Cortical and trabecular load sharing in the human vertebral body.
about
Predicting mouse vertebra strength with micro-computed tomography-derived finite element analysis.From high-resolution CT data to finite element models: development of an integrated modular framework.Role of trabecular microarchitecture in whole-vertebral body biomechanical behaviorEffects of suppression of bone turnover on cortical and trabecular load sharing in the canine vertebral body.Bone three-dimensional microstructural features of the common osteoporotic fracture sites.Effect of sequential treatments with alendronate, parathyroid hormone (1-34) and raloxifene on cortical bone mass and strength in ovariectomized rats.Lumbar trabecular bone mineral density distribution in patients with and without vertebral fractures: a case-control study.Morphometric comparison of the lumbar cancellous bone of sheep, deer, and humansMechanisms of initial endplate failure in the human vertebral body.Higher doses of bisphosphonates further improve bone mass, architecture, and strength but not the tissue material properties in aged ratsTrabecular plates and rods determine elastic modulus and yield strength of human trabecular bone.Trabecular bone loss at a distant skeletal site following noninvasive knee injury in miceVariability of tissue mineral density can determine physiological creep of human vertebral cancellous bone.Prediction of local ultimate strain and toughness of trabecular bone tissue by Raman material composition analysis.Functional interactions among morphologic and tissue quality traits define bone qualityRelation of vertebral deformities to bone density, structure, and strength.Subregional DXA-derived vertebral bone mineral measures are stronger predictors of failure load in specimens with lower areal bone mineral density, compared to those with higher areal bone mineral density.Variability of trabecular microstructure is age-, gender-, race- and anatomic site-dependent and affects stiffness and stress distribution properties of human vertebral cancellous bone.Differential maintenance of cortical and cancellous bone strength following discontinuation of bone-active agentsMechanical contributions of the cortical and trabecular compartments contribute to differences in age-related changes in vertebral body strength in men and women assessed by QCT-based finite element analysis.Influence of vertical trabeculae on the compressive strength of the human vertebraCompromised vertebral structural and mechanical properties associated with progressive kidney disease and the effects of traditional pharmacological interventionsEndplate deflection is a defining feature of vertebral fracture and is associated with properties of the underlying trabecular boneThe effect of standard and low-modulus cement augmentation on the stiffness, strength, and endplate pressure distribution in vertebroplasty.Micromechanical analyses of vertebral trabecular bone based on individual trabeculae segmentation of plates and rods.Morphology, localization and accumulation of in vivo microdamage in human cortical bone.Locations of bone tissue at high risk of initial failure during compressive loading of the human vertebral body.Micromechanics of the human vertebral body for forward flexion.Vertebral fragility and structural redundancy.Trabecular shear stress amplification and variability in human vertebral cancellous bone: relationship with age, gender, spine level and trabecular architectureThe Effect of Polymethyl Methacrylate Augmentation on the Primary Stability of Cannulated Bone Screws in an Anterolateral Plate in Osteoporotic Vertebrae: A Human Cadaver Study.Digital Volume Correlation for Study of the Mechanics of Whole BonesStructural strength of cancellous specimens from bovine femur under cyclic compressionLongitudinal changes in lumbar bone mineral density distribution may increase the risk of wedge fractures.Vertebral deformities and fractures are associated with MRI and pQCT measures obtained at the distal tibia and radius of postmenopausal womenThe effect of intravertebral heterogeneity in microstructure on vertebral strength and failure patterns.Material heterogeneity in cancellous bone promotes deformation recovery after mechanical failureAge-related changes in trabecular and cortical bone microstructureEffective modulus of the human intervertebral disc and its effect on vertebral bone stressMechanical loading causes detectable changes in morphometric measures of trabecular structure in human cancellous bone.
