survey of micro-finite element analysis for clinical assessment of bone strength: The first decade.

Author

van Rietbergen, B. and Ito, K.

Subjects

*FINITE element method, *BIOLOGICAL research, *BONE mechanics, *COMPUTED tomography, *BONE density, *CLINICAL trials, *HEALTH surveys

Abstract

Micro-Finite Element (micro-FE) analysis is now widely used in biomedical research as a tool to derive bone mechanical properties as they relate to its microstructure. With the development of in vivo high-resolution peripheral quantitative CT (HR-pQCT) scanners, it can now be applied to analyze bone in-vivo in the peripheral skeleton. In this survey, the results of several experimental and clinical studies are summarized that addressed the feasibility of this approach to predict bone strength in-vivo. Specific questions that will be addressed are: how accurate are strength predictions based on micro-FE; how reproducible are the results; and, is it a better predictor of bone fracture risk than DXA based measures? Based on results of experimental studies, it is first concluded that micro-FE based on HR-pQCT images can accurately predict the strength of the distal radius during a fall on the outstretched hand using either linear elastic analysis, implementing a 'Pistoia criterion' or similar criterion in combination with an 'effective' Young's modulus or using non-linear analyses. When evaluating results of clinical reproducibility studies, it is concluded that for single-center studies, errors at the radius are less than 4.4% and 3.7% and at the tibia less than 3.6% and 2.3% for stiffness and strength, respectively. In multicenter trials, however, these errors can be increased by some 1.8% and 1.4% for stiffness and strength, respectively. Finally, based on the results of large cohort studies, it is concluded that micro-FE calculated stiffness better separates cases from controls than bone density parameters for subjects with fragility fractures at any site, but not for subjects with only radius fractures. In this latter case, however, combinations of micro-FE derived parameters can significantly improve the separation. [ABSTRACT FROM AUTHOR]

Published

2015

6. Alterations to the subchondral bone architecture during osteoarthritis: bone adaptation vs endochondral bone formation.

Author

Cox, L.G.E., van Donkelaar, C.C., van Rietbergen, B., Emans, P.J., and Ito, K.

Abstract

Summary: Objective: Osteoarthritis (OA) is characterized by loss of cartilage and alterations in subchondral bone architecture. Changes in cartilage and bone tissue occur simultaneously and are spatially correlated, indicating that they are probably related. We investigated two hypotheses regarding this relationship. According to the first hypothesis, both wear and tear changes in cartilage, and remodeling changes in bone are a result of abnormal loading conditions. According to the second hypothesis, loss of cartilage and changes in bone architecture result from endochondral ossification. Design: With an established bone adaptation model, we simulated adaptation to high load and endochondral ossification, and investigated whether alterations in bone architecture between these conditions were different. In addition, we analyzed bone structure differences between human bone samples with increasing degrees of OA, and compared these data to the simulation results. Results: The simulation of endochondral ossification led to a more refined structure, with a higher number of trabeculae in agreement with the finding of a higher trabecular number in osteochondral plugs with severe OA. Furthermore, endochondral ossification could explain the presence of a “double subchondral plate” which we found in some human bone samples. However, endochondral ossification could not explain the increase in bone volume fraction that we observed, whereas adaptation to high loading could. Conclusion: Based on the simulation and experimental data, we postulate that both endochondral ossification and adaptation to high load may contribute to OA bone structural changes, while both wear and tear and the replacement of mineralized cartilage with bone tissue may contribute cartilage thinning. [ABSTRACT FROM AUTHOR]

Published

2013

7. The turnover of mineralized growth plate cartilage into bone may be regulated by osteocytes

Author

Cox, Lieke G.E., van Rietbergen, B., van Donkelaar, C.C., and Ito, K.

Subjects

*CARTILAGE, *OSTEOCYTES, *ENDOCHONDRAL ossification, *BONE remodeling, *HYPOTHESIS, *TIBIA, *CELLS, *TISSUES

Abstract

Abstract: During endochondral ossification, growth plate cartilage is replaced with bone. Mineralized cartilage matrix is resorbed by osteoclasts, and new bone tissue is formed by osteoblasts. As mineralized cartilage does not contain any cells, it is unclear how this process is regulated. We hypothesize that, in analogy with bone remodeling, osteoclast and osteoblast activity are regulated by osteocytes, in response to mechanical loading. Since the cartilage does not contain osteocytes, this means that cartilage turnover during endochondral ossification would be regulated by the adjacent bone tissue. We investigated this hypothesis with an established computational bone adaptation model. In this model, osteocytes stimulate osteoblastic bone formation in response to the mechanical bone tissue loading. Osteoclasts resorb bone near randomly occurring microcracks that are assumed to block osteocyte signals. We used finite element modeling to evaluate our hypothesis in a 2D-domain representing part of the growth plate and adjacent bone. Cartilage was added at a constant physiological rate to simulate growth. Simulations showed that osteocyte signals from neighboring bone were sufficient for successful cartilage turnover, since equilibrium between cartilage remodeling and growth was obtained. Furthermore, there was good agreement between simulated bone structures and rat tibia histology, and the development of the trabecular architecture resembled that of infant long bones. Additionally, prohibiting osteoclast invasion resulted in thickened mineralized cartilage, similar to observations in a knock-out mouse model. We therefore conclude that it is well possible that osteocytes regulate the turnover of mineralized growth plate cartilage. [Copyright &y& Elsevier]

Published

2011

8. Bone structural changes in osteoarthritis as a result of mechanoregulated bone adaptation: a modeling approach.

Author

Cox, L.G.E., van Rietbergen, B., van Donkelaar, C.C., and Ito, K.

