| scholarly article | Q13442814 |
| P50 | author | Michael Koehle | Q82204989 |
| Nathan Townsend | Q86454867 | ||
| Eliran Mizelman | Q89177637 | ||
| David C Clarke | Q98169756 | ||
| P2093 | author name string | Michael J Puchowicz | |
| Assaf Yogev | |||
| P2860 | cites work | Rationale and resources for teaching the mathematical modeling of athletic training and performance | Q26828356 |
| Some empirical notes on the epo epidemic in professional cycling | Q28258113 | ||
| Accuracy of the Velotron Ergometer and SRM Power Meter | Q29013678 | ||
| Strength training increases endurance time to exhaustion during high-intensity exercise despite no change in critical power | Q30456744 | ||
| Validation of a novel intermittent w' model for cycling using field data | Q30752794 | ||
| Time in human endurance models. From empirical models to physiological models. | Q33694220 | ||
| The effects of a pre-workout supplement containing caffeine, creatine, and amino acids during three weeks of high-intensity exercise on aerobic and anaerobic performance. | Q33787293 | ||
| Prevalence of blood doping in samples collected from elite track and field athletes | Q34026214 | ||
| Reliability of power in physical performance tests | Q34207286 | ||
| Tests of cycling performance | Q34294612 | ||
| Validity of measures is no simple matter | Q34337702 | ||
| Reliability of Time-to-Exhaustion versus Time-Trial Running Tests in Runners | Q57541045 | ||
| A Single-Visit Field Test of Critical Speed | Q57741662 | ||
| Possible origins of undetectable EPO in urine samples | Q60714061 | ||
| Metabolic and respiratory profile of the upper limit for prolonged exercise in man | Q67969745 | ||
| A comparison between methods of measuring anaerobic work capacity | Q67999956 | ||
| A methodological consideration for the determination of critical power and anaerobic work capacity | Q68396435 | ||
| The effects of training on the metabolic and respiratory profile of high-intensity cycle ergometer exercise | Q68707837 | ||
| The y-intercept of the critical power function as a measure of anaerobic work capacity | Q70128114 | ||
| The influence of high-intensity exercise training on the Wlim-Tlim relationship | Q70603101 | ||
| Critical power as a measure of physical work capacity and anaerobic threshold | Q70870513 | ||
| The dynamic calibration of cycle ergometers | Q72135431 | ||
| Y-intercept of the maximal work-duration relationship and anaerobic capacity in cyclists | Q72147653 | ||
| Reproducibility of running time to exhaustion at VO2max in subelite runners | Q72378839 | ||
| A comparison of methods of estimating anaerobic work capacity | Q72723325 | ||
| A method to ensure the accuracy of estimates of anaerobic capacity derived using the critical power concept | Q72736064 | ||
| The influence of resistance training on the critical power function & time to fatigue at critical power | Q73090386 | ||
| Second-generation blood tests to detect erythropoietin abuse by athletes | Q73159066 | ||
| Creatine ingestion increases anaerobic capacity and maximum accumulated oxygen deficit | Q73429351 | ||
| A comparison of critical velocity estimates to actual velocities in predicting simulated rowing performance | Q74206634 | ||
| Reproducibility of self-paced treadmill performance of trained endurance runners | Q74324822 | ||
| Dynamic calibration of mechanically, air- and electromagnetically braked cycle ergometers | Q77354842 | ||
| The effect of oral creatine supplementation on the curvature constant parameter of the power-duration curve for cycle ergometry in humans | Q77959664 | ||
| Muscle metabolic responses to exercise above and below the "critical power" assessed using 31P-MRS | Q80141047 | ||
| Determination of critical power using a 3-min all-out cycling test | Q80250938 | ||
| Reliability of time to exhaustion analyzed with critical-power and log-log modeling | Q81611941 | ||
| The record power profile to assess performance in elite cyclists | Q82336495 | ||
| A false start in the race against doping in sport: concerns with cycling's biological passport | Q82439952 | ||
| Implementation of the biological passport: the experience of the International Cycling Union | Q83121323 | ||
| The power profile predicts road cycling MMP | Q83367386 | ||
