Catherine Behets scite author profile

Because SBM may contribute to cartilage breakdown in OA, experimental OA was induced in dogs by transecting the anterior cruciate ligament of the knee and treating with either CT or a placebo. CT significantly reduced both SBM and cartilage lesions. This study supports the use of CT in the treatment of canine experimental OA.Introduction: Because subchondral bone remodeling (SBM) may contribute to cartilage breakdown in osteoarthritis (OA), we evaluated to what extend calcitonin (CT) might affect cartilage and bone changes in the early stages of canine experimental OA. Materials and Methods: Twelve dogs underwent transection of the anterior cruciate ligament (ACLT) of the right knee. After ACLT, each animal received a daily nasal spray delivering either 400 U of CT (CT-treated group; n ϭ 6) or a placebo (PL-treated group; n ϭ 6). At day 84 after surgery, animals were killed, and cartilage changes were graded. BMD and volume fraction (BVF) were assessed by pQCT in different regions of interest (ROIs) of the subchondral cancellous bone of tibial plateaus (TPs).Statistics included a 2 ϫ 2 factorial analysis with ϮCT as one factor and ϮACLT as the other. Results and Conclusions: Nonoperated (N-OP) knees were normal in both groups. In the PL-treated group, ACLT knees all exhibited OA changes, which predominated in the medial knee compartment. Furthermore, compared with N-OP knees, the BMD and BVF of ACLT joints were both markedly reduced in medial TP but not in lateral TP. In contrast, in the CT-treated group, cartilage OA lesions of ACLT knees were significantly reduced, and there was no difference in BMD and BFV between N-OP and ACLT knees. These findings suggest that the loss of subchondral trabeculae contributes to cartilage breakdown, possibly by enhancing cartilage deformation on joint loading. By counteracting bone loss, CT reduced cartilage OA lesions, and thus, might be useful in the treatment of OA in cruciate-deficient dogs.

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The enhanced performance of bone allografts using osteogenic-differentiated adipose-derived mesenchymal stem cells

Schubert

Xhema

Vériter

et al. 2011

Biomaterials

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Critical size bone defect reconstruction by an autologous 3D osteogenic-like tissue derived from differentiated adipose MSCs

et al. 2013

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Patients’ and orthodontists’ perceptions of miniplates used for temporary skeletal anchorage: A prospective study

Cornelis

Scheffler

Behets

et al. 2008

American Journal of Orthodontics and Dentofacial Orthopedics

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Bioengineering a Human Face Graft

Duisit

Maistriaux

Taddeo

et al. 2017

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Alterated talar and navicular bone morphology is associated with pes planus deformity: A CT‐scan study

Peeters

Schreuer

Burg

et al. 2012

Journal Orthopaedic Research

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We compared bone and articular morphology of the talus and navicular in clinically diagnosed flatfeet and evaluated their potential contribution to talo-navicular joint instability. We used CT images to develop 3D models of talus and navicular bones of 10 clinically diagnosed flatfeet and 15 non-flatfeet. We quantified their global bone dimensions, inclination and dimensions of the articular surfaces and their curvatures. Additionally, ratios of six talar and navicular dimensions were calculated. The values for these parameters were then compared between both groups. In flatfeet, the talar head faced more proximal and its width was larger compared to non-flatfeet. Also the navicular cup faced more proximal and its depth was significantly increased. Furthermore, we observed a more protruding talar head compared to the navicular cup in the control group with the articular surface depth being relatively larger for the navicular cups when compared to the talus in flatfeet. The ratio of the talar and navicular articular surface height was decreased in flatfeet, suggesting increased height of navicular cups relative to the articulating talar heads. Our results show that flatfoot deformity is associated with morphological changes of talar and navicular articular surfaces that can favor medial arch collapse and forefoot abduction. Several authors tried to introduce more reproducible exams, such as measurement of the bone-to-bone relationships on MRI or weightbearing CT-scan images, to define foot function during weightbearing conditions. 5,6 CT-scan studies led to several outcomes, such as 3D changes in relationships among bones, 7,8 and alterations in joint contact characteristics. 9-11 These studies contributed to the conclusion that flatfoot deformity is associated with changes in bone-to-bone relationships.Evidence exists that anatomical configuration and morphology per se are associated with the development of flatfoot deformity. Dyal et al. 12 found that many patients with symptomatic flatfeet also presented a decreased foot arch on the contralateral, asymptomatic side. However, few authors explored further these morphological changes until now. Anderson et al. 13 investigated alterations of talar bone morphology in flatfeet and found significant differences with respect to controls. These differences concerned the ratios of bone length/width, bone length/height, and head length/ width. Flatfoot tali were narrower in width and shorter in height and had more oval shaped heads. Furthermore, Grasso et al. 14 observed different calcaneal morphotypes when comparing different plantar arch alterations, including pes planus deformity.Based on these observations we investigated if, in addition to the aberrant relationships between bones previously documented in flatfeet, a difference also exists in bone and articular surface morphology of the talo-navicular joint. We hypothesized that a decreased congruence of articular surfaces in flatfeet compared to a control group is associated with increased talonavicular jo...

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The deep belly of the temporalis muscle: an anatomical, histological and MRI study

et al. 2005

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In order to achieve a better functional and clinical knowledge of a masticatory muscle called the sphenomandibularis that is suspected to be responsible for headaches by compressing the maxillary nerve, bilateral dissections of the infratemporal fossa were performed on ten human cadavers and completed by histological and radiological studies of the same areas. Both macroscopic and microscopic observations obviously showed that the so-called sphenomandibularis muscle corresponds to the deep portion of the temporalis muscle, since there is no epimysial septum between these two structures, which previously have been described as being completely independent from each other. In spite of the close topographic relationship between the deep belly of the temporalis and the lateral pterygoid muscle, as well as their similar innervation pattern, the sphenomandibularis in fact has to be considered functionally as an original but non-isolated positional fascicle of the temporalis muscle itself. Our observations, correlated with MR images, suggest indeed that the deep belly of the temporalis muscle is of functional importance in the masticatory movements, but is not involved by its neurovascular vicinity in the genesis of specific headaches. Its surgical release, however, should be discussed in the case of a temporal myoplasty.

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