Abstract

Summary: Objective: There are strong indications that subchondral bone may play an important role in osteoarthritis (OA), making it an interesting target for medical therapies. The subchondral bone structure changes markedly during OA, and it has long been assumed that this occurs secondary to cartilage degeneration. However, for various conditions that are associated with OA, it is known that they may also induce bone structural changes in the absence of cartilage degeneration. We therefore aimed to investigate if OA bone structural changes can result from mechanoregulated bone adaptation, independent of cartilage degeneration. Method: With a bone adaptation model, we simulated various conditions associated with OA –without altering the articular cartilage– and we evaluated if mechanoregulated bone remodeling by itself could lead to OA-like bone structural changes. Results: For each of the conditions, the predicted changes in bone structural parameters (bone fraction, trabecular thickness, trabecular number, and trabecular separation) were similar to those observed in OA. Conclusion: This indicates that bone adaptation in OA can be mechanoregulated with structural changes occurring independent of cartilage degeneration. [ABSTRACT FROM AUTHOR]

Published

2011

9. Indirect determination of trabecular bone effective tissue failure properties using micro-finite element simulations

Author

Verhulp, E., van Rietbergen, B., Müller, R., and Huiskes, R.

Subjects

*DEFORMATIONS (Mechanics), *ELASTIC solids, *MECHANICS (Physics), *RHEOLOGY

Abstract

Abstract: Trabecular bone strength is marked not only by the onset of local yielding, but also by post-yield behavior. To study and predict trabecular bone elastic and yield properties, micro-finite element (micro-FE) models were successfully applied. However, trabecular bone strength predictions require micro-FE models incorporating post-yield behavior of trabecular bone tissue. Due to experimental difficulties, such data is currently not available. Here we used micro-FE modeling to determine failure behavior of trabecular bone tissue indirectly, by iteratively fitting FE simulation to experimental results. Failure parameters were fitted to an isotropic plasticity model based on Hill''s yield function, using materially and geometrically nonlinear micro-FE models of seven bovine trabecular bone specimens. The predictive value of the averaged effective tissue properties was subsequently tested. The results showed that compression softening had to be included on the tissue level in order to accurately describe the apparent-level behavior of the bone specimens. A sensitivity study revealed that the simulated response was less sensitive to variations in the post-yield properties of the bone tissue than variations in the elastic and yield properties. Due to fitting of the tissue properties, apparent-level behavior could be accurately reproduced for each specimen separately. Predictions based on the averaged and fixed tissue properties were less accurate, due to inter-specimen variations in the tissue properties. [Copyright &y& Elsevier]

Published

2008

10. Load distribution in the healthy and osteoporotic human proximal femur during a fall to the side

Author

Verhulp, E., van Rietbergen, B., and Huiskes, R.

Subjects

*OSTEOPOROSIS, *BONE diseases, *ACCIDENTS, *PUBLIC health research, FEMUR abnormalities

Abstract

Abstract: Due to remodeling of bone architecture, an optimal structure is created that minimizes bone mass and maximizes strength. In the case of osteoporotic vertebral bodies, however, this process can create over-adaptation, making them vulnerable for non-habitual loads. In a recent study, micro-finite element models of a healthy and an osteoporotic human proximal femur were analyzed for the stance phase of gait. In the present study, tissue stresses and strains were calculated with the same proximal femur micro-finite element models for a simulated fall to the side onto the greater trochanter. Our specific objectives were to determine the contribution of trabecular bone to the strength of the proximal femurs for this non-habitual load. Further, we tested the hypothesis that the trabecular structure of osteoporotic bone is over-adapted to habitual loads. For that purpose, we calculated the load distributions and estimated the apparent yield and ultimate loads from linear analyses. Two different methods were used for this purpose, which resulted in very similar values, all in a realistic range. Distributions of maximal principal strain and effective strain in the entire model suggest that the contributions to bone strength of the trabecular and cortical structures are similar. However, a thick cortical shell is preferred over a dense trabecular core in the femoral neck. When the load applied to the osteoporotic femur was reduced to approximately 61% of the original value, strain distributions were created similar in value to those obtained for the healthy femur. Since a comparable reduction factor was found for habitual load cases, it was concluded that the osteoporotic femur was not ‘over-adapted’. [Copyright &y& Elsevier]

Published

2008

11. Comparison of micro-level and continuum-level voxel models of the proximal femur

Author

Verhulp, E., van Rietbergen, B., and Huiskes, R.

Subjects

*FINITE element method, *FEMUR, *NUMERICAL analysis, *BONES

Abstract

Abstract: Continuum-level finite element (FE) models became standard computational tools for the evaluation of bone mechanical behavior from in vivo computed tomography scans. Such scans do not account for the anisotropy of the bone. Instead, local mechanical properties in the continuum-level FE models are assumed isotropic and are derived from bone density, using statistical relationships. Micro-FE models, on the other hand, incorporate the anisotropic structure in detail. This study aimed to quantify the effects of assumed isotropy, by comparing continuum-level voxel models of a healthy and a severely osteoporotic proximal femur with recently analyzed micro-FE models of the same bones. The micro-model element size was coarsened to generate continuum FE models with two different element sizes (0.64 and 3.04mm) and two different density–modulus relationships found in the literature for wet and ash density. All FE models were subjected to the same boundary conditions that simulated a fall to the side, and the stress and strain distributions, model stiffness and yield load were compared. The results indicated that the stress and strain distributions could be reproduced well with the continuum models. The smallest differences between the continuum-level model and micro-level model predictions of the stiffness and yield load were obtained with the coarsest element size. Better results were obtained for both continuum-element sizes when isotropic moduli were based on ash density rather than wet density. [Copyright &y& Elsevier]

Published

2006

12. Thermal analysis of bone cement polymerisation at the cement–bone interface

Author

Stańczyk, M. and van Rietbergen, B.

