Electrically induced muscle contractions influence bone density decline after spinal cord injury. - Wikidata - awgldk - TriplyDB

Electrically induced muscle contractions influence bone density decline after spinal cord injury.

Electrically induced muscle contractions influence bone density decline after spinal cord injury.

http://www.wikidata.org/entity/Q35724288

about

Does standing protect bone density in patients with chronic spinal cord injury?Non-pharmacological treatment and prevention of bone loss after spinal cord injury: a systematic review Evidence-based prevention and treatment of osteoporosis after spinal cord injury: a systematic review.Doublet electrical stimulation enhances torque production in people with spinal cord injury Effect of chronic activity-based therapy on bone mineral density and bone turnover in persons with spinal cord injury Bone and muscle loss after spinal cord injury: organ interactions.Reliability and responsiveness of musculoskeletal ultrasound in subjects with and without spinal cord injury.Alteration of contraction-to-rest ratio to optimize trabecular bone adaptation induced by dynamic muscle stimulation.Enhancing muscle force and femur compressive loads via feedback-controlled stimulation of paralyzed quadriceps in humans.A minimal dose of electrically induced muscle activity regulates distinct gene signaling pathways in humans with spinal cord injury.Electrical stimulation at the dorsal root ganglion preserves trabecular bone mass and microarchitecture of the tibia in hindlimb-unloaded rats.The effect of low-magnitude whole body vibration on bone density and microstructure in men and women with chronic motor complete paraplegia.Postfatigue potentiation of the paralyzed soleus muscle: evidence for adaptation with long-term electrical stimulation training.Feedback-controlled stimulation enhances human paralyzed muscle performance.Dose estimation and surveillance of mechanical loading interventions for bone loss after spinal cord injury.Musculoskeletal adaptations in chronic spinal cord injury: effects of long-term soleus electrical stimulation training Predictive model of muscle fatigue after spinal cord injury in humans.Peripheral quantitative computed tomography: measurement sensitivity in persons with and without spinal cord injury.Musculoskeletal plasticity after acute spinal cord injury: effects of long-term neuromuscular electrical stimulation training.A biomechanical analysis of exercise in standing, supine, and seated positions: Implications for individuals with spinal cord injury.High dose compressive loads attenuate bone mineral loss in humans with spinal cord injury.Limb segment load inhibits post activation depression of soleus H-reflex in humans.Prevention and Treatment of Bone Loss after a Spinal Cord Injury: A Systematic Review.Mechanisms of osteoporosis in spinal cord injury.Limb compressive load does not inhibit post activation depression of soleus H-reflex in indiviudals with chronic 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 stimulation Asymmetric bone adaptations to soleus mechanical loading after spinal cord injury.Doublet stimulation protocol to minimize musculoskeletal stress during paralyzed quadriceps muscle testing.MRI analysis and clinical significance of lower extremity muscle cross-sectional area after spinal cord injury.Mathematical models of human paralyzed muscle after long-term training.The generation of loads in excess of the osteogenic threshold by physical movement.Can FES-rowing mediate bone mineral density in SCI: a pilot study.Limb Segment Load Inhibits the Recovery of Soleus H-Reflex After Segmental Vibration in Humans.Effect of tendon vibration during wide-pulse neuromuscular electrical stimulation (NMES) on muscle force production in people with spinal cord injury (SCI).Assessing kinematics and kinetics of functional electrical stimulation rowing.

P2860

Q24654183-1D1BEF79-AEB1-46D3-BE27-FB8B001F7943 Q28307736-22E605FE-7D24-47E8-BE3F-F19E0544DD7F Q30234487-417BD88F-3ABA-422D-9115-AFD137D65270 Q33790777-9499C628-06B4-48E4-B27C-74F43E7357C0 Q33893898-A255EA74-3BC1-4A6F-879B-283A20B4DED1 Q34148869-5AF94A22-D521-4C4A-B5D2-3DB037F0E62D Q34169810-BF370104-03E2-481B-AF7A-C190E270EFE6 Q34494281-1BF2EE76-2444-482E-8803-C578AB10FC59 Q34666024-E66504F6-12AB-429A-91EE-2FF2E7C2FFE6 Q34758299-51392941-7DCE-4C71-98C8-64A770F68F1C Q35248668-A6F9B53B-0DB0-4F48-9083-C76EFF3C1E92 Q35418541-8E4817D0-6D95-45A9-B563-EC2D2DD4A62E Q35724224-1649C695-18D7-4AFB-BFC7-225A92D14261 Q35724253-567B3298-4C64-4159-8D9B-7ECC914CE322 Q35724264-3FE68C72-131C-4A97-90E7-DD0F38FE620E Q35724303-CA107B01-D72D-45EA-BB57-C8CC4B0C403C Q35737531-F0E7CBF5-3FDC-49BC-A860-72AC1F82E490 Q35737534-A822E1F0-12C7-4CA6-8ABA-A28E27DF6617 Q35819950-099BC48A-CDEA-4A62-AE87-7440CA4FB44E Q35884632-83BFAC6A-1F32-4A77-A679-6C6101F90CAE Q36028679-5F6AC133-902F-41C9-8FF1-D4F0BABA1710 Q36049278-A5EEC483-6E20-4254-9656-98C294AE0545 Q36073958-5291CD97-7DCC-4507-AC5E-E1D09159FE7B Q36630034-4E16B897-5DA7-4235-AF13-9D9DB1CCFBAA Q36787950-C2B09164-3883-4AD0-8929-65257D782DBE Q36863047-94FD6F8B-5A03-4EC2-801F-41E80678A402 Q37195874-80C605AF-49ED-4A58-A437-082CB92B5D47 Q37348077-63B32349-D0D5-4047-8181-A4E4A5AE94D0 Q37348106-874B8544-8FF6-44A7-96B8-C8963C8B5B3F Q39374476-9164257A-4D88-4B32-9D03-48406892EA21 Q40849555-716212D5-E2E2-4645-8191-5A0A964D9749 Q44117404-0122D883-9149-43DD-B3F1-8336F63509F2 Q44401557-5D535179-AA03-4C15-8A67-D971E02CEB4F Q47707903-A7B5D01C-7AA7-49A8-8ADD-12005B9E6A65 Q50058022-39A0E78C-4656-4FE6-9C72-0AB61940855A Q50334498-821077D6-4BC2-4913-97F7-D842719BBF54

