Using functional loading to influence bone mass and architecture: objectives, mechanisms, and relationship with estrogen of the mechanically adaptive process in bone.
about
Perspective on post-menopausal osteoporosis: establishing an interdisciplinary understanding of the sequence of events from the molecular level to whole bone fractures.Relationship of tibial speed of sound and lower limb length to nutrient intake in preterm infants.Time-course of exercise and its association with 12-month bone changesMultiscale musculoskeletal modelling, data-model fusion and electromyography-informed modelling.Accumulation of physical activity for health gains: what is the evidence?Three-dimensional loading and growth of the zygomatic archWhy do woodpeckers resist head impact injury: a biomechanical investigation.Increased physical activity is associated with enhanced development of peak bone mass in men: a five-year longitudinal studyReduced bone density in children on long-term warfarin.Muscular, skeletal, and neural adaptations following spinal cord injury.Bone mineral density across a range of physical activity volumes: NHANES 2007-2010Adaptive properties of human cementum and cementum dentin junction with age.In vivo loading model to examine bone adaptation in humans: a pilot study.Is exercise of value in the prevention of fragility fractures in men?Analysis of Compression Force in the Hip Joint during Impulsive Exercises: A Preliminary Study for Developing Exercise Protocol for OsteoporosisDiseases affecting bone quality: beyond osteoporosis.Cancellous bone adaptation to tibial compression is not sex dependent in growing miceImpact of mild versus moderate intensity aerobic walking exercise training on markers of bone metabolism and hand grip strength in moderate hemophilic A patients.Exercise and estrogen or estrogen alternatives (phytoestrogens, bisphosphonates)for preservation of bone mineral in postmenopausal women.The effect of physical activity and its interaction with nutrition on bone health.Effects of high-impact training and detraining on femoral neck structure in premenopausal women: a hip structural analysis of an 18-month randomized controlled exercise intervention with 3.5-year follow-up.High dose compressive loads attenuate bone mineral loss in humans with spinal cord injury.Bones' adaptive response to mechanical loading is essentially linear between the low strains associated with disuse and the high strains associated with the lamellar/woven bone transition.Effects of a 20-week high-intensity strength and sprint training program on tibial bone structure and strength in middle-aged and older male sprint athletes: a randomized controlled trial.Exercise effects on bone mineral density in older adults: a meta-analysis of randomized controlled trials.An aerobic weight-loaded pilot exercise intervention for breast cancer survivors: bone remodeling and body composition outcomes.Bone metabolism and hand grip strength response to aerobic versus resistance exercise training in non-insulin dependent diabetic patients.Quantifying load-induced solute transport and solute-matrix interaction within the osteocyte lacunar-canalicular system.Effects of resistance training on bone mineral content and density in adolescent females.Active-resisted stance modulates regional bone mineral density in humans with spinal cord injury.Exercise for optimising peak bone mass in women.Patterns of physical activity and ultrasound attenuation by heel bone among Norfolk cohort of European Prospective Investigation of Cancer (EPIC Norfolk): population based studyEndocannabinoids and the regulation of bone metabolism.Muscle and bone plasticity after spinal cord injury: review of adaptations to disuse and to electrical muscle stimulationAlterations in the Synthesis of IL-1β, TNF-α, IL-6, and Their Downstream Targets RANKL and OPG by Mouse Calvarial Osteoblasts In vitro: Inhibition of Bone Resorption by Cyclic Mechanical StrainImpact + resistance training improves bone health and body composition in prematurely menopausal breast cancer survivors: a randomized controlled trial.Protein kinase C-delta transactivates platelet-derived growth factor receptor-alpha in mechanical strain-induced collagenase 3 (matrix metalloproteinase-13) expression by osteoblast-like cells.Predictors of Bone Status by Quantitative Ultrasound Measurements in a Mountain Village in Japan.Exercise and Bone Macro-architecture: Is Childhood a Window of Opportunity for Osteoporosis Prevention?Unmet needs and current and future approaches for osteoporotic patients at high risk of hip fracture.
