Organization and distribution of intramuscular connective tissue in normal and immobilized skeletal muscles. An immunohistochemical, polarization and scanning electron microscopic study.
about
Pathophysiology of muscle contractures in cerebral palsyUpregulation of interleukin-1β/transforming growth factor-β1 and hypoxia relate to molecular mechanisms underlying immobilization-induced muscle contractureAgent-based computational model investigates muscle-specific responses to disuse-induced atrophy.Periostin secreted by mesenchymal stem cells supports tendon formation in an ectopic mouse model.Contributions of biarticular myogenic components to the limitation of the range of motion after immobilization of rat knee joint.Pericytes: multitasking cells in the regeneration of injured, diseased, and aged skeletal muscle.Spaceflight and hind limb unloading induce similar changes in electrical impedance characteristics of mouse gastrocnemius muscle.Pathophysiology of spasticity: implications for neurorehabilitation.Quantitative analysis of muscle histologic method in rodent facial nerve injuryThe extracellular matrix of the lateral pharyngeal wall in obstructive sleep apnea.Cyclooxygenase-2 inhibitor celecoxib attenuates joint contracture following immobilization in rat knees.Fascia: a morphological description and classification system based on a literature reviewPregnancy-induced adaptations in the intrinsic structure of rat pelvic floor musclesCellular mechanisms of tissue fibrosis. 4. Structural and functional consequences of skeletal muscle fibrosisCircuit modeling of the electrical impedance: part III. Disuse following bone fracture.Intramuscular drug transport under mechanical loading: resonance between tissue function and uptake.Myosteatosis and myofibrosis: relationship with aging, inflammation and insulin resistance.Genetic influences in sport and physical performance.Structure and function of the skeletal muscle extracellular matrix.Electrical stimulation attenuates morphological alterations and prevents atrophy of the denervated cranial tibial muscle.Mechanical loading by fluid shear stress of myotube glycocalyx stimulates growth factor expression and nitric oxide production.Impact of vaginal parity and aging on the architectural design of pelvic floor muscles.Reversibility of abdominal wall atrophy and fibrosis after primary or mesh herniorrhaphy.Original article Muscle extracellular matrix degradation and contractibility following tendon rupture and disuse.Insight in spastic musculoskeletal structures in cerebral palsy: impaired or compensatory structural changes?Muscle mechanical properties of adult and older rats submitted to exercise after immobilization.Skeletal muscle mechanics, energetics and plasticity.Effect of Immobilization on Insoluble Collagen Concentration and Type I and Type III Collagen Isoforms of Rat Soleus Muscle.Age-related deficit in load-induced skeletal muscle growth.The worsening of tibialis anterior muscle atrophy during recovery post-immobilization correlates with enhanced connective tissue area, proteolysis, and apoptosis.Soluble Milk Proteins Improve Muscle Mass Recovery after Immobilization-Induced Muscle Atrophy in Old Rats but Do not Improve Muscle Functional Property Restoration.Resistance to radial expansion limits muscle strain and work.Autologous minced muscle grafts: a tissue engineering therapy for the volumetric loss of skeletal muscle.The deep fascia and retinacula of the equine forelimb - structure and innervation.Relationship between extensibility and collagen expression in immobilized rat skeletal muscle.Cyclic muscle twitch contraction inhibits immobilization-induced muscle contracture and fibrosis in rats.Incisional herniation induces decreased abdominal wall compliance via oblique muscle atrophy and fibrosis.Tenotomy immobilization as a model to investigate skeletal muscle fibrosis (with emphasis on Secreted frizzled-related protein 2).Quantitative and temporal differential recovery of articular and muscular limitations of knee joint contractures; results in a rat model.Bouts of passive stretching after immobilization of the rat soleus muscle increase collagen macromolecular organization and muscle fiber area.