| Performance profiling: a role for sport science in the fight against doping? | Q83773433 | ||
| Reliability analysis of the 3-min all-out exercise test for cycle ergometry | Q84180602 | ||
| Responses during exhaustive exercise at critical power determined from the 3-min all-out test | Q85345338 | ||
| Influence of hypoxia on the power-duration relationship during high-intensity exercise | Q85828735 | ||
| Modeling Intermittent Cycling Performance in Hypoxia Using the Critical Power Concept | Q86454870 | ||
| Effect of work and recovery durations on W' reconstitution during intermittent exercise | Q87224794 | ||
| The fight against doping is a fight for the protection of the clean athlete, the health of the athlete and the integrity of sport | Q87750762 | ||
| Annual banned-substance review: analytical approaches in human sports drug testing | Q88841066 | ||
| Relationship between speed and time in running | Q43409615 | ||
| Effects of growth hormone and testosterone therapy on aerobic and anaerobic fitness, body composition and lipoprotein profile in middle-aged men. | Q43519299 | ||
| Accuracy of SRM and power tap power monitoring systems for bicycling | Q43575546 | ||
| Effect of caffeine and ephedrine ingestion on anaerobic exercise performance | Q43688835 | ||
| Metabolic and neuromuscular responses at critical power from the 3-min all-out test | Q43693846 | ||
| Sustainability of critical power determined by a 3-minute all-out test in elite cyclists | Q43709148 | ||
| Modeling the expenditure and reconstitution of work capacity above critical power | Q43750746 | ||
| Effect of ingesting caffeine and ephedrine on 10-km run performance | Q43877137 | ||
| Effects of prolonged low doses of recombinant human erythropoietin during submaximal and maximal exercise | Q43908507 | ||
| Maximal lactate steady state, critical power and EMG during cycling | Q44233749 | ||
| Determination and validity of critical velocity as an index of swimming performance in the competitive swimmer | Q44704420 | ||
| Effect of two and five days of creatine loading on anaerobic working capacity in women | Q44769503 | ||
| Creatine supplementation and exercise performance: an update | Q45111950 | ||
| A six-year monitoring case study of a top-10 cycling Grand Tour finisher | Q45345927 | ||
| Critical velocity as a measure of aerobic fitness in women's rugby sevens. | Q45377471 | ||
| Validity and reliability of critical power field testing | Q45854395 | ||
| Effects of continuous and interval training on the parameters of the power-endurance time relationship for high-intensity exercise | Q46358124 | ||
| Haematological and iron metabolism parameters in professional cyclists during the Giro d'Italia 3-weeks stage race. | Q46622083 | ||
| The critical power model for intermittent exercise | Q47414561 | ||
| The Reliability and Validity of the 3-min All-out Cycling Critical Power Test | Q47895436 | ||
| Temporal changes in physiology and haematology in response to high- and micro-doses of recombinant human erythropoietin | Q47967042 | ||
| A comparison of methods to estimate anaerobic capacity: Accumulated oxygen deficit and W' during constant and all-out work-rate profiles. | Q48051017 | ||
| Measures of reliability in sports medicine and science. | Q49058173 | ||
| Speed trends in male distance running | Q34542857 | ||
| Control of muscle blood flow during exercise: local factors and integrative mechanisms | Q35170190 | ||
| Recombinant erythropoietin and analogues: a challenge for doping control | Q35823318 | ||
| Quantifying test-retest reliability using the intraclass correlation coefficient and the SEM. | Q36037496 | ||
| Challenges in detecting the abuse of growth hormone in sport | Q36195365 | ||
| The critical power and related whole-body bioenergetic models | Q36311913 | ||
| Validity, reliability and sensitivity of measures of sporting performance | Q37112891 | ||
| A review of vision-based motion analysis in sport | Q37331936 | ||
| Methodological approach to the first and second lactate threshold in incremental cardiopulmonary exercise testing | Q37339590 | ||
| The athlete's biological passport and indirect markers of blood doping | Q37658560 | ||
| Applications of GPS technologies to field sports | Q37930847 | ||
| Metabolic responses at various intensities relative to critical swimming velocity. | Q38085491 | ||
