scholarly article | Q13442814 |
P50 | author | Martino V Franchi | Q57313890 |
Neil D. Reeves | Q39186628 | ||
P2093 | author name string | Marco V Narici | |
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Decline running produces more sarcomeres in rat vastus intermedius muscle fibers than does incline running | Q72464308 | ||
Muscle-fiber pennation angles are greater in hypertrophied than in normal muscles | Q72912952 | ||
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The relation between force, velocity and integrated electrical activity in human muscles | Q73403047 | ||
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Muscle structure and theories of contraction | Q74709864 | ||
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Muscle activation differences between eccentric and concentric isokinetic exercise | Q77547482 | ||
The relation between force and speed in muscular contraction | Q80330090 | ||
Influence of concentric and eccentric resistance training on architectural adaptation in human quadriceps muscles | Q80838246 | ||
Effects of dynamic resistance training on fascicle length and isometric strength | Q83142740 | ||
Effects of eccentric strength training on biceps femoris muscle architecture and knee joint range of movement | Q83448932 | ||
Differential adaptations to eccentric versus conventional resistance training in older humans | Q83734169 | ||
Architectural, functional and molecular responses to concentric and eccentric loading in human skeletal muscle | Q87030489 | ||
Effects of divergent resistance exercise contraction mode and dietary supplementation type on anabolic signalling, muscle protein synthesis and muscle hypertrophy | Q87369886 | ||
Early-phase musculoskeletal adaptations to different levels of eccentric resistance after 8 weeks of lower body training | Q87421616 | ||
Investigation of supraspinatus muscle architecture following concentric and eccentric training | Q88164582 | ||
Mechanisms and Mediators of the Skeletal Muscle Repeated Bout Effect | Q88629298 | ||
Muscular performance after concentric and eccentric exercise in trained men | Q95818081 | ||
Reduced skeletal muscle satellite cell number alters muscle morphology after chronic stretch but allows limited serial sarcomere addition | Q46257168 | ||
Anabolic signaling and protein synthesis in human skeletal muscle after dynamic shortening or lengthening exercise | Q46786550 | ||
Impact of range of motion during ecologically valid resistance training protocols on muscle size, subcutaneous fat, and strength | Q47238121 | ||
Changes in muscle strength, muscle fibre size and myofibrillar gene expression after immobilization and retraining in humans | Q47242525 | ||
Similar increases in muscle size and strength in young men after training with maximal shortening or lengthening contractions when matched for total work | Q47366243 | ||
Behavior of fascicles and the myotendinous junction of human medial gastrocnemius following eccentric strength training | Q48857174 | ||
Eccentric resistance training increases and retains maximal strength, muscle endurance, and hypertrophy in trained men. | Q51738564 | ||
Expression of collagen and related growth factors in rat tendon and skeletal muscle in response to specific contraction types. | Q51751525 | ||
Myofibrillar damage following intense eccentric exercise in man. | Q52501950 | ||
Differential serial sarcomere number adaptations in knee extensor muscles of rats is contraction type dependent. | Q52978625 | ||
Architectural Changes of the Biceps Femoris Long Head after Concentric or Eccentric Training. | Q53313574 | ||
Short-term high- vs. low-velocity isokinetic lengthening training results in greater hypertrophy of the elbow flexors in young men. | Q53874783 | ||
The role of metabolites in strength training. I. A comparison of eccentric and concentric contractions. | Q54184590 | ||
Influence of eccentric actions on skeletal muscle adaptations to resistance training | Q54287308 | ||
Effects of eccentric and concentric resistance training on skeletal muscle substrates, enzyme activities and capillary supply. | Q54311364 | ||
Is titin a 'winding filament'? A new twist on muscle contraction. | Q54562398 | ||
Adaptation to chronic eccentric exercise in humans: the influence of contraction velocity. | Q55035380 | ||
The effects of eccentric and concentric training at different velocities on muscle hypertrophy. | Q55036560 | ||
Malleability of the motor system: a comparative approach. | Q55061293 | ||
Stretch-induced growth in chicken wing muscles: a new model of stretch hypertrophy. | Q55063114 | ||
Effects of concentric and eccentric training on muscle strength, cross-sectional area, and neural activation. | Q55066802 | ||
Adaptive responses to muscle lengthening and shortening in humans. | Q55066828 | ||
Mixed muscle protein synthesis and breakdown after resistance exercise in humans. | Q55067147 | ||
Neuromuscular Adaptations Associated with Knee Joint Angle-Specific Force Change | Q57540912 | ||