Subjects

*POLYMETHYLMETHACRYLATE, *FINITE element method, *ACRYLIC resins, *COMPUTER simulation

Abstract

The two major problems that have been reported with the use of polymethylmethacrylate (PMMA) cement are thermal necrosis of surrounding bone due to the high heat generation during polymerisation and chemical necrosis due to unreacted monomer release. Computer models have been used to study the temperature and monomer distribution after cementation. In most of these models, however, polymerisation is modelled as temperature independent and cancellous bone is modelled as a continuum. Such models thus cannot account for the expected important role of the trabecular bone micro-structure. The aim of this study is to investigate the distribution of temperature and monomer leftover at the cancellous bone–cement interface during polymerisation for a realistic trabecular bone—cement micro-structure and realistic temperature-dependent polymerisation kinetics behaviour.A 3-D computer model of a piece of bovine cancellous bone that underwent pressurization with bone–cement was generated using a micro-computed tomography scanner. This geometry was used as the basis for a finite element model and a temperature-dependent problem for bone cement polymerisation kinetics was solved to simulate the bone cement polymerisation process in the vicinity of the interface. The transient temperature field throughout the interface was calculated, along with the polymerisation fraction distribution in the cement domain.The calculations revealed that the tips of the bone trabeculae that are embedded in the cement attain temperatures much higher than the average temperature of the bone volume. A small fraction of the bone (10%) is exposed to temperatures exceeding 70°C, but the exposure time to these high temperatures is limited to 50 s. In the region near the bone, the cement polymerisation fraction (about 84%) is less than that in the centre (where it is reaching values of over 96%). An important finding of this study thus is the fact that the bone tissue that is subjected to the highest temperatures is also subjected to high leftover monomer concentration. Furthermore the maximum bone temperature is reached relatively early, when monomer content in the neighbouring cement is still quite high. [Copyright &y& Elsevier]

Published

2004

13. The osteoporotic vertebral structure is well adapted to the loads of daily life, but not to infrequent “error” loads

Author

Homminga, J., Van-Rietbergen, B., Lochmüller, E.M., Weinans, H., Eckstein, F., and Huiskes, R.

Subjects

*VERTEBRAE injuries, *BONE fractures, *BONE injuries, *OSTEOPOROSIS, *BONE diseases

Abstract

Osteoporotic vertebral fractures typically have a gradual onset, frequently remain clinically undetected, and do not seem to be related to traumatic events. The osteoporotic vertebrae may therefore be expected to display a less “optimal” bone architecture, leading to an uneven load distribution over the bone material. We evaluated the trabecular load distribution in an osteoporotic and a healthy vertebra under normal daily loading by combining three recent innovations: high resolution computed tomography (μCT) of entire bones, microfinite element analyses (μFEA), and parallel supercomputers. Much to our surprise, the number of highly loaded trabeculae was not higher in the osteoporotic vertebra than in the healthy one under normal daily loads (8% and 9%, respectively). The osteoporotic trabeculae were more oriented in the longitudinal direction, compensating for effects of bone loss and ensuring adequate stiffness for normal daily loading. The increased orientation did, however, make the osteoporotic structure less resistant against collateral “error” loads. In this case, the number of overloaded trabeculae in the osteoporotic vertebra was higher than in the healthy one (13% and 4%, respectively). These results strengthen the paradigm of a strong relationship between bone morphology and external loads applied during normal daily life. They also indicate that vertebral fractures result from actions like forward flexion or lifting, loads that may not be “daily” but are normally not traumatic either. If future clinical imaging techniques would enable such high-resolution images to be obtained in vivo, the combination of μCT and μFEA would produce a powerful tool to diagnose osteoporosis. [Copyright &y& Elsevier]

Published

2004

14. Mechanical consequences of different scenarios for simulated bone atrophy and recovery in the distal radius

Author

Pistoia, W., van Rietbergen, B., and Rüegsegger, P.

Subjects

*OSTEOPOROSIS, *BONE density, *TOMOGRAPHY, *FINITE element method, *BONE diseases

Abstract

Metabolic bone diseases such as osteoporosis usually cause a decrease in bone mass and a deterioration of bone microarchitecture leading to a decline in bone strength. Methods to predict bone strength in patients are currently based on bone mass only. It has been suggested that an improved prediction of bone strength might be possible if structural changes are taken into account as well. In this study we evaluated which structural parameters (other than bone mass) are the best predictors for changes in bone mechanical properties of the human radius after different bone atrophy scenarios and whether the original strength of the affected bone can be recovered if bone loss is restored by thickening of the remaining structures. To answer these questions, a human radius was measured with a microcomputer tomography scanner to extract the full three-dimensional architecture of the distal radius at an isotropic resolution of 80 μm. Eight models with modified bone architecture were created and the mechanical variations due to these modifications were studied using microfinite element (micro-FE) simulations. In four models mass was lowered by 20%, either by reducing cortical thickness, trabecular thickness, or number of trabeculae or by overall thinning of structures. In the other four models bone mass was restored to the original value using a trabecular bone thickening procedure. The micro-FE analyses revealed that most load was carried by the cortical bone. For this reason, bone strength was affected most in the reduced cortical thickness model. For the same reason, the trabecular bone atrophy scenarios, all of which affected bone strength in a very similar way, resulted in less dramatic bone strength reduction. The restoration of bone mass did not recover the original bone strength. These findings demonstrate that the importance of different parameters for the prediction of bone strength also depends on the mechanical loading. This could explain why results of earlier studies on the importance of structural parameters can be inconsistent and site-dependent. [Copyright &y& Elsevier]

Published

2003

15. Pathways of load-induced cartilage damage causing cartilage degeneration in the knee after meniscectomy

Author

Wilson, W., van Rietbergen, B., van Donkelaar, C.C., and Huiskes, R.

Subjects

*CARTILAGE, *FINITE element method

Abstract

Results of both clinical and animal studies show that meniscectomy often leads to osteoarthritic degenerative changes in articular cartilage. It is generally assumed that this process of cartilage degeneration is due to changes in mechanical loading after meniscectomy. It is, however, not known why and where this cartilage degeneration starts. Load induced cartilage damage is characterized as either type (1)—damage without disruption of the underlying bone or calcified cartilage layer—or type (2), subchondral fracture with or without damage to the overlying cartilage. We asked the question whether cartilage degeneration after meniscectomy is likely to be initiated by type (1) and/or type (2) cartilage damage. To investigate that we applied an axisymmetric biphasic finite element analysis model of the knee joint. In this model the articular cartilage layers of the tibial and the femoral condyles, the meniscus and the bone underlying the articular cartilage of the tibia plateau were included. The model was validated with data from clinical studies, in which the effects of meniscectomy on contact areas and pressures were measured. It was found that both the maximal values and the distributions of the shear stress in the articular cartilage changed after meniscectomy, and that these changes could lead to both type (1) and type (2) cartilage damage. Hence it likely that the cartilage degeneration seen after meniscectomy is initiated by both type (1) and type (2) cartilage damage. [Copyright &y& Elsevier]

Published

2003

16. Estimation of distal radius failure load with micro-finite element analysis models based on three-dimensional peripheral quantitative computed tomography images

Author

Pistoia, W., van Rietbergen, B., Lochmüller, E.-M., Lill, C.A., Eckstein, F., and Rüegsegger, P.

