Musculoskeletal adaptations in chronic spinal cord injury: effects of long-term soleus electrical stimulation training
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Non-pharmacological treatment and prevention of bone loss after spinal cord injury: a systematic reviewEvidence-based prevention and treatment of osteoporosis after spinal cord injury: a systematic review.Low-frequency H-reflex depression in trained human soleus after spinal cord injuryHigh bone density masks architectural deficiencies in an individual with spinal cord injury.Phase-dependent modulation of percutaneously elicited multisegmental muscle responses after spinal cord injuryLongitudinal changes in femur bone mineral density after spinal cord injury: effects of slice placement and peel method.Reliability and responsiveness of musculoskeletal ultrasound in subjects with and without spinal cord injury.Dynamic skeletal muscle stimulation and its potential in bone adaptation.Enhancing muscle force and femur compressive loads via feedback-controlled stimulation of paralyzed quadriceps in humans.Altered mRNA expression after long-term soleus electrical stimulation training in humans with paralysisA minimal dose of electrically induced muscle activity regulates distinct gene signaling pathways in humans with spinal cord injury.Electrical stimulation modulates Wnt signaling and regulates genes for the motor endplate and calcium binding in muscle of rats with spinal cord transection.The effects of electrical stimulation on body composition and metabolic profile after spinal cord injury--Part II.Prior heat stress effects fatigue recovery of the elbow flexor muscles.Whole-Body Electromyostimulation to Fight Osteopenia in Elderly Females: The Randomized Controlled Training and Electrostimulation Trial (TEST-III).The effect of low-magnitude whole body vibration on bone density and microstructure in men and women with chronic motor complete paraplegia.Dose estimation and surveillance of mechanical loading interventions for bone loss after spinal cord injury.High dose compressive loads attenuate bone mineral loss in humans with spinal cord injury.Bone architecture adaptations after spinal cord injury: impact of long-term vibration of a constrained lower limb.Regional cortical and trabecular bone loss after spinal cord injury.The effects of aging and electrical stimulation exercise on bone after spinal cord injury.Muscle and bone plasticity after spinal cord injury: review of adaptations to disuse and to electrical muscle stimulationAsymmetric bone adaptations to soleus mechanical loading after spinal cord injury.Doublet stimulation protocol to minimize musculoskeletal stress during paralyzed quadriceps muscle testing.Reactions of the rat musculoskeletal system to compressive spinal cord injury (SCI) and whole body vibration (WBV) therapy.Low force contractions induce fatigue consistent with muscle mRNA expression in people with spinal cord injury.Challenges, concerns and common problems: physiological consequences of spinal cord injury and microgravity.Neuronal involvement in muscular atrophy.Bone loss at the distal femur and proximal tibia in persons with spinal cord injury: imaging approaches, risk of fracture, and potential treatment options.Interval training elicits higher enjoyment versus moderate exercise in persons with spinal cord injury.Electroacupuncture and Acupuncture Promote the Rat's Transected Median Nerve Regeneration.Effects of endurance and strength-directed electrical stimulation training on the performance and histological properties of paralyzed human muscle: a pilot study.Fatigue and non-fatigue mathematical muscle models during functional electrical stimulation of paralyzed muscle.Identification of a Modified Wiener-Hammerstein System and Its Application in Electrically Stimulated Paralyzed Skeletal Muscle Modeling.In Vivo Assessment of Mitochondrial Dysfunction in Clinical Populations Using Near-Infrared Spectroscopy.Effects of cycling and/or electrical stimulation on bone mineral density in children with spinal cord injury.A feasibility pilot using telehealth videoconference monitoring of home-based NMES resistance training in persons with spinal cord injury.Method to Reduce Muscle Fatigue During Transcutaneous Neuromuscular Electrical Stimulation in Major Knee and Ankle Muscle Groups.Evaluation of serum myostatin and sclerostin levels in chronic spinal cord injured patients.Improving the Efficiency of Electrical Stimulation Activities After Spinal Cord Injury.
P2860
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P2860
Musculoskeletal adaptations in chronic spinal cord injury: effects of long-term soleus electrical stimulation training
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
2007年论文
@zh
2007年论文
@zh-cn
name
Musculoskeletal adaptations in ...... lectrical stimulation training
@ast
Musculoskeletal adaptations in ...... lectrical stimulation training
@en
type
label
Musculoskeletal adaptations in ...... lectrical stimulation training
@ast
Musculoskeletal adaptations in ...... lectrical stimulation training
@en
prefLabel
Musculoskeletal adaptations in ...... lectrical stimulation training
@ast
Musculoskeletal adaptations in ...... lectrical stimulation training
@en
P2860
P356
P1476
Musculoskeletal adaptations in ...... lectrical stimulation training
@en
P2093
Richard K Shields
Shauna Dudley-Javoroski
P2860
P304
P356
10.1177/1545968306293447
P577
2007-03-01T00:00:00Z