P2860

Electrically induced muscle contractions influence bone density decline after spinal cord injury.

http://www.wikidata.org/entity/Q35724288

description

2006 nî lūn-bûn

@nan

2006年の論文

@ja

2006年論文

@yue

2006年論文

@zh-hant

2006年論文

@zh-hk

2006年論文

@zh-mo

2006年論文

@zh-tw

2006年论文

@wuu

2006年论文

@zh

2006年论文

@zh-cn

name

Electrically induced muscle co ...... line after spinal cord injury.

@ast

Electrically induced muscle co ...... line after spinal cord injury.

@en

type

label

Electrically induced muscle co ...... line after spinal cord injury.

@ast

Electrically induced muscle co ...... line after spinal cord injury.

@en

prefLabel

Electrically induced muscle co ...... line after spinal cord injury.

@ast

Electrically induced muscle co ...... line after spinal cord injury.

@en

P1433

Q35724288-443BF186-6762-4C6E-9A16-AFF6B24AB474

P1476

Q35724288-89F8A55B-A130-46C0-A91E-B0C95278D4BF

P2093

Q35724288-291606EC-501F-4C4D-B775-45FB772B6FB4

Q35724288-5B865D63-C4ED-440B-97E4-6B6DEB5E0D3E

Q35724288-EB4AD811-B0C2-4C08-9E07-872248807880

P2860

Q35724288-1775384E-EA31-4D47-84D8-7354B34654B2

Q35724288-525EB1FF-D666-41DE-9A6E-046894FF4BE3

Q35724288-6AFD351B-1C3A-499E-88FA-BB4279BB0025

Q35724288-6EC938F7-39C7-43E3-B628-FD9313AF4F14

Q35724288-6F928C5A-DEE0-4228-91B2-10E0A48BADC3

Q35724288-732D7A25-7FD8-47CB-BC47-DCC1744E7145

Q35724288-7BE17205-9292-43BE-B8FB-4CB0D0DD7068

Q35724288-81C46882-2E91-4E4C-A642-6FF64990F938

Q35724288-87BF266C-2E2A-4FD7-81C1-637F03D6472E

Q35724288-BDB134E0-753E-4D6E-838B-FF3F748525DB

P304

Q35724288-9FB7CF34-2306-476D-BD64-18F2A34C71E3

P31

Q35724288-4713C3C2-9990-416B-857A-7094B3DDC730

P356

Q35724288-B20AB8D1-9070-4FEA-8550-9891C82DC6FC

P407

Q35724288-C02AAD85-4FAC-48DC-B865-6F7276083A6F

P433

Q35724288-134E2473-4E0F-4665-A5E4-64D1DB3A76EA

P478

Q35724288-17272B41-B8D5-4342-B7A8-C4D0268C91F8

P577

Q35724288-D89B370A-0A35-4D17-8FF9-6DD3CE2BA483

P5875

Q35724288-37AD1355-BBA2-4E34-BE36-FD40E54FD50D

P698

Q35724288-3DB6A33F-F436-4F84-9598-5DB06EA50C19

P932

Q35724288-887F1CF5-3862-4F36-83C0-287D5DB37214

P356

01.BRS.0000201303.49308.A8

P1433

P1476

Electrically induced muscle co ...... line after spinal cord injury.

@en

P2093

Laura A Frey Law

http://www.w3.org/2001/XMLSchema#string

Richard K Shields

http://www.w3.org/2001/XMLSchema#string

Shauna Dudley-Javoroski

http://www.w3.org/2001/XMLSchema#string

P2860

Changes in Achilles tendon moment arm from rest to maximum isometric plantarflexion: in vivo observations in man

Longitudinal study of bone mineral content in the lumbar spine, the forearm and the lower extremities after spinal cord injury.

Bone's mechanostat: a 2003 update.

The loads on the lumbar spine during extreme weight lifting.

Femoral loads during passive, active, and active-resistive stance after spinal cord injury: a mathematical model

Longitudinal study of the bone mineral content and of soft tissue composition after spinal cord section.

Bone metabolism in spinal cord injured individuals and in others who have prolonged immobilisation. A review.

Bone mineral density after bicycle ergometry training.

Validation of a technique for studying functional adaptation of the mouse ulna in response to mechanical loading.

Effect of electrical stimulation-induced cycling on bone mineral density in spinal cord-injured patients.

P304

548-553

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1097/01.BRS.0000201303.49308.A8

http://www.w3.org/2001/XMLSchema#string

P407

P433

5

http://www.w3.org/2001/XMLSchema#string

P478

31

http://www.w3.org/2001/XMLSchema#string

P577

2006-03-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

7268371

http://www.w3.org/2001/XMLSchema#string

P698

16508550

http://www.w3.org/2001/XMLSchema#string

P932

3270313

http://www.w3.org/2001/XMLSchema#string