Subjects

*BONES, *TOMOGRAPHY, *RADIAL bone

Abstract

There is increasing evidence that, in addition to bone mass, bone microarchitecture and its mechanical load distribution are important factors for the determination of bone strength. Recently, it has been shown that new high-resolution imaging techniques in combination with new modeling algorithms based on the finite element (FE) method can account for these additional factors. Such models thus could provide more relevant information for the estimation of bone failure load. The purpose of the present study was to determine whether results of whole-bone micro-FE (μFE) analyses with models based on three-dimensional peripheral quantitative computer tomography (3D-pQCT) images (isotropic voxel resolution of 165 μm) could predict the failure load of the human radius more accurately than results with dual-energy X-ray absorptiometry (DXA) or bone morphology measurements. For this purpose, μFE models were created using 54 embalmed cadaver arms. It was assumed that bone failure would be initiated if a certain percentage of the bone tissue (varied from 1% to 7%) would be strained beyond the tissue yield strain. The external force that produced this tissue strain was calculated from the FE analyses. These predictions were correlated with results of real compression testing on the same cadaver arms. The results of these compression tests were also correlated with results of DXA and structural measurements of these arms. The compression tests produced Colles-type fractures in the distal 4 cm of the radius. The predicted failure loads calculated from the FE analysis agreed well with those measured in the experiments (R2 = 0.75 p < 0.001). Lower correlations were found with bone mass (R2 = 0.48, p < 0.001) and bone structural parameters (R2 = 0.57 p < 0.001). We conclude that application of the techniques investigated here can lead to a better prediction of the bone failure load for bone in vivo than is possible from DXA measurements, structural parameters, or a combination thereof. [ABSTRACT FROM AUTHOR]

Published

2002

17. High-resolution MRI and micro-FE for the evaluation of changes in bone mechanical properties during longitudinal clinical trials: application to calcaneal bone in postmenopausal women after one year of idoxifene treatment.

Author

van Rietbergen B, Majumdar S, Newitt D, and MacDonald B

Published

2002

18. A Consensus Method for Determining Volumetric Joint Space Width in Finger Joints of Arthritis Patients Using HR-PQCT.

Author

Stok, K.S., Burhardt, A.J., Boutroy, S., Peters, M., Vilayphiou, N., van Rietbergen, B., Geusens, P., van den Bergh, J., Li, X., Marotte, H., Boyd, S.K., and Barnabe, C.

Published

2017

19. Quantifying joint stiffness in clubfoot patients.

Author

van der Steen, M.C., Andrei, P.A., van Rietbergen, B., Ito, K., and Besselaar, A.T.

Subjects

*ANKLE, *CLUBFOOT, *RANGE of motion of joints, *ORTHODONTIC appliances, *ORTHOPEDIC implants, *SHOES, *TORQUE, *ABDUCTION (Kinesiology), *SUBTALAR joint, *DORSIFLEXION

Abstract

Abstract Background In clinical practice, clubfeet feel stiffer compared to healthy feet. Furthermore, the clinical impression is that stiffer clubfeet have a higher tendency to relapse. Until now, no objective measure has been available to determine the stiffness of clubfeet. The goal of the current project was to objectively quantify ankle and subtalar joint stiffness in clubfeet patients and to compare this stiffness between clubfeet patients and healthy controls using a newly developed measurement device. Methods The newly developed Torque-Displacement-Handpiece in combination with an adjusted Abduction Dorsiflexion Mechanism clubfoot-brace, made it possible to move a foot over two rotational axis, while continuously capturing the applied torque and the achieved angulation. Based on this information, stiffness of the ankle and subtalar joint were assessed for 11 clubfoot patients with 17 clubfeet and 11 healthy subjects with 22 healthy feet. Findings With the Torque-Displacement-Handpiece measuring device it was possible to measure torque, angulation and stiffness in a reliable and precise manner. Clubfoot patients showed less angulation and a higher stiffness for measurements over the ADM subtalar axis compared to controls. After adjusting for shoe size, the stiffness for measurements over the ADM tibiotalar axis was also significantly higher in clubfeet than controls. Interpretation Overall, these results indicate that clubfoot patients have a higher ankle and subtalar joint stiffness in the affected joint compared to healthy controls. In the future, the Torque-Displacement-Handpiece could be used to monitor stiffness of clubfeet during treatment, and as such, play a potential role in the early detection of relapsing clubfeet. Highlights • The slope of torque-angulation graph is a measure for joint stiffness. • The Torque-Displacement-Handpiece is a precise and reliable device to measure ankle and subtalar joint stiffness. • Clubfeet have higher ankle stiffness compared to healthy controls. [ABSTRACT FROM AUTHOR]

Published

2018

20. Bone remodeling.

Author

Naili, S., van Rietbergen, B., Sansalone, V., and Taylor, D.

Published

2011

21. Impaired fracture healing by highly selective COX-2 inhibition.

Author

Janssen, M.P., Caron, M.M., van Rietbergen, B., Welting, T.J., and Emans, P.J.

Published

2013

22. 42 Bone Strength Obtained from Finite Element Analysis as Surrogate End Point for Osteoporosis.

Author

van Rietbergen, B.

Published

2009

23. L'analyse par éléments finis basée sur des images de radius distal obtenues in vivo par tomographie haute résolution est une technique très prometteuse pour améliorer la prédiction des fractures du poignet

Author

Boutroy, S, Van Rietbergen, B, Sornay-Rendu, E, Munoz, F, Bouxsein, ML, and Delmas, PD

Published

2007

24. Indirect determination of trabecular bone effective tissue properties using micro-finite element simulations

Author

Verhulp, E., van Rietbergen, B., Müller, R., and Hulskes, R.

