Sex differences in geometry of the femoral neck with aging: a structural analysis of bone mineral data.
about
Assessing Bone Mineral Density Following Acute Hip Fractures: The Role of Computed Tomography AttenuationA three-dimensional axis for the study of femoral neck orientationAn integration of genome-wide association study and gene expression profiling to prioritize the discovery of novel susceptibility Loci for osteoporosis-related traits.Refined QTLs of osteoporosis-related traits by linkage analysis with genome-wide SNPs: Framingham SHAReThe effect of risedronate on hip structural geometry in chemotherapy-induced postmenopausal women with or without use of aromatase inhibitors: a 2-year trial.Background for studies on the treatment of male osteoporosis: state of the art.Osteoporosis: The connection to urologic health.Timing of peak bone mass in Caucasian females and its implication for the prevention of osteoporosis. Inference from a cross-sectional model.Systematic review of raloxifene in postmenopausal Japanese women with osteoporosis or low bone mass (osteopenia).Divergent Significance of Bone Mineral Density Changes in Aging Depending on Sites and Sex Revealed through Separate Analyses of Bone Mineral Content and AreaCalcium intake in health maintenance - a systematic review.Reduced bone formation and increased bone resorption: rational targets for the treatment of osteoporosis.Lean mass predicts hip geometry in men and women with non-insulin-requiring type 2 diabetes mellitusPTH receptor signaling in osteocytes governs periosteal bone formation and intracortical remodeling.Invited Review: Pathogenesis of osteoporosis.The growth and age-related origins of bone fragility in men.Radiographic study on the anatomical characteristics of the proximal femur in Brazilian adults.Proximal hip geometry is linked to several chromosomal regions: genome-wide linkage results from the Framingham Osteoporosis StudyPelvis width associated with bone mass distribution at the proximal femur in children 10-11 years old.Femoral Neck External Size but not aBMD Predicts Structural and Mass Changes for Women Transitioning Through Menopause.Approach to the prostate cancer patient with bone diseaseHip structural geometry in old and old-old age: similarities and differences between men and womenSex-specific differences in progressive glucose intolerance and hip geometry: the Baltimore Longitudinal Study of Aging.Bivariate linkage study of proximal hip geometry and body size indices: the Framingham study.Polymorphisms in the endothelial nitric oxide synthase gene and bone density/ultrasound and geometry in humans.Effect of risedronate on hip structural geometry: a 1-year, double-blind trial in chemotherapy-induced postmenopausal women.Differentiation and proliferation of periosteal osteoblast progenitors are differentially regulated by estrogens and intermittent parathyroid hormone administrationBivariate genome-wide linkage analysis of femoral bone traits and leg lean mass: Framingham studyCorrelation of plain radiographic indices of the hip with quantitative bone mineral density.Sex and the single nucleotide polymorphism: exploring the genetic causes of skeletal sex differences.The amount of periosteal apposition required to maintain bone strength during aging depends on adult bone morphology and tissue-modulus degradation rate.Epidemiology and structural basis of racial differences in fragility fractures in Chinese and Caucasians.Associations between body mass index across adult life and hip shapes at age 60 to 64: Evidence from the 1946 British birth cohort.Mineral and mechanics of bone fragility fractures. A review of fixation methods.Difference in the trajectory of change in bone geometry as measured by hip structural analysis in the narrow neck, intertrochanteric region, and femoral shaft between men and women following hip fracture.Canal to diaphysis ratio as a risk factor for hip fractures and hip fracture pattern.Older men who sustain a hip fracture experience greater declines in bone mineral density at the contralateral hip than non-fractured comparators.Selected contribution: Bone adaptation with aging and long-term caloric restriction in Fischer 344 x Brown-Norway F1-hybrid rats.Hip revision using the Exeter stem, impacted morselized allograft bone and cement: a consecutive 5-year radiostereometric and radiographic study in 15 hips.Combined use of ibandronate and eldecalcitol in postmenopausal Japanese women with osteoporosis.