P2860
Q30385252-08E07BB1-750B-4CAD-B60A-26462FB87CDBQ33374337-0DE588F3-635B-476D-A734-7E97AF9BC70CQ33425431-C1CFB4A5-9649-4595-BA94-13D7691FE939Q33923777-E4E34EF0-DDBB-4735-946D-695A7C73A35FQ34047741-43B0C71A-BD9F-4F0A-A8EF-E7F38C4A83D3Q34149279-6A199F8F-078A-46AB-8776-210D72BCA49AQ34206088-6EFA5289-884E-4D9A-90A9-6AB54B4D0F5FQ34217417-53E145AC-643F-41B0-AF4C-A2B3D7F13A33Q34348645-A24596C0-7CB7-48BB-95F4-F0B8AF649F0FQ34411999-CE4FDD7C-3DF3-4B50-A37C-5F7926DAA729Q34810185-ACC63CBA-C0B0-4F82-9621-A26C4787A2D9Q34975034-B6F27AD9-6E49-4929-B3A4-10C69AF61E89Q35000270-3E0C9F46-9135-40DD-85DB-950D24160D90Q35071764-B025463B-AF4A-44A8-95C3-0A522A417700Q35078839-877652FB-FD08-4B87-BF03-00861A7AC1F8Q35156311-DF10304D-10FB-4C8D-8675-E68C9DA2F5E6Q35173498-3AFE0B44-B098-4885-845B-41736D415C4FQ35206911-7F89B032-0626-406C-9CEB-F5657F3EF8B1Q35229871-93E6E78A-B86F-4DF3-89AD-AEAC1016F21AQ35229916-5A4444EE-934B-4D21-8E46-60B0DFBF86AAQ35230067-2860E26D-7447-45A1-A1F2-C0241C934E7CQ35661168-8BB82949-5B18-4D5C-961D-D24E29351BE1Q35668485-5EE654E0-C84F-4631-830B-66B1A084D281Q35916355-46DF8CF6-44D1-4B95-BFAF-2C7C1399B889Q36051959-294C2F75-86E6-4C77-8297-32C1F791E40AQ36052388-0212F801-7EF0-414F-A1D7-4D44C3C80EAAQ36151562-7590A7C9-E36B-4921-8AD4-C5F4F80A0D50Q36152369-F3DCB9DB-83AB-4FF5-A41F-16E072475585Q36230067-C8B9B278-E838-4D79-B85E-5A24F11021E8Q36512404-F3EFF51B-BE04-4D2A-B209-A4A3524FA208Q36521940-74578C02-BA0E-4A76-8CC2-4EB1C72B516AQ36542211-37741972-8D92-47EA-9265-1F628B145A26Q36543149-8328DEC0-95FA-4AC3-BC9C-47F8A94C0A20Q36553140-D3468804-EA61-432B-B2A1-CF0706AECF6EQ36560449-C6F4BB72-FFBC-44CC-947C-AFBC98240F10Q36612189-B5CB16AF-AB50-4F75-83E9-F1FCF2965D1EQ36710698-415A15CB-31DC-4C91-8BD0-931152212BE3Q36734024-BAA6386D-1ADF-4F38-A94C-524375FBC1A8Q36853192-14EB5873-375E-4C6F-AFDF-43C1979F8B69Q36995423-F4DD0CF0-ECA1-4C37-9033-495938FF835E
P2860
Cortical and trabecular load sharing in the human vertebral body.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh
2005年學術文章
@zh-hant
name
Cortical and trabecular load sharing in the human vertebral body.
@en
Cortical and trabecular load sharing in the human vertebral body.
@nl
type
label
Cortical and trabecular load sharing in the human vertebral body.
@en
Cortical and trabecular load sharing in the human vertebral body.
@nl
prefLabel
Cortical and trabecular load sharing in the human vertebral body.
@en
Cortical and trabecular load sharing in the human vertebral body.
@nl
P2093
P2860
P1476
Cortical and trabecular load sharing in the human vertebral body.
@en
P2093
Atul Gupta
Mark F Adams
Senthil K Eswaran
Tony M Keaveny
P2860
P304
P356
10.1359/JBMR.2006.21.2.307
P577
2005-11-07T00:00:00Z