Published

2006

25. Effects of early and late zoledronate treatment on bone microstructure in ovariectomized rats assessed by in vivo micro-CT

Author

Brouwers, J., van Rietbergen, B., and Huiskes, R.

Published

2006

26. Fracture history of healthy premenopausal women is associated with a reduction of cortical microstructural components at the distal radius.

Author

Chevalley, T., Bonjour, J.P., van Rietbergen, B., Ferrari, S., and Rizzoli, R.

Subjects

*PERIMENOPAUSE, *RADIUS bone injuries, *RISK factors of fractures, *BONE density, *COMPUTED tomography, *FINITE element method, *BONE physiology

Abstract

Objectives: The objective of this study is to determine in healthy premenopausal women with a history of fracture which bone structural components of the distal radius are the most closely associated with a risk of fracture. Methods and participants: The method was as follows: measurement of radial areal bone mineral density (aBMD) by DXA, microstructural components by high-resolution quantitative peripheral computerized tomography (HR-pQCT) and strength variables by micro Finite Element Analysis (μFEA) in 196 healthy premenopausal women aged 45.9±3.7 (±SD) years with (FX, n=96) and without (NO-FX, n=100) a history of fracture. We evaluated differences in T-scores between FX and NO-FX and risk of fracture by Odds ratios (OR with 95% confidence intervals, CI) per one SD decrease, using logistic regression analysis after adjustment for age, height, weight, menarcheal age, calcium and protein intakes, and physical activity. Results: In the whole group the mean radial metaphysis aBMD T-score was not significantly different from zero. In the FX as compared to the NO-FX group, the differences in T-scores were as follows: for radial metaphysis: aBMD, −0.24 (P =0.005); for distal radius microstructure components: cortical volumetric BMD, −0.38 (P =0.0009); cortical thickness, −0.37 (P =0.0001); cross-sectional area (CSA), +0.24 (P =0.034); and endosteal perimeter, +0.28 (P =0.032); and for strength estimates: stiffness, −0.15 (P =0.030); failure load, −0.14 (P =0.044); and apparent modulus, −0.28 (P =0.006). T-scores of trabecular volumetric BMD and thickness did not significantly differ between the FX and the NO-FX group. Accordingly, the risk of fracture (OR, 95% CI) for 1 SD decrease in radius bone parameters was as follows: radial metaphysis aBMD: 1.70 (1.18–2.44), P =0.004; cortical volumetric BMD: 1.86 (1.28–2.71), P =0.001; and cortical thickness: 2.36 (1.53–3.63), P =0.0001. The corresponding fracture risk for the strength estimates was as follows: stiffness: 1.66 (1.06–2.61), P =0.028; failure load: 1.59 (1.02–2.47), P =0.041; and apparent modulus: 1.76 (1.17–2.64), P =0.006. Conclusions: In healthy premenopausal women, a history of fracture is associated with reduced T-scores in the distal radius, with the cortical components showing the greatest deficit. A reduction of one SD in cortical thickness is associated with a nearly three-fold increased risk of fracture. This finding strengthens the notion that, in healthy women, a certain degree of bone structural fragility contributes to fractures before the menopause and therefore should be taken into consideration in the individual prevention strategy of postmenopausal osteoporosis. [ABSTRACT FROM AUTHOR]

Published

2013

27. Decreased bone tissue mineralization can partly explain subchondral sclerosis observed in osteoarthritis

Author

Cox, L.G.E., van Donkelaar, C.C., van Rietbergen, B., Emans, P.J., and Ito, K.

Subjects

*OSTEOARTHRITIS treatment, *BIOMINERALIZATION, *TARGETED drug delivery, *CARTILAGE, *BONE mechanics, *BIOLOGICAL adaptation

Abstract

Abstract: For many years, pharmaceutical therapies for osteoarthritis (OA) were focused on cartilage. However, it has been theorized that bone changes such as increased bone volume fraction and decreased bone matrix mineralization may play an important role in the initiation and pathogenesis of OA as well. The mechanisms behind the bone changes are subject of debate, and a better understanding may help in the development of bone-targeting OA therapies. In the literature, the increase in bone volume fraction has been hypothesized to result from mechanoregulated bone adaptation in response to decreased mineralization. Furthermore, both changes in bone volume fraction and mineralization have been reported to be highest close to the cartilage, and bone volume fraction has been reported to be correlated with cartilage degeneration. These data indicate that cartilage degeneration, bone volume fraction, and bone matrix mineralization may be related in OA. In the current study, we aimed to investigate the relationships between cartilage degeneration, bone matrix mineralization and bone volume fraction at a local level. With microCT, we determined bone matrix mineralization and bone volume fraction as a function of distance from the cartilage in osteochondral plugs from human OA tibia plateaus with varying degrees of cartilage degeneration. In addition, we evaluated whether mechanoregulated bone adaptation in response to decreased bone matrix mineralization may be responsible for the increase in bone volume fraction observed in OA. For this purpose, we used the experimentally obtained mineralization data as input for bone adaptation simulations. We simulated the effect of mechanoregulated bone adaptation in response to different degrees of mineralization, and compared the simulation results to the experimental data. We found that local changes in subchondral bone mineralization and bone volume fraction only occurred underneath severely degenerated cartilage, indicating that bone mineralization and volume fraction are related to cartilage degeneration at a local level. In addition, both the experimental data and the simulations indicated that a depth-dependent increase in bone volume fraction could be caused by decreased bone matrix mineralization. However, a quantitative comparison showed that decreased mineralization can only explain part of the subchondral sclerosis observed in OA. [Copyright &y& Elsevier]

Published

2012

28. Assessment of the healing of conservatively-treated scaphoid fractures using HR-pQCT.

Author

Bevers, M.S.A.M., Daniels, A.M., van Rietbergen, B., Geusens, P.P.M.M., van Kuijk, S.M.J., Sassen, S., Kaarsemaker, S., Hannemann, P.F.W., Poeze, M., Janzing, H.M.J., van den Bergh, J.P., and Wyers, C.E.

