The influence of induced micromovement upon the healing of experimental tibial fractures.
about
In silico bone mechanobiology: modeling a multifaceted biological systemMechanical stimulation alters tissue differentiation and molecular expression during bone healingLow-intensity pulsed ultrasound treatment for scaphoid fracture nonunions in adolescents.Refining animal models in fracture research: seeking consensus in optimising both animal welfare and scientific validity for appropriate biomedical use.Knee loading accelerates bone healing in mice.Low-magnitude high-frequency mechanical signals accelerate and augment endochondral bone repair: preliminary evidence of efficacy.Mechanical stimulus to boneImpaired fracture healing with high non-union rates remains irreversible after traumatic brain injury in leptin-deficient mice.The effects of axial displacement on fracture callus morphology and MSC homing depend on the timing of application.Transcriptional profiling and biochemical analysis of mechanically induced cartilaginous tissues in a rat modelRole of parathyroid hormone in the mechanosensitivity of fracture healing.New method for detection of complex 3D fracture motion--verification of an optical motion analysis system for biomechanical studies.Stabilization of distal femur fractures with intramedullary nails and locking plates: differences in callus formation.Evaluation of sixty-eight cases of fracture stabilisation by external hybrid fixation and a proposal for hybrid construct classification.Effects of construct stiffness on healing of fractures stabilized with locking plates.A first order system model of fracture healing.Far cortical locking enables flexible fixation with periarticular locking platesPrediction of the time course of callus stiffness as a function of mechanical parameters in experimental rat fracture healing studies--a numerical study.Novel Perfused Compression Bioreactor System as an in vitro Model to Investigate Fracture HealingInfluence of gender and fixation stability on bone defect healing in middle-aged rats: a pilot study.Elastic stable intramedullary nailing of tibial shaft fractures in children.Effects of in vivo mechanical loading on large bone defect regeneration.What Are the Biomechanical Effects of Half-pin and Fine-wire Configurations on Fracture Site Movement in Circular Frames?Masticatory mechanics of a mandibular distraction osteogenesis site: interfragmentary micromovement.Callus massage after distraction osteogenesis using the concept of lengthening then dynamic platingRap system of stress stimulation can promote bone union after lower tibial bone fracture: a clinical research.The effects of alpha-tocopherol supplementation on fracture healing in a postmenopausal osteoporotic rat modelImproved healing of large segmental defects in the rat femur by reverse dynamization in the presence of bone morphogenetic protein-2.Internal plate fixation of fractures: short history and recent developmentsMechanical load modulates the stimulatory effect of BMP2 in a rat nonunion modelActivity vs. rest in the treatment of bone, soft tissue and joint injuriesDynamic Stabilization with Active Locking Plates Delivers Faster, Stronger, and More Symmetric Fracture-Healing.Mechanotransduction and fracture repairIdentification of a vibration regime favorable for bone healing and muscle in estrogen-deficient ratsFrom Bench to Bedside: How Stiff is Too Stiff? Far-cortical Locking or Dynamic Locked Plating May Obviate the Question.Failed treatment of long bone nonunions with low intensity pulsed ultrasoundProduction of VEGF receptor 1 and 2 mRNA and protein during endochondral bone repair is differential and healing phase specific.Development and preliminary validation of a Function IndeX for Trauma (FIX-IT)Far cortical locking can reduce stiffness of locked plating constructs while retaining construct strength.The multifactorial aetiology of fracture nonunion and the importance of searching for latent infection.
