Influence of bone composition and apparent density on fracture toughness of the human femur and tibia.
about
The fracture mechanics of human bone: influence of disease and treatmentMechanical behavior of human cortical bone in cycles of advancing tensile strain for two age groups.Hierarchy of Bone Microdamage at Multiple Length Scales.Age-related factors affecting the postyield energy dissipation of human cortical bone.Qualitative and quantitative ultrashort-TE MRI of cortical bone.Bone mineral (31)P and matrix-bound water densities measured by solid-state (31)P and (1)H MRI.Magnetic resonance imaging assessed cortical porosity is highly correlated with μCT porosity.Identifying Novel Clinical Surrogates to Assess Human Bone Fracture Toughness.Raman spectral classification of mineral- and collagen-bound water's associations to elastic and post-yield mechanical properties of cortical bone.Cortical bone water: in vivo quantification with ultrashort echo-time MR imaging.Ultra-short echo-time MRI detects changes in bone mineralization and water content in OVX rat bone in response to alendronate treatment.Ultrashort TE MR imaging of bovine cortical bone: the effect of water loss on the T1 and T2* relaxation timesUltrashort echo time (UTE) imaging with bi-component analysis: bound and free water evaluation of bovine cortical bone subject to sequential dryingQuantitative ultrashort echo time (UTE) MRI of human cortical bone: correlation with porosity and biomechanical properties.Effects of mineral content on the fracture properties of equine cortical bone in double-notched beamsRaman and mechanical properties correlate at whole bone- and tissue-levels in a genetic mouse model.The loss of activating transcription factor 4 (ATF4) reduces bone toughness and fracture toughnessMicroarchitecture influences microdamage accumulation in human vertebral trabecular bone.Evaluation of bound and pore water in cortical bone using ultrashort-TE MRI.Interfragmentary surface area as an index of comminution severity in cortical bone impact.How can bone turnover modify bone strength independent of bone mass?SERMs have substance-specific effects on bone, and these effects are mediated via ERαAF-1 in female mice.Measurement of the toughness of bone: a tutorial with special reference to small animal studies.The impact of discrete compartments of a multi-compartment collagen-GAG scaffold on overall construct biophysical properties.The contribution of the extracellular matrix to the fracture resistance of bone.The role of nanoscale toughening mechanisms in osteoporosis.Prediction of cortical bone porosity in vitro by microcomputed tomography.Age- and sex-specific thorax finite element model development and simulation.Cortical Bone Mineralization in the Human Femoral Neck in Cases and Controls from Synchrotron Radiation Study.Analysis of crack growth in a 3D Voronoi structure: a model for fatigue in low density trabecular bone.Calculation of porosity and osteonal cement line effects on the effective fracture toughness of cortical bone in longitudinal crack growth.Effects of different exercise modes on mineralization, structure, and biomechanical properties of growing bone.Mechanical and metabolic interactions in cortical bone development.3D printed phantoms mimicking cortical bone for the assessment of ultrashort echo time magnetic resonance imaging.Scanning Skeletal Remains for Bone Mineral Density in Forensic Contexts.Fracture resistance of gamma radiation sterilized cortical bone allografts.
P2860
Q26784190-F6FAD6BC-D715-499B-81D8-A3A6DA3ACC3DQ30489924-3A680BDA-AD5D-4B42-A419-787DC4AB0056Q30494296-BE19FF3D-5D7E-4F21-87D0-61B546F9BC93Q30501027-EE22386C-799F-45C9-AAFB-D5E4477A796FQ30583890-5A26B546-5B93-4DBF-81A2-762DA7BA7687Q30824972-12FC13BA-602B-42E0-82FC-14B952038035Q30831057-7330BD02-D2F7-4A9C-BE9C-24DE3A5A1D57Q30886905-2B433FB8-6B51-44D1-A9DB-8FB6E4301D67Q30982708-FF935D40-E56D-4F47-88A0-A875580C1FCDQ31162836-E22E02A2-0193-494E-9A45-276AF59B0822Q33526115-FFC797E0-7C00-4F70-934F-CC6CC7224860Q33832582-E88AB13C-3BCF-475C-B6A7-AAA9B485F2B5Q34104476-E292B9B6-4AB2-4A03-BAC2-78D63810D368Q34108271-9359929A-6793-47FE-817A-53349679662BQ34224626-35B1B79E-0F87-480F-B967-38E29071C180Q34482292-5F1AC14D-7762-43F9-A109-4DEB207CCEDEQ35089416-2DAACA48-7A7F-4EC4-9129-55A727513FC9Q35747398-308D1BC7-9423-4BEF-9D64-C663F17205B9Q35829986-A5F04C0B-D1F0-4F33-8DC6-109E3FECC3CCQ36372953-ABBBCB3D-2A42-4A41-AFBD-1C37B3342B57Q36741750-BDDDFDF0-BC39-4463-BA2B-903DE60125BFQ37070860-4A2BF3E0-ED9D-40A8-AD91-96C3FD9DDA12Q37223996-2FA5A434-C5BE-4DA5-A873-A7942FB1528AQ37651592-F6F16024-A959-4CC5-A456-9BD023856190Q38004934-337A464C-3D7A-420C-A208-E6A9AED22448Q38223620-27217C3B-0F2B-4CF7-8412-6875B25CEC6AQ39406495-5FF80183-2FB4-4260-BD4C-EDD0C9C6A335Q40885816-61864368-1948-4138-B58D-4F661F3C4BBFQ41461973-D29ECB7C-C047-4D9D-B18F-1A99C647B06DQ42686854-7B37C05A-EE15-4DDD-8D22-137B2D216E38Q44873441-75D74E3A-78E0-4A5E-8050-BB9509871F7CQ46287442-21758851-3E70-4027-8770-74DDFD8051DBQ47331554-4FB712DF-065E-4950-A275-6942822A2C68Q47756742-14AA3523-0E07-4360-BC09-3E9ACF4F3D65Q50010578-6539D12B-9F34-4B3C-9B84-63B223C28D11Q53993532-55D878B2-7605-4777-95DD-648250FFFC24
P2860
Influence of bone composition and apparent density on fracture toughness of the human femur and tibia.
description
1998 nî lūn-bûn
@nan
1998年の論文
@ja
1998年学术文章
@wuu
1998年学术文章
@zh
1998年学术文章
@zh-cn
1998年学术文章
@zh-hans
1998年学术文章
@zh-my
1998年学术文章
@zh-sg
1998年學術文章
@yue
1998年學術文章
@zh-hant
name
Influence of bone composition ...... of the human femur and tibia.
@en
Influence of bone composition ...... of the human femur and tibia.
@nl
type
label
Influence of bone composition ...... of the human femur and tibia.
@en
Influence of bone composition ...... of the human femur and tibia.
@nl
prefLabel
Influence of bone composition ...... of the human femur and tibia.
@en
Influence of bone composition ...... of the human femur and tibia.
@nl
P2093
P1433
P1476
Influence of bone composition ...... of the human femur and tibia.
@en
P2093
P356
10.1016/S8756-3282(97)00227-5
P577
1998-01-01T00:00:00Z