Subjects

*DISTAL radius fractures, *COMPUTED tomography, *SCAPHOID bone, *BONE density, *HEALING

Abstract

Improving the clinical outcome of scaphoid fractures may benefit from adequate monitoring of their healing in order to for example identify complications such as scaphoid nonunion at an early stage and to adjust the treatment strategy accordingly. However, quantitative assessment of the healing process is limited with current imaging modalities. In this study, high-resolution peripheral quantitative computed tomography (HR-pQCT) was used for the first time to assess the changes in bone density, microarchitecture, and strength during the healing of conservatively-treated scaphoid fractures. Thirteen patients with a scaphoid fracture (all confirmed on HR-pQCT and eleven on CT) received an HR-pQCT scan at baseline and three, six, twelve, and 26 weeks after first presentation at the emergency department. Bone mineral density (BMD) and trabecular microarchitecture of the scaphoid bone were quantified, and failure load (FL) was estimated using micro-finite element analysis. Longitudinal changes were evaluated with linear mixed-effects models. Data of two patients were excluded due to surgical intervention after the twelve-week follow-up visit. In the eleven fully evaluable patients, the fracture line became more apparent at 3 weeks. At 6 weeks, individual trabeculae at the fracture region became more difficult to identify and distinguish from neighboring trabeculae, and this phenomenon concerned a larger region around the fracture line at 12 weeks. Quantitative assessment showed that BMD and FL were significantly lower than baseline at all follow-up visits with the largest change from baseline at 6 weeks (−13.6% and − 23.7%, respectively). BMD remained unchanged thereafter, while FL increased. Trabecular thickness decreased significantly from baseline at three (−3.9%), six (−6.7%), and twelve (−4.4%) weeks and trabecular number at six (−4.5%), twelve (−7.3%), and 26 (−7.9%) weeks. Trabecular separation was significantly higher than baseline at six (+13.3%), twelve (+19.7%), and 26 (+16.3%) weeks. To conclude, this explorative HR-pQCT study showed a substantial decrease in scaphoid BMD, Tb.Th, and FL during the first 6 weeks of healing of conservatively-treated scaphoid fractures, followed by stabilization or increase in these parameters. At 26 weeks, BMD, trabecular microarchitecture, and FL were not returned to baseline values. • HR-pQCT can be used to assess the healing process of scaphoid fractures. • Density and failure load significantly decreased until 6 weeks post-fracture. • Density and failure load were not returned to baseline 26 weeks post-fracture. • The healing of scaphoid fractures seems slower than that of distal radius fractures. [ABSTRACT FROM AUTHOR]

Published

2021

29. A fibril-reinforced poroviscoelastic swelling model for articular cartilage

Author

Wilson, W., van Donkelaar, C.C., van Rietbergen, B., and Huiskes, R.

Subjects

*CONNECTIVE tissues, *CARTILAGE, *EXTRACELLULAR matrix proteins, *LIGAMENTS, *GLYCOPROTEINS

Abstract

Abstract: From a mechanical point of view, the most relevant components of articular cartilage are the tight and highly organized collagen network together with the charged proteoglycans. Due to the fixed charges of the proteoglycans, the cation concentration inside the tissue is higher than in the surrounding synovial fluid. This excess of ion particles leads to an osmotic pressure difference, which causes swelling of the tissue. The fibrillar collagen network resists straining and swelling pressures. This combination makes cartilage a unique, highly hydrated and pressurized tissue, enforced with a strained collagen network. Many theories to explain articular cartilage behavior under loading, expressed in computational models that either include the swelling behavior or the properties of the anisotropic collagen structure, can be found in the literature. The most common tests used to determine the mechanical quality of articular cartilage are those of confined compression, unconfined compression, indentation and swelling. All theories currently available in the literature can explain the cartilage response occurring in some of the above tests, but none of them can explain these for all of the tests. We hypothesized that a model including simultaneous mathematical descriptions of (1) the swelling properties due to the fixed-change densities of the proteoglycans and (2) the anisotropic viscoelastic collagen structure, can explain all these test simultaneously. To study this hypothesis we extended our fibril-reinforced poroviscoelastic finite element model with our biphasic swelling model. We have shown that the newly developed fibril-reinforced poroviscoelastic swelling (FPVES) model for articular cartilage can simultaneously account for the reaction force during swelling, confined compression, indentation and unconfined compression as well as the lateral deformation during unconfined compression. Using this theory it is possible to analyze the link between the collagen network and the swelling properties of articular cartilage. [Copyright &y& Elsevier]

Published

2005

30. A theoretical framework for strain-related trabecular bone maintenance and adaptation

Author

Ruimerman, R., Hilbers, P., van Rietbergen, B., and Huiskes, R.

Subjects

*BONES, *FINITE element method, *SIMULATION methods & models, *OSTEOCYTES

Abstract

It is assumed that density and morphology of trabecular bone is partially controlled by mechanical forces. How these effects are expressed in the local metabolic functions of osteoclast resorption and osteoblast formation is not known. In order to investigate possible mechano-biological pathways for these mechanisms we have proposed a mathematical theory (Nature 405 (2000) 704). This theory is based on hypothetical osteocyte stimulation of osteoblast bone formation, as an effect of elevated strain in the bone matrix, and a role for microcracks and disuse in promoting osteoclast resorption. Applied in a 2-D Finite Element Analysis model, the theory explained the formation of trabecular patterns. In this article we present a 3-D FEA model based on the same theory and investigated its potential morphological predictability of metabolic reactions to mechanical loads. The computations simulated the development of trabecular morphological details during growth, relative to measurements in growing pigs, reasonably realistic. They confirmed that the proposed mechanisms also inherently lead to optimal stress transfer. Alternative loading directions produced new trabecular orientations. Reduction of load reduced trabecular thickness, connectivity and mass in the simulation, as is seen in disuse osteoporosis. Simulating the effects of estrogen deficiency through increased osteoclast resorption frequencies produced osteoporotic morphologies as well, as seen in post-menopausal osteoporosis. We conclude that the theory provides a suitable computational framework to investigate hypothetical relationships between bone loading and metabolic expressions. [Copyright &y& Elsevier]

Published

2005

31. Stresses in the local collagen network of articular cartilage: a poroviscoelastic fibril-reinforced finite element study

Author

Wilson, W., van Donkelaar, C.C., van Rietbergen, B., Ito, K., and Huiskes, R.