P2860
Q30476509-B0021BC2-F37D-4155-8D9D-C530C68D1D7BQ30479685-50841973-F014-43A1-99FB-B0848AADBB0AQ30883528-DFA78EEC-BF65-4B13-A0B2-1B679C957418Q31070221-1457C557-67F8-4A60-B6BB-C1B65AADA892Q33595374-83885BEA-D46C-4B5B-A31D-E84355CF8721Q33619927-5B57488F-596B-4AD0-A3F0-F303D26300BCQ34064482-8A418640-EFD2-456B-A855-790F77E6E287Q34128172-8C80CFFC-3884-478F-97FC-5AB6D08AFC4EQ34391685-8A7FE8EF-FF89-45B1-914C-36F29DC1BC65Q34524823-CB4F5E5E-0F04-47B1-905F-672643569736Q34579994-B9D8A2CB-F89E-4FB7-A198-905CDB4B783EQ34696081-1181DA7F-73DF-4342-8A58-C0D69B0D3846Q34760200-56540624-F8BE-4AF5-B21C-9344280B5A45Q34801593-8AC5787D-A977-4895-858F-64BB16579EAFQ35047185-31538EC9-4335-4F0D-B951-8DBEC6C7415AQ35078847-24EC71DB-C842-474C-82DA-F9FFDECBC160Q35107970-E3EED61B-AA89-4418-9FB2-DAE46F0139BCQ35665204-1C07D735-03BB-482F-89B9-66E156F3A3D6Q35682935-B1E780FF-4BBA-4877-996B-A5312993CF68Q35690128-4E37520C-4DDE-41A2-BB3F-68F607C3A346Q35760438-9265C5A7-44A2-45AD-97FA-A25B8D1282CEQ36028679-7C7DF611-A9D1-4174-A15C-AA7D35AFF3BEQ36189934-63F37FED-60E6-4853-BC64-D29860E50E9EQ36407755-0D82FDB5-9826-499C-B270-EE0FA9D6023BQ36483072-2E8AFF57-300C-44D3-863A-D25C12A4FDACQ36520117-91A0362E-7835-4FBF-905E-976DD062B448Q36612785-F8DF8BC9-3BF3-4B92-96D1-A1F6CD2EF8D5Q36672812-9A7FA394-1EE1-4510-87CE-E3170F7E745EQ36837303-69F1E8A0-4F13-4F17-9622-C1D78D9C5E1EQ36845397-2D9E4E12-18E7-4FC0-808E-D56052D5BC15Q37072000-DD13054A-71DC-4571-A32F-6F1BE02A821CQ37136764-B144D2EF-BFCD-4D57-A73E-AEAA6B04148BQ37143584-E8C1C20D-2378-4FB8-8FD4-72E0C4D9A502Q37195874-167B8E62-B4D4-432B-8C78-F2B81B740A56Q37258283-8BE83C4A-67DA-44F3-84C6-8F6CFED6E396Q37376419-BCCEED3B-78B0-473F-B75D-864463183AE9Q37377737-803E0AFF-D112-4B85-B09E-9A93E884B0F5Q37431403-CB7FEBE9-91C7-4E6A-9B69-757751884181Q37519944-D831A579-B074-47F4-ABE8-97F087FCF01BQ37639402-5B312732-8806-48BD-9F79-11A870CEB1F1
P2860
Using functional loading to influence bone mass and architecture: objectives, mechanisms, and relationship with estrogen of the mechanically adaptive process in bone.
description
1996 nî lūn-bûn
@nan
1996年の論文
@ja
1996年論文
@yue
1996年論文
@zh-hant
1996年論文
@zh-hk
1996年論文
@zh-mo
1996年論文
@zh-tw
1996年论文
@wuu
1996年论文
@zh
1996年论文
@zh-cn
name
Using functional loading to in ...... ally adaptive process in bone.
@en
type
label
Using functional loading to in ...... ally adaptive process in bone.
@en
prefLabel
Using functional loading to in ...... ally adaptive process in bone.
@en
P1433
P1476
Using functional loading to in ...... ally adaptive process in bone.
@en
P2093
P304
P356
10.1016/8756-3282(95)00378-9
P433
P577
1996-01-01T00:00:00Z