scholarly article | Q13442814 |
P2093 | author name string | Johannes Pleiner | |
Michael Quittan | |||
Veronika Fialka-Moser | |||
Richard Crevenna | |||
Martin Nuhr | |||
Dirk Pette | |||
Günther Wiesinger | |||
Bärbel Gohlsch | |||
Christian Bittner | |||
P2860 | cites work | Molecular diversity of myofibrillar proteins: gene regulation and functional significance | Q28277318 |
Type IIx myosin heavy chain transcripts are expressed in type IIb fibers of human skeletal muscle | Q28288501 | ||
Characterization of human skeletal muscle fibres according to the myosin heavy chains they express | Q28301470 | ||
What does chronic electrical stimulation teach us about muscle plasticity? | Q33656159 | ||
Oxidative capacity of muscle and mitochondria: correlation of physiological, biochemical, and morphometric characteristics | Q33840609 | ||
Transitions of muscle fiber phenotypic profiles. | Q34306520 | ||
Adaptation of mammalian skeletal muscle fibers to chronic electrical stimulation | Q35800488 | ||
Cellular and molecular diversities of mammalian skeletal muscle fibers | Q37865994 | ||
Influence of intermittent long-term stimulation on contractile, histochemical and metabolic properties of fibre populations in fast and slow rabbit muscles | Q39755238 | ||
The adaptive response of skeletal muscle to increased use. | Q40301091 | ||
The mammalian myosin heavy chain gene family | Q41275293 | ||
Mammalian skeletal muscle fiber type transitions | Q41322798 | ||
Responses of muscles of patients with Duchenne muscular dystrophy to chronic electrical stimulation | Q42583849 | ||
Training by low-frequency stimulation of tibialis anterior in spinal cord-injured men. | Q43982819 | ||
Myosin polymorphism in single fibers of chronically stimulated rabbit fast-twitch muscle | Q45264396 | ||
Alpha-cardiac-like myosin heavy chain as an intermediate between MHCIIa and MHCI beta in transforming rabbit muscle | Q48039113 | ||
Transient expression of myosin heavy chain MHCI alpha in rabbit muscle during fast-to-slow transition. | Q52175711 | ||
The dose-related response of rabbit fast muscle to long-term low-frequency stimulation. | Q54113934 | ||
Contractile properties and fatiguability of the human adductor pollicis and first dorsal interosseus: a comparison of the effects of two chronic stimulation patterns. | Q54380789 | ||
Myosin heavy chain isoform transformation in single fibres from m. vastus lateralis in spinal cord injured individuals: effects of long-term functional electrical stimulation (FES). | Q54447045 | ||
A simplified ultrasensitive silver stain for detecting proteins in polyacrylamide gels | Q56879289 | ||
Effects of transcutaneous short-term electrical stimulation on M. vastus lateralis characteristics of healthy young men | Q58812299 | ||
Ipsi- and contralateral fibre transformations by cross-reinnervation. A principle of symmetry. | Q64983252 | ||
"Semi-open" muscle biopsy technique. A simple outpatient procedure | Q66936397 | ||
Electrical stimulation-induced changes in skeletal muscle enzymes of men and women | Q67865233 | ||
Species-specific effects of chronic nerve stimulation upon tibialis anterior muscle in mouse, rat, guinea pig, and rabbit | Q67940227 | ||
Influence of electrical stimulation on the morphological and metabolic properties of paralyzed muscle | Q68056315 | ||
Histochemical, biochemical, and ultrastructural analyses of single human muscle fibers, with special reference to the C-fiber population | Q68080054 | ||
Metabolic differentiation of distinct muscle types at the level of enzymatic organization | Q68600269 | ||
Species-specific responses of muscle lactate dehydrogenase isozymes to increased contractile activity | Q69619071 | ||
Degeneration-regeneration as a mechanism contributing to the fast to slow conversion of chronically stimulated fast-twitch rabbit muscle | Q69996325 | ||
A method for quantitative extraction of enzymes and metabolites from tissue samples in the milligram range | Q70289804 | ||
The sequential replacement of myosin subunit isoforms during muscle type transformation induced by long term electrical stimulation | Q71104606 | ||
Electrical stimulation-induced changes in performance and fiber type proportion of human knee extensor muscles | Q71765764 | ||
Slow-to-fast transitions in myosin expression of rat soleus muscle by phasic high-frequency stimulation | Q71949135 | ||
