| scholarly article | Q13442814 |
| P50 | author | Truls Raastad | Q42978188 |
| Ernst Albin Hansen | Q43294564 | ||
| P2093 | author name string | Bent R Rønnestad | |
| P2860 | cites work | Psychophysical bases of perceived exertion | Q29615667 |
| Endurance exercise performance: the physiology of champions | Q33344681 | ||
| The effect of endurance training on parameters of aerobic fitness | Q33952482 | ||
| Interference of strength development by simultaneously training for strength and endurance | Q34281096 | ||
| Maximal voluntary force of bilateral and unilateral leg extension | Q34544221 | ||
| Science and cycling: current knowledge and future directions for research | Q35568470 | ||
| Anaerobic fitness tests: what are we measuring? | Q36771162 | ||
| Velocity specificity of resistance training | Q40830442 | ||
| Enzymatic adaptations consequent to long-term strength training | Q44190596 | ||
| Effects of strength training on submaximal and maximal endurance performance capacity in middle-aged and older men. | Q44311352 | ||
| Effect of a 10-week strength training program and recovery drink on body composition, muscular strength and endurance, and anaerobic power and capacity | Q44856449 | ||
| Maximal strength and power, muscle mass, endurance and serum hormones in weightlifters and road cyclists | Q44908530 | ||
| Effects of strength, endurance and combined training on myosin heavy chain content and fibre-type distribution in humans | Q44969469 | ||
| Peak power output predicts maximal oxygen uptake and performance time in trained cyclists | Q46167151 | ||
| Effects of strength training on running economy | Q46271784 | ||
| Neuromuscular blockade of slow twitch muscle fibres elevates muscle oxygen uptake and energy turnover during submaximal exercise in humans | Q46291561 | ||
| Validity and stability of a computerized metabolic system with mixing chamber | Q46729263 | ||
| Cycling efficiency in humans is related to low UCP3 content and to type I fibres but not to mitochondrial efficiency | Q46901938 | ||
| Strength training improves 5-min all-out performance following 185 min of cycling | Q51604259 | ||
| Maximal strength training improves running economy in distance runners | Q51703476 | ||
| Strength training improves supramaximal cycling but not anaerobic capacity | Q53126685 | ||
| Maximal leg-strength training improves cycling economy in previously untrained men. | Q53134531 | ||
| The effects of strength training on endurance performance and muscle characteristics | Q54091344 | ||
| Compatibility of high-intensity strength and endurance training on hormonal and skeletal muscle adaptations | Q54178734 | ||
| Dissimilar effects of one- and three-set strength training on strength and muscle mass gains in upper and lower body in untrained subjects | Q54296529 | ||
| Potential for strength and endurance training to amplify endurance performance | Q54373751 | ||
| Neuromuscular adaptations to concurrent strength and endurance training. | Q55035725 | ||
| Neuromuscular adaptations during concurrent strength and endurance training versus strength training. | Q55036436 | ||
| Compatibility of adaptive responses with combining strength and endurance training. | Q55064929 | ||
| Muscle fibre type, efficiency, and mechanical optima affect freely chosen pedal rate during cycling | Q60686276 | ||
| Maximal strength training improves work economy in trained female cross-country skiers | Q61896422 | ||
| Effects of strength training on lactate threshold and endurance performance | Q67965577 | ||
| Metabolic and respiratory profile of the upper limit for prolonged exercise in man | Q67969745 | ||
| Cycling efficiency is related to the percentage of type I muscle fibers | Q68013914 | ||
| Physiological and biomechanical factors associated with elite endurance cycling performance | Q68203106 | ||
| Aerobic, anaerobic, assistant exercise and weightlifting performance capacities in elite weightlifters | Q69404838 | ||
| Muscle glycogenolysis and H+ concentration during maximal intermittent cycling | Q69948767 | ||
| Maximum bilateral contractions are modified by neurally mediated interlimb effects | Q70129142 | ||
| The specificity of strength training: the effect of posture | Q71470302 | ||
| Poor correlations between isometric tests and dynamic performance: relationship to muscle activation | Q71470305 | ||
| Critical power is related to cycling time trial performance | Q73016616 | ||
| Effects of maximal effort strength training with different loads on dynamic strength, cross-sectional area, load-power and load-velocity relationships | Q73193691 | ||
| Early Phase Changes by Concurrent Endurance and Strength Training | Q73382663 | ||
| Relationship between plasma lactate parameters and muscle characteristics in female cyclists | Q73914205 | ||
| Failure to obtain a unique threshold on the blood lactate concentration curve during exercise | Q74485884 | ||
| Effects of concurrent endurance and strength training on running economy and .VO(2) kinetics | Q74583589 | ||
| The relationship between plasma lactate parameters, Wpeak and 1-h cycling performance in women | Q77118130 | ||
| Physiological Differences Between Professional and Elite Road Cyclists | Q77164523 | ||
| Explosive-strength training improves 5-km running time by improving running economy and muscle power | Q77417616 | ||
| The effects of replacing a portion of endurance training by explosive strength training on performance in trained cyclists | Q77575992 | ||
| Muscle activation and torque development during maximal unilateral and bilateral isokinetic knee extensions | Q77608769 | ||
| Maximal strength training improves aerobic endurance performance | Q78382456 | ||
| Effects of a drink containing creatine, amino acids, and protein combined with ten weeks of resistance training on body composition, strength, and anaerobic performance | Q79805611 | ||
| Endurance and strength training effects on physiological and muscular parameters during prolonged cycling | Q83927165 | ||
| P433 | issue | 5 | |
| P304 | page(s) | 965-975 | |
| P577 | publication date | 2009-12-04 | |
| P1433 | published in | European Journal of Applied Physiology | Q2687577 |
| P1476 | title | Effect of heavy strength training on thigh muscle cross-sectional area, performance determinants, and performance in well-trained cyclists | |
| P478 | volume | 108 |
| Q53775316 | 10 weeks of heavy strength training improves performance-related measurements in elite cyclists |
| Q48714245 | A Time-Saving Method to Assess Power Output at Lactate Threshold in Well-Trained and Elite Cyclists |
| Q57811703 | Adaptations to Concurrent Training in Combination with High Protein Availability: A Comparative Trial in Healthy, Recreationally Active Men |
| Q24598721 | Anaerobic capacity of amateur mountain bikers during the first half of the competition season |
| Q47997161 | Bilateral extracephalic transcranial direct current stimulation improves endurance performance in healthy individuals. |
| Q91706308 | Block periodization of endurance training - a systematic review and meta-analysis |
| Q84247334 | Block periodization of high‐intensity aerobic intervals provides superior training effects in trained cyclists |
| Q90290029 | Comparison of Short-Sprint and Heavy Strength Training on Cycling Performance |
| Q88380149 | Comparison of running and cycling economy in runners, cyclists, and triathletes |
| Q38923257 | Concurrent exercise training: do opposites distract? |
| Q60922324 | Eccentric cycling does not improve cycling performance in amateur cyclists |
| Q82260829 | Effect of heavy strength training on muscle thickness, strength, jump performance, and endurance performance in well-trained Nordic Combined athletes |
| Q35949082 | Effects of Heavy Strength Training on Running Performance and Determinants of Running Performance in Female Endurance Athletes |
| Q54385411 | Effects of different strength training frequencies during reduced training period on strength and muscle cross-sectional area |
| Q87986510 | HIT maintains performance during the transition period and improves next season performance in well-trained cyclists |
| Q37699640 | Heavy strength training improves running and cycling performance following prolonged submaximal work in well-trained female athletes |
| Q84743983 | High volume of endurance training impairs adaptations to 12 weeks of strength training in well-trained endurance athletes |
| Q35950742 | Improved cycling performance with ingestion of hydrolyzed marine protein depends on performance level |
| Q51545179 | In-season strength maintenance training increases well-trained cyclists' performance |
| Q30353316 | Intensive training and reduced volume increases muscle FXYD1 expression and phosphorylation at rest and during exercise in athletes |
| Q48160423 | Mechanisms underlying enhancements in muscle force and power output during maximal cycle ergometer exercise induced by chronic β2-adrenergic stimulation in men. |
| Q34655018 | Optimizing strength training for running and cycling endurance performance: A review |
| Q47450100 | Radial bone size and strength indices in male road cyclists, mountain bikers and controls. |
| Q85835623 | Sex Differences in Time to Fatigue at 100% VO2peak When Normalized for Fat Free Mass |
| Q37855786 | Strategies to optimize concurrent training of strength and aerobic fitness for rowing and canoeing |
| Q51031932 | Strength training improves cycling performance, fractional utilization of VO2max and cycling economy in female cyclists |
| Q90460624 | The Validity of Functional Threshold Power and Maximal Oxygen Uptake for Cycling Performance in Moderately Trained Cyclists |
| Q28307737 | The effect of strength training on performance in endurance athletes |
| Q53189717 | Unique muscularity in cyclists' thigh and trunk: A cross-sectional and longitudinal study |
| Q51480843 | Validity and repeatability of a depth camera-based surface imaging system for thigh volume measurement. |
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