Subjects

*OSTEOARTHRITIS, *COLLAGEN, *PHYSIOLOGICAL stress, *CARTILAGE

Abstract

Osteoarthritis (OA) is a multifactorial disease, resulting in diarthrodial joint wear and eventually destruction. Swelling of cartilage, which is proportional to the amount of collagen damage, is an initial event of cartilage degeneration, so damage to the collagen fibril network is likely to be one of the earliest signs of OA cartilage degeneration. We propose that the local stresses and strains in the collagen fibrils, which cause the damage, cannot be determined dependably without taking the local arcade-like collagen-fibril structure into account. We investigate this using a poroviscoelastic fibril-reinforced FEA model. The constitutive fibril properties were determined by fitting numerical data to experimental results of unconfined compression and indentation tests on samples of bovine patellar articular cartilage. It was demonstrated that with this model the stresses and strains in the collagen fibrils can be calculated. It was also exhibited that fibrils with different orientations at the same location can be loaded differently, depending on the local architecture of the collagen network. To the best of our knowledge, the present model is the first that can account for these features. We conclude that the local stresses and strains in the articular cartilage are highly influenced by the local morphology of the collagen-fibril network. [Copyright &y& Elsevier]

Published

2004

32. Erratum to “Stresses in the local collagen network of articular cartilage: a poroviscoelastic fibril-reinforced finite element study” [Journal of Biomechanics 37 (2004) 357–366] and “A fibril-reinforced poroviscoelastic swelling model for articular cartilage” [Journal of Biomechanics 38 (2005) 1195–1204]

Author

Wilson, W., van Donkelaar, C.C., van Rietbergen, B., Ito, K., and Huiskes, R.

Published

2005

33. Long-term functional outcome of distal radius fractures is associated with early post-fracture bone stiffness of the fracture region: An HR-pQCT exploratory study.

Author

Heyer, F.L., de Jong, J.J.A., Willems, P.C., Arts, J.J., Bours, S.G.P., van Kuijk, S.M.J., Poeze, M., Geusens, P.P., van Rietbergen, B., and van den Bergh, J.P.

Subjects

*BONE fractures, *ULNA, *RADIUS (Geometry), *BONE density, *TORSIONAL stiffness, *CLINICAL trials

Abstract

Identifying determinants of long-term functional outcome after a distal radius fracture is challenging. Previously, we reported on the association between early HR-pQCT measurements and clinical outcome 12 weeks after a conservatively treated distal radius fracture. We extended the follow-up and assessed functional outcome after two years in relation to early HR-pQCT derived bone parameters. HR-pQCT scans of the fracture region were performed in 15 postmenopausal women with a distal radius fracture at 1–2 (baseline), 3–4 weeks and 26 months post-fracture. Additionally, the contralateral distal radius was scanned at baseline. Bone density, micro-architecture parameters and bone stiffness using micro-finite element analysis (μFEA) were evaluated. During all visits, wrist pain and function were assessed using the patient-rated wrist evaluation questionnaire (PRWE), quantifying functional outcome with a score between 0 and 100. Two-year PRWE was associated with torsional and bending stiffness 3–4 weeks post-fracture (R2: 0.49, p = 0.006 and R2: 0.54, p = 0.003, respectively). In contrast, early micro-architecture parameters of the fracture region or contralateral bone parameters did not show any association with long-term outcome. This exploratory study indicates that HR-pQCT with μFEA performed within four weeks after a distal radius fracture captures biomechanical fracture characteristics that are associated with long-term functional outcome and therefore could be a valuable early outcome measure in clinical trials and clinical practice. • HR-pQCT scans can be used to assess the healing process of distal radius fractures. • μFEA-derived stiffness is associated with functional outcome 2 years post-fracture. • Early torsional/bending stiffness may be most important for functional recovery. • Fracture region micro-architecture is not associated with long-term function. [ABSTRACT FROM AUTHOR]

Published

2019

34. Mechanical behaviour of Bioactive Glass granules and morselized cancellous bone allograft in load bearing defects.

Author

Hulsen, D.J.W., Geurts, J., van Gestel, N.A.P., van Rietbergen, B., and Arts, J.J.

Subjects

*BIOACTIVE glasses, *CANCELLOUS bone, *BONE grafting, *ANTIBACTERIAL agents, *BIOMATERIALS, *MECHANICAL behavior of materials, *DISEASES

Abstract

Bioactive Glass (BAG) granules are osteoconductive and possess unique antibacterial properties for a synthetic biomaterial. To assess the applicability of BAG granules in load-bearing defects, the aim was to compare mechanical behaviour of graft layers consisting of BAG granules and morselized cancellous bone allograft in different volume mixtures under clinically relevant conditions. The graft layers were mechanically tested, using two mechanical testing modalities with simulated physiological loading conditions: highly controllable confined compression tests (CCT) and more clinically realistic in situ compression tests (ISCT) in cadaveric porcine bone defects. Graft layer impaction strain, residual strain, aggregate modulus, and creep strain were determined in CCT. Graft layer porosity was determined using micro computed tomography. The ISCT was used to determine graft layer subsidence in bone environment. ANOVA showed significant differences ( p <0.001) between different graft layer compositions. True strains absolutely decreased for increasing BAG content: impaction strain −0.92 (allograft) to −0.39 (BAG), residual strain −0.12 to −0.01, and creep strain −0.09 to 0.00 respectively. Aggregate modulus increased with increasing BAG content from 116 to 653 MPa. Porosity ranged from 66% (pure allograft) to 15% (pure BAG). Subsidence was highest for allograft, and remarkably low for a 1:1 BAG-allograft volume mixture. Both BAG granules and allograft morsels as stand-alone materials exhibit suboptimal mechanical behaviour for load-bearing purpose. BAG granules are difficult to handle and less porous, whereas allograft subsides and creeps. A 1:1 volume mixture of BAG and allograft is therefore proposed as the best graft material in load-bearing defects. [ABSTRACT FROM AUTHOR]

Published

2016

35. The role of pressurized fluid in subchondral bone cyst growth

Author

Cox, L.G.E., Lagemaat, M.W., van Donkelaar, C.C., van Rietbergen, B., Reilingh, M.L., Blankevoort, L., van Dijk, C.N., and Ito, K.

