Muscle architecture predicts maximum strength and is related to activity levels in cerebral palsy
about
Morphological and functional relationships with ultrasound measured muscle thickness of the lower extremity: a brief reviewHeterogeneity of muscle sizes in the lower limbs of children with cerebral palsy.Automatic thickness estimation for skeletal muscle in ultrasonography: evaluation of two enhancement methodsMuscle plasticity and ankle control after repetitive use of a functional electrical stimulation device for foot drop in cerebral palsy.Rapid force generation is impaired in cerebral palsy and is related to decreased muscle size and functional mobility.Tibialis anterior architecture, strength, and gait in individuals with cerebral palsyArchitectural changes of the gastrocnemius muscle after botulinum toxin type A injection in children with cerebral palsy.Mediating effects of the ICF domain of function and the gross motor function measure on the ICF domains of activity, and participation in children with cerebral palsy.Relationship between Lower Limb Muscle Structure and Function in Cerebral Palsy.Cellular and Morphological Alterations in the Vastus Lateralis Muscle as the Result of ACL Injury and Reconstruction.Relationships between lower limb muscle architecture and activities and participation of children with cerebral palsy.Muscle-Tendon Unit Properties during Eccentric Exercise Correlate with the Creatine Kinase Response.Differential adaptations of muscle architecture to high-velocity versus traditional strength training in cerebral palsy.Influence of ankle plantar flexor muscle architecture and strength on gait in boys with haemophilia in comparison to typically developing children.Local architecture of the vastus intermedius is a better predictor of knee extension force than that of the other quadriceps femoris muscle heads.Hamstring contractures in children with spastic cerebral palsy result from a stiffer extracellular matrix and increased in vivo sarcomere length.Paralympic athletes with cerebral palsy display altered pacing strategies in distance-deceived shuttle running trials.Muscle size and strength in children with cerebral palsy.Comparison of calf muscle architecture between Asian children with spastic cerebral palsy and typically developing peers.Skeletal Muscle Ultrasonography in Nutrition and Functional Outcome Assessment of Critically Ill Children: Experience and Insights From Pediatric Disease and Adult Critical Care Studies [Formula: see text].Vastus lateralis exhibits non-homogenous adaptation to resistance training.Muscle and tendon morphology alterations in children and adolescents with mild forms of spastic cerebral palsy.Relationship Between Functional Level and Muscle Thickness in Young Children With Cerebral Palsy.Estimation of quadriceps femoris muscle dysfunction in the early period after surgery of the knee joint using shear-wave elastography
P2860
Q26738990-FEABED48-572E-45B1-A89A-911C344BD303Q30278093-69084FE1-09F2-435D-8C06-C76E600E206CQ30455317-6D165B62-BCF1-47AC-8FAC-E8FA4692DC20Q30457814-D4D6E45F-CFCC-4B6D-AADA-FD2B4B568325Q30459513-DA654926-CEBF-476F-A578-E1958A729D95Q30463101-CCA29CB9-4496-4F46-B3FA-EB6F941FA485Q33941700-4202A24B-F56A-48F9-A3CB-6B25965EC0CDQ36342590-74A8F40A-EBF8-4344-B682-EAAB0EE96193Q37589500-0750B792-3B9C-4E84-AE84-507DF7FD3498Q39364131-8BF27F47-02CE-4724-A185-DB81071EC462Q42186460-EF9F415F-2C73-4F05-B72D-0F765FC6C54BQ42363080-BC2310D0-F265-4565-9C84-878D3EEDCBE4Q44481245-518928A1-B13E-4BE4-9AE5-87E4A4D713F1Q45858324-7C86B6E6-EF14-4EAC-ACE9-927EEDA4A598Q45983941-573E9284-79BC-4D9B-AE61-DE97BFE66A62Q46123725-71A61282-8269-4490-926C-F5881432BA74Q46959572-FEAE1756-0906-43C7-97BE-AB7E76A77712Q47446302-0A2BF42A-F43D-4CD4-81F5-2E1BB0A781C9Q48302822-72DB6B09-8C2E-4E01-B280-F0D4CC9667EDQ50095770-7A63059C-3A82-4D9F-A331-39D160A9027AQ51103002-2A7331F4-DBE2-42B9-8F15-89ECDB5D8B2DQ55263933-97C9B1E1-1F3E-4D8C-96D9-7A15AAEB6C04Q55331906-DDF435F6-D9E7-45DC-ADD2-F15A75B40374Q58593411-D75B3161-4A3B-4206-9342-7885B29F2FFF
P2860
Muscle architecture predicts maximum strength and is related to activity levels in cerebral palsy
description
2010 nî lūn-bûn
@nan
2010 թուականի Սեպտեմբերին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի սեպտեմբերին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Muscle architecture predicts m ...... ivity levels in cerebral palsy
@ast
Muscle architecture predicts m ...... ivity levels in cerebral palsy
@en
Muscle architecture predicts m ...... ivity levels in cerebral palsy
@nl
type
label
Muscle architecture predicts m ...... ivity levels in cerebral palsy
@ast
Muscle architecture predicts m ...... ivity levels in cerebral palsy
@en
Muscle architecture predicts m ...... ivity levels in cerebral palsy
@nl
prefLabel
Muscle architecture predicts m ...... ivity levels in cerebral palsy
@ast
Muscle architecture predicts m ...... ivity levels in cerebral palsy
@en
Muscle architecture predicts m ...... ivity levels in cerebral palsy
@nl
P2093
P2860
P356
P1433
P1476
Muscle architecture predicts m ...... ivity levels in cerebral palsy
@en
P2093
Diane L Damiano
Kit N Simpson
Noelle G Moreau
Sharlene A Teefey
P2860
P304
P356
10.2522/PTJ.20090377
P577
2010-09-16T00:00:00Z