P2860
Q28070192-4DD11099-0AC6-4894-B12A-F2AC7B14E033Q28572930-CB761D98-48FD-446F-969F-2881F57A1891Q30384746-6738B60F-E196-4545-A8AA-EBA851B7D912Q33293225-096891E6-1787-4D48-AFBD-AE5E02A68264Q33294070-0DB03CE3-5769-4E85-B9C9-51973DAAFAA5Q33396710-0FFFDEEF-B1EF-43DA-A5ED-F24F6F6B27DCQ33564165-A5C4F47D-8685-4765-B417-FDDEFB3F3C41Q33856945-084DE200-E54E-4477-81B6-C175CB461A22Q33941513-72374FA0-9A80-4BCC-8BBA-A97F3D000001Q34090485-B5A53412-EDD8-4C8B-AFE9-A970BC1F1DF6Q34167115-A621B93D-20B8-4FFE-8F5C-3AAEF1FD7914Q34190274-B3ED5521-CB1A-4EC1-815E-2CA5591E3FE8Q34217902-DB2A0865-05C4-48B3-B1B5-F73998BA3EC4Q34340337-EB49C195-88F3-4558-AB45-321A63116A2AQ34371182-00298D2F-D0F5-4827-946C-9464729822AEQ34425736-83A9D166-A6A0-402E-BE17-C11DE03700D1Q34670235-1AAF98D6-E47D-415B-BF33-1C79E6DFAC90Q34757877-B5FDCEB4-F3EA-4483-80E6-750DF98CF1CBQ35037593-0C0AA2FC-8D3E-463A-8F79-EEBC7BC370DAQ35242723-BD4815BE-632D-4F91-9843-7E7E2C85914BQ35604765-0618CA86-BADD-4F74-9D55-754697A13878Q35840219-162FFABC-117B-46BC-A056-69A01C77BA0DQ35862671-48271DF1-FCA7-43AB-BDCF-7F107465B59BQ36005521-24853B0E-00DC-4996-B965-F0A3B837EC92Q36062490-7A311A93-7D2D-4BB2-8DEB-884D734EAA89Q36135087-450DAE70-D21E-4C05-9F5F-18CD296A21D4Q36223013-983E47F8-5EBA-437A-B69F-930B4D65E6BAQ36398279-883102E6-108B-4D1A-802D-5EE786CF1956Q36433770-66CA758F-0C88-42A8-A020-ECE066752B17Q36490760-FA08FEA0-047D-450D-A9AA-846535294C62Q36578548-65ED333F-B9A0-426B-BDD5-3250B0F85330Q36679055-2775009B-891C-436C-98E8-4E9B555D1A5AQ36767009-53F8CDDC-5DAB-4D69-AC4E-2D2CFB4A2047Q36844545-C7B0123B-82BE-4C94-8300-D69E286FFFBFQ36952210-1277CF0D-EA46-4667-9F0C-2B5751CC32CEQ37096108-0889F96F-A5E7-40A5-B5A4-CE09A38E94E8Q37174627-861691EA-A3ED-4493-A939-AA5838B74F97Q37209849-9939E066-3D60-4183-BB98-E750FDAD93DFQ37272604-68430171-287B-4DFF-BCEB-55427ABACE71Q37412566-D746C5B2-DCF5-4AFC-B990-B9B570170C05
P2860
The influence of induced micromovement upon the healing of experimental tibial fractures.
description
1985 nî lūn-bûn
@nan
1985年の論文
@ja
1985年学术文章
@wuu
1985年学术文章
@zh
1985年学术文章
@zh-cn
1985年学术文章
@zh-hans
1985年学术文章
@zh-my
1985年学术文章
@zh-sg
1985年學術文章
@yue
1985年學術文章
@zh-hant
name
The influence of induced micromovement upon the healing of experimental tibial fractures.
@en
The influence of induced micromovement upon the healing of experimental tibial fractures.
@nl
type
label
The influence of induced micromovement upon the healing of experimental tibial fractures.
@en
The influence of induced micromovement upon the healing of experimental tibial fractures.
@nl
prefLabel
The influence of induced micromovement upon the healing of experimental tibial fractures.
@en
The influence of induced micromovement upon the healing of experimental tibial fractures.
@nl
P1476
The influence of induced micromovement upon the healing of experimental tibial fractures.
@en
P2093
Goodship AE
Kenwright J
P304
P577
1985-08-01T00:00:00Z