Subjects

*BONE diseases, *CYSTS (Pathology), *BODY fluids, *BONE resorption, *BONE growth, *OSTEOCYTES, *PHYSIOLOGICAL adaptation, *PHYSIOLOGICAL stress

Abstract

Abstract: Pressurized fluid has been proposed to play an important role in subchondral bone cyst development. However, the exact mechanism remains speculative. We used an established computational mechanoregulated bone adaptation model to investigate two hypotheses: 1) pressurized fluid causes cyst growth through altered bone tissue loading conditions, 2) pressurized fluid causes cyst growth through osteocyte death. In a 2D finite element model of bone microarchitecture, a marrow cavity was filled with fluid to resemble a cyst. Subsequently, the fluid was pressurized, or osteocyte death was simulated, or both. Rather than increasing the load, which was the prevailing hypothesis, pressurized fluid decreased the load on the surrounding bone, thereby leading to net bone resorption and growth of the cavity. In this scenario an irregularly shaped cavity developed which became rounded and obtained a rim of sclerotic bone after removal of the pressurized fluid. This indicates that cyst development may occur in a step-wise manner. In the simulations of osteocyte death, cavity growth also occurred, and the cavity immediately obtained a rounded shape and a sclerotic rim. Combining both mechanisms increased the growth rate of the cavity. In conclusion, both stress-shielding by pressurized fluid, and osteocyte death may cause cyst growth. In vivo observations of pressurized cyst fluid, dead osteocytes, and different appearances of cysts similar to our simulation results support the idea that both mechanisms can simultaneously play a role in the development and growth of subchondral bone cysts. [Copyright &y& Elsevier]

Published

2011

36. Predictive value of femoral head heterogeneity for fracture risk

Author

Tanck, E., Bakker, A.D., Kregting, S., Cornelissen, B., Klein-Nulend, J., and Van Rietbergen, B.

Subjects

*FEMUR, *RISK factors of fractures, *OSTEOPOROSIS, *BONE density, *ANISOTROPY

Abstract

Abstract: Osteoporosis (OP) is characterized by low bone mass and weak bone structure, which results in increased fracture risk. It has been suggested that osteoporotic bone is strongly adapted to the main loading direction and less adapted to the other directions. In this study, we hypothesized that osteoporotic femoral heads have 1) an increased anisotropy; 2) a more heterogenic distribution of bone volume fraction (BV/TV) throughout the femoral head; and, 3) a more heterogenic distribution of the trabecular thickness (Tb.Th.) throughout the femoral head, as compared to non-osteoporotic bone. To test these hypotheses, we used 7 osteoporotic femoral heads from patients who fractured their femoral neck and 7 non-fractured femoral heads from patients with osteoarthrosis (OA). Bone structural parameters from the entire trabecular region were analyzed using microCT. We found that the degree of anisotropy was higher in the fractured femoral heads, i.e. 1.72, compared to a value of 1.61 in the non-fractured femoral heads. The BV/TV and Tb.Th. and their variations throughout the femoral head, however, were all significantly lower in the fractured group. Hence, the first hypothesis was confirmed, whereas the other two were rejected. Interestingly, the variation of Tb.Th. throughout the femoral head provided a 100% discrimination between the OP and OA groups, i.e. for the same BV/TV, all fractured cases had a less heterogenic distribution. In conclusion, our results suggest that bone loss in OP takes place uniformly throughout the femoral head, leading to an overall decrease in bone mass and trabecular thickness. Furthermore, the variation of Tb.Th. in the femoral head could be an interesting parameter to improve the prediction of fracture risk in the proximal femur. [Copyright &y& Elsevier]

Published

2009

37. A new semi-orthotopic bone defect model for cell and biomaterial testing in regenerative medicine.

Author

Andrés Sastre, E., Nossin, Y., Jansen, I., Kops, N., Intini, C., Witte-Bouma, J., van Rietbergen, B., Hofmann, S., Ridwan, Y., Gleeson, J.P., O'Brien, F.J., Wolvius, E.B., van Osch, G.J.V.M., and Farrell, E.

Subjects

*BONE growth, *BONE grafting, *REGENERATIVE medicine, *BONE resorption, *IMAGE registration, *TISSUE engineering

Abstract

In recent decades, an increasing number of tissue engineered bone grafts have been developed. However, expensive and laborious screenings in vivo are necessary to assess the safety and efficacy of their formulations. Rodents are the first choice for initial in vivo screens but their size limits the dimensions and number of the bone grafts that can be tested in orthotopic locations. Here, we report the development of a refined murine subcutaneous model for semi-orthotopic bone formation that allows the testing of up to four grafts per mouse one order of magnitude greater in volume than currently possible in mice. Crucially, these defects are also "critical size" and unable to heal within the timeframe of the study without intervention. The model is based on four bovine bone implants, ring-shaped, where the bone healing potential of distinct grafts can be evaluated in vivo. In this study we demonstrate that promotion and prevention of ossification can be assessed in our model. For this, we used a semi-automatic algorithm for longitudinal micro-CT image registration followed by histological analyses. Taken together, our data supports that this model is suitable as a platform for the real-time screening of bone formation, and provides the possibility to study bone resorption, osseointegration and vascularisation. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2021

38. Association between bone stiffness and age. A micro-finite element analysis in women from the OFELY cohort

Author

Vilayphiou, N., Boutroy, S., Sornay-Rendu, E., Munoz, F., Van Rietbergen, B., Delmas, P., and Chapurlat, R.

Published

2011

39. Differences in radius strength between male elite rock climbers and runners determined by FE analysis of bone in-vivo

Author

Kunecky, J., Kemmler, W., von Stengel, S., Engelke, K., and van Rietbergen, B.

Published

2006