Muscle conduction velocity, strength, neural activity, and morphological changes after eccentric and concentric training | Q57652971 | ||
Mode and Speed Specificity of Eccentric and Concentric Exercise Training | Q59604023 | ||
Fascicle length does increase in response to longitudinal resistance training and in a contraction-mode specific manner | Q36515829 | ||
The influence of frequency, intensity, volume and mode of strength training on whole muscle cross-sectional area in humans | Q36746740 | ||
Plasticity of human skeletal muscle: gene expression to in vivo function. | Q36881964 | ||
Altering the length-tension relationship with eccentric exercise : implications for performance and injury | Q36920604 | ||
High-frequency electrical stimulation reveals a p38-mTOR signaling module correlated with force-time integral | Q36958704 | ||
Mysteries of muscle contraction | Q37097827 | ||
Neural control of shortening and lengthening contractions: influence of task constraints | Q37309930 | ||
The effects of eccentric versus concentric resistance training on muscle strength and mass in healthy adults: a systematic review with meta-analysis | Q37316237 | ||
Contraction mode itself does not determine the level of mTORC1 activity in rat skeletal muscle | Q37339231 | ||
The metabolic effects of exercise-induced muscle damage | Q37441084 | ||
Physiological Mechanisms of Eccentric Contraction and Its Applications: A Role for the Giant Titin Protein | Q37633448 | ||
Eccentric Exercise and the Critically Ill Patient | Q37671491 | ||
What is the role of titin in active muscle? | Q37966929 | ||
Muscle protein synthesis in response to nutrition and exercise | Q37979988 | ||
Mechanisms of enhanced force production in lengthening (eccentric) muscle contractions. | Q38083538 | ||
Eccentric exercise training: modalities, applications and perspectives | Q38105294 | ||
Molecular mechanisms of muscle plasticity with exercise | Q38111713 | ||
Lengthening our perspective: morphological, cellular, and molecular responses to eccentric exercise. | Q38137031 | ||
Identification of novel TGF-beta /Smad gene targets in dermal fibroblasts using a combined cDNA microarray/promoter transactivation approach. | Q38302488 | ||
Architectural adaptations of muscle to training and injury: a narrative review outlining the contributions by fascicle length, pennation angle and muscle thickness. | Q38714031 | ||
Connective tissue regeneration in skeletal muscle after eccentric contraction-induced injury. | Q38937571 | ||
Chronic Adaptations to Eccentric Training: A Systematic Review | Q38959252 | ||
Mechanism of work-induced hypertrophy of skeletal muscle | Q39754961 | ||
Accelerated de novo sarcomere assembly by electric pulse stimulation in C2C12 myotubes | Q40147251 | ||
Fiber architecture and muscle function | Q40242969 | ||
Injury to skeletal muscle fibers during contractions: conditions of occurrence and prevention | Q40783531 | ||
Extracellular matrix remodeling and its contribution to protective adaptation following lengthening contractions in human muscle. | Q41161248 | ||
Use of intermittent stretch in the prevention of serial sarcomere loss in immobilised muscle | Q41222222 | ||
Eccentric muscle action increases site-specific osteogenic response | Q41690415 | ||
The importance of stretch and contractile activity in the prevention of connective tissue accumulation in muscle | Q42076057 | ||
Early structural remodeling and deuterium oxide-derived protein metabolic responses to eccentric and concentric loading in human skeletal muscle | Q42645627 | ||
Effects of strength training with eccentric overload on muscle adaptation in male athletes | Q43235983 | ||
Muscle activation during maximal voluntary eccentric and concentric knee extension | Q43407096 | ||
Muscle architecture adaptations to knee extensor eccentric training: rectus femoris vs. vastus lateralis | Q43573998 | ||
Actin rotates as myosin translates | Q43811755 | ||
The contractile response during steady lengthening of stimulated frog muscle fibres | Q44197386 | ||
Whey protein hydrolysate augments tendon and muscle hypertrophy independent of resistance exercise contraction mode | Q44830649 | ||
Voluntary activation level and muscle fiber recruitment of human quadriceps during lengthening contractions | Q44838216 | ||
Myofibrillar and collagen protein synthesis in human skeletal muscle in young men after maximal shortening and lengthening contractions | Q45168917 | ||
Similar acute molecular responses to equivalent volumes of isometric, lengthening, or shortening mode resistance exercise | Q46079796 | ||
Metabolic and vascular limb differences affected by exercise, gender, age, and disease | Q46140448 | ||
P921 | main subject | metabolic adaptation | Q47171912 |
P304 | page(s) | 447 | |
P577 | publication date | 2017-07-04 | |
P1433 | published in | Frontiers in Physiology | Q2434141 |
P1476 | title | Skeletal Muscle Remodeling in Response to Eccentric vs. Concentric Loading: Morphological, Molecular, and Metabolic Adaptations | |
P478 | volume | 8 |