Human skeletal muscle adaptation in response to chronic low-frequency electrical stimulation | Q72464734 | ||
Actomyosin ATPase. II. Fiber typing by histochemical ATPase reaction | Q72608507 | ||
Training-induced increase in myofibrillar ATPase intermediate fibers in human skeletal muscle | Q72775365 | ||
Energy state and myosin heavy chain isoforms in single fibres of normal and transforming rabbit muscles | Q77501626 | ||
Biochemical and ultrastructural changes of skeletal muscle mitochondria after chronic electrical stimulation in rabbits | Q93582767 | ||
P433 | issue | 2 | |
P304 | page(s) | 202-208 | |
P577 | publication date | 2003-02-28 | |
P1433 | published in | European Journal of Applied Physiology | Q2687577 |
P1476 | title | Functional and biochemical properties of chronically stimulated human skeletal muscle | |
P478 | volume | 89 |
Q50692363 | Alpha-catalytic subunits of 5'AMP-activated protein kinase display fiber-specific expression and are upregulated by chronic low-frequency stimulation in rat muscle. |
Q60054152 | Ambulation capacity and functional outcome in patients undergoing neuromuscular electrical stimulation after cardiac valve surgery: A randomised clinical trial |
Q36315459 | Application of animal models: chronic electrical stimulation-induced contractile activity |
Q38694058 | Aspects of physical medicine and rehabilitation in the treatment of deconditioned patients in the acute care setting: the role of skeletal muscle |
Q58449845 | Calcineurin Regulates Skeletal Muscle Metabolism via Coordinated Changes in Gene Expression |
Q64093975 | Changes in Physical Fitness After 12 Weeks of Structured Concurrent Exercise Training, High Intensity Interval Training, or Whole-Body Electromyostimulation Training in Sedentary Middle-Aged Adults: A Randomized Controlled Trial |
Q30439203 | Could Low-Frequency Electromyostimulation Training be an Effective Alternative to Endurance Training? An Overview in One Adult |
Q48277253 | Diaphragm pacing improves sleep in patients with amyotrophic lateral sclerosis |
Q42122003 | Effects of Neuromuscular Electrical Stimulation Training on Endurance Performance. |
Q54386148 | Effects of electrical muscle stimulation early in the quadriceps and tibialis anterior muscle of critically ill patients. |
Q39823969 | Effects of endurance and strength-directed electrical stimulation training on the performance and histological properties of paralyzed human muscle: a pilot study |
Q44640455 | Electrical stimulation of human lower extremities enhances energy consumption, carbohydrate oxidation, and whole body glucose uptake |
Q55384534 | Functional Exercise Training and Undulating Periodization Enhances the Effect of Whole-Body Electromyostimulation Training on Running Performance. |
Q59072667 | Genetic Dissection of the Physiological Role of Skeletal Muscle in Metabolic Syndrome |
Q35982538 | Human skeletal muscle fiber type specific protein content |
Q33827791 | Intricate effects of primary motor neuronopathy on contractile proteins and metabolic muscle enzymes as revealed by label-free mass spectrometry. |
Q38165143 | Mechanisms modulating skeletal muscle phenotype |
Q26999324 | Metabolic and structural changes in lower-limb skeletal muscle following neuromuscular electrical stimulation: a systematic review |
Q34539228 | Metabolic load during strength training or NMES in individuals with COPD: results from the DICES trial |
Q38111713 | Molecular mechanisms of muscle plasticity with exercise |
Q35219150 | Neural adaptations to electrical stimulation strength training |
Q56639031 | Neuromuscular electrical stimulation training induces atypical adaptations of the human skeletal muscle phenotype: a functional and proteomic analysis |
Q45918229 | Neuromuscular stimulation of quadriceps in patients hospitalised during an exacerbation of COPD: a comparison of low (35 Hz) and high (50 Hz) frequencies. |
Q48183372 | Reply to: Could superimposed electromyostimulation be an effective training to improve aerobic and anaerobic capacity? Methodological considerations for its development. |
Q48149585 | The adaptive response of skeletal muscle: What is the evidence? |
Q59335692 | Whole-Body Electromyostimulation Improves Performance-Related Parameters in Runners |
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