P2860
Q26865007-71B966A6-FA57-4C7C-9178-EA7CB9F4EB96Q28577362-87E5DBD6-B11E-41E6-A680-3BE20DD5CADEQ30300535-55B1E1ED-CD73-41BF-9FF5-6E68E492F21BQ33998055-1A545037-D7E5-4236-A70C-F99BB756AA36Q34042457-76BC0E6F-6B7B-42F2-8228-BE2EA2AE38F4Q34201678-11044C90-03E6-4B33-8EA8-71389A20A640Q34388970-57FD51C9-19AC-45FA-BC38-789ABFC8EA12Q34455092-3DE20A66-BD2E-44ED-89C3-BDDDD997A056Q35357474-687CBCA3-BF19-4E7E-8ABB-EC311165E0C4Q35812457-6669FFC7-FEBC-4ABA-A840-2493C3065E2AQ36173370-CF5A11D3-A273-4DF3-82AF-0A41E52E18C7Q36197892-BD8028E1-628C-48FE-9A16-3F6631B71420Q36590373-52A4998A-F3B1-4844-9BD4-6F5CC2F38D40Q37093579-F7AE4C8D-5181-40BD-B0F7-E9641979CBC7Q37178244-1C337FE6-C836-4E59-A1C5-9776A41B63A0Q37196655-C589B42B-4919-47F6-829D-4357CF63B55EQ37612828-3192515B-6D82-4671-B1A6-30F9DE05E30DQ37933316-4F2FF06E-ACCA-4444-B6E2-122F47ADCDA0Q37939096-1D37CBAD-91E9-4681-B190-9BBCA5BD61F2Q38819425-A8C3865B-8B7B-47C5-9532-491D84D704DAQ39036306-1E270733-9910-4675-A314-F6C7E106B708Q40968702-2BB10E80-A981-4BA0-9E8C-DB9538B31C96Q41362224-C98F72CD-6097-4472-BC7B-5A0086797B8EQ41911350-DAF48547-9033-4D35-93DC-B43D940BF1E9Q41919276-135D1365-09A2-4E0E-AD92-1B896EAB1AE8Q42031522-BB32C5EB-5234-438E-A71E-8EEC6A2BCE03Q42654379-6CB3884E-55BA-40D4-A6D4-7C249D9D0D6EQ43131030-DA37C59B-C48D-40DC-B1A3-EEF662B019FDQ43831608-62DF63B5-8D9B-4E9B-9EB2-ACDF29C28141Q44294298-B3ACE5BB-278E-45FC-A798-A875380230ADQ47348486-9C48ACC8-F248-47E7-B064-32EDC8CC2BAFQ47876518-124FAF82-B999-4635-BA65-0C404306A9F6Q47938733-51D4E090-4ACE-4201-8E8D-E186A447FC54Q48060198-8E84028F-5C87-4AD4-B43B-A60A30B96B27Q50052302-2E7BF7C9-DE07-42C4-B072-68DD884301B7Q51107607-924D783D-5F1C-43AB-83CF-9FA76062FF0EQ52575948-325B3CBD-49FF-45DD-8424-A3E7BA3751DDQ53115057-4C938156-D56D-4EBA-96D5-D3A047A72ACDQ53473481-337A7DF4-273C-44C3-9940-AF58DD5ECB7CQ53587169-9DD24D32-8983-4277-8A79-97FF73D2A96B
P2860
Organization and distribution of intramuscular connective tissue in normal and immobilized skeletal muscles. An immunohistochemical, polarization and scanning electron microscopic study.
description
2002 nî lūn-bûn
@nan
2002 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2002 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2002年の論文
@ja
2002年論文
@yue
2002年論文
@zh-hant
2002年論文
@zh-hk
2002年論文
@zh-mo
2002年論文
@zh-tw
2002年论文
@wuu
name
Organization and distribution ...... ng electron microscopic study.
@ast
Organization and distribution ...... ng electron microscopic study.
@en
type
label
Organization and distribution ...... ng electron microscopic study.
@ast
Organization and distribution ...... ng electron microscopic study.
@en
prefLabel
Organization and distribution ...... ng electron microscopic study.
@ast
Organization and distribution ...... ng electron microscopic study.
@en
P2093
P356
P1476
Organization and distribution ...... ng electron microscopic study.
@en
P2093
Laszló Józsa
Markku Järvinen
Pekka Kannus
Teppo L N Järvinen
Tero A H Järvinen
P2888
P304
P356
10.1023/A:1020904518336
P577
2002-01-01T00:00:00Z
P6179
1018652841