P2860
Q26798174-ECFA76C0-1F5D-4AFC-A4C0-39C3C46838F1Q28714409-E6E235BF-5782-44A8-862B-DF17624A433BQ30435869-82E8A688-711F-4BD6-ACD4-7209030F987BQ33742242-C0F001B6-A458-445A-9967-3944080E13D5Q33802932-9B15CF16-0BAA-4AE8-A37A-8688D389E64DQ34045842-082AFBF5-21DC-4958-8616-E6FB8AAD7936Q34093512-6B3FF008-7149-48F9-B4C4-F1C09506563BQ34127309-A5BE6422-6B51-4006-B08A-A4C3B683E907Q34482507-657B453C-3B1F-41AC-892C-F5C3F5CE1835Q34507421-801E7A86-424D-4F03-AB37-B8D3503AB0B5Q34728549-6077F2AA-2D8D-40B9-B3B8-EFCC9C837E2EQ35121397-82587A98-E160-4C42-AF77-A31F905D66BEQ35147358-690BD7C9-3892-4C25-9B46-84ADADB03287Q35229920-985432E8-B24C-45DB-8A78-E8944B295F97Q35557866-25D89C90-B058-4450-9CBB-EE9ED4D42DDCQ35895413-314FD2A9-A322-4D4B-A5C1-4902B7C57AB9Q35901651-CE39942E-7608-43D4-9FE6-D7DE1F2EF7F1Q35950352-FDAEC5A9-7AFA-4B9E-9D46-1F50A04CA4BEQ35962211-FBA4EEA4-9CB3-45BF-93D0-F85A70F33D80Q36248483-92FA54D6-887D-4445-B3F2-BCE420B86A56Q36360754-B190D9AD-EB2C-4471-B31F-817035288880Q36380152-AB031BB0-C863-4FA4-846F-CC6D4200A7E7Q36580612-970EACD2-1B9C-4C94-B7EE-77C5FC1A0114Q36647729-B0ED47F1-9BD5-409E-A3EA-334F98709980Q36661653-6A7A5112-1C07-4123-AF1D-B5082F1028F8Q36976210-5F52AB6C-2610-4F80-B53B-27F7C9950DDEQ36976441-3045DC52-DE06-491A-8CF6-B4D1C8B017C4Q37137458-4F467C3C-D63B-4E8D-84C3-87EDBF32DB26Q37422861-9D520585-F798-4854-8C36-8C4B019E5C5BQ37605194-0B6B08D8-9F75-4A45-8218-AF44FDAE457BQ37626885-81DB699C-0507-4F38-8369-42AE5F385162Q37919760-D24ED902-3BF3-47E3-A9F2-ECBB1E7D24FFQ40069887-025993A5-9104-4B82-8C1C-9C0769337DE0Q40909585-8C443CCD-EEF3-48AA-B526-2489C09D125AQ42682902-512EB732-6FD5-435E-AA2D-F832F751719CQ47112731-F6D09E7B-E528-4774-9EE8-A58470475AD6Q47733138-9E7E2A23-35D5-4B97-9072-F12057750EDEQ47830537-3204E328-72BA-4A29-90FD-BA5257EFD902Q51591868-6ADBEF84-4518-400A-9F0E-28BAA9378B71Q54205972-1A4A78CE-4D08-481E-B3D1-C690DBE0B1B6
P2860
Sex differences in geometry of the femoral neck with aging: a structural analysis of bone mineral data.
description
1992 nî lūn-bûn
@nan
1992 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
1992 թվականի հունվարին հրատարակված գիտական հոդված
@hy
1992年の論文
@ja
1992年論文
@yue
1992年論文
@zh-hant
1992年論文
@zh-hk
1992年論文
@zh-mo
1992年論文
@zh-tw
1992年论文
@wuu
name
Sex differences in geometry of ...... analysis of bone mineral data.
@ast
Sex differences in geometry of ...... analysis of bone mineral data.
@en
type
label
Sex differences in geometry of ...... analysis of bone mineral data.
@ast
Sex differences in geometry of ...... analysis of bone mineral data.
@en
prefLabel
Sex differences in geometry of ...... analysis of bone mineral data.
@ast
Sex differences in geometry of ...... analysis of bone mineral data.
@en
P2093
P356
P1476
Sex differences in geometry of ...... analysis of bone mineral data.
@en
P2093
P2888
P356
10.1007/BF00297293
P407
P577
1992-01-01T00:00:00Z
P6179
1003714224