| Monitoring of biological markers indicative of doping: the athlete biological passport | Q38198584 | ||
| Variability of competitive performance of elite athletes: a systematic review | Q38238434 | ||
| Prevalence of doping use in elite sports: a review of numbers and methods | Q38244410 | ||
| Skeletal muscle fatigue and decreased efficiency: two sides of the same coin? | Q38358288 | ||
| Multiday acute sodium bicarbonate intake improves endurance capacity and reduces acidosis in men. | Q38453960 | ||
| Effects of four weeks of high-intensity interval training and creatine supplementation on critical power and anaerobic working capacity in college-aged men. | Q38493035 | ||
| The relationship between movement speed and duration during soccer matches | Q38652021 | ||
| Applying the Critical Speed Concept to Racing Strategy and Interval Training Prescription | Q38838533 | ||
| Knowledge is power: Issues of measuring training and performance in cycling. | Q38968123 | ||
| The 'Critical Power' Concept: Applications to Sports Performance with a Focus on Intermittent High-Intensity Exercise | Q39195119 | ||
| Standards for talking and thinking about validity | Q39200841 | ||
| The mechanistic bases of the power-time relationship: muscle metabolic responses and relationships to muscle fibre type. | Q39949443 | ||
| The distance-time relationship over a century of running Olympic performances: A limit on the critical speed concept. | Q40259198 | ||
| A definition and systems view of anaerobic capacity | Q40559930 | ||
| The critical power concept. A review | Q40783903 | ||
| Self-pacing increases critical power and improves performance during severe-intensity exercise | Q40822542 | ||
| Establishing Duration-Specific Running Intensities From Match-Play Analysis in Rugby League. | Q40890765 | ||
| Sleep, Travel, and Recovery Responses of National Footballers During and After Long-Haul International Air Travel. | Q40970849 | ||
| The relationship between power output and endurance: a brief review | Q41118656 | ||
| Acute hyperhydration reduces athlete biological passport OFF-hr score. | Q41430233 | ||
| Work-exhaustion time relationships and the critical power concept. A critical review | Q41547741 | ||
| Prediction of Critical Power and W' in Hypoxia: Application to Work-Balance Modelling. | Q41952688 | ||
| Validity of critical frequency test for measuring table tennis aerobic endurance through specific protocol | Q42159035 | ||
| Determinants of curvature constant (W') of the power duration relationship under normoxia and hypoxia: the effect of pre-exercise alkalosis. | Q42291994 | ||
| Anaerobic contribution to distance running performance of trained cross-country athletes | Q42662903 | ||
| Critical Power: An Important Fatigue Threshold in Exercise Physiology | Q42709220 | ||
| Endogenous steroid profiling in the athlete biological passport | Q43178313 | ||
| Effect of recovery duration from prior exhaustive exercise on the parameters of the power-duration relationship | Q43186533 | ||
| Influence of hyperoxia on muscle metabolic responses and the power-duration relationship during severe-intensity exercise in humans: a 31P magnetic resonance spectroscopy study | Q43211416 | ||
| Isoperformance curves: an application in team selection | Q43228282 | ||
| Effect of induced alkalosis on the power-duration relationship of "all-out" exercise. | Q43232522 | ||
| Caffeine Increases Work Done above Critical Power, but Not Anaerobic Work. | Q50497792 | ||
| New insights for identification of doping with recombinant human erythropoietin micro-doses after high hydration. | Q50615051 | ||
| Biological variation in variables associated with exercise training. | Q51020284 | ||
| Comparison of Critical Power and W' Derived From 2 or 3 Maximal Tests. | Q51027706 | ||
| Applying the critical velocity model for an off-season interval training program. | Q51265351 | ||
| Critical velocity: a predictor of 2000-m rowing ergometer performance in NCAA D1 female collegiate rowers. | Q51463108 | ||
| The power-duration relationship of high-intensity exercise: from mathematical parameters to physiological mechanisms. | Q51568871 | ||
| Exercise Intensity Thresholds: Identifying the Boundaries of Sustainable Performance. | Q51665339 | ||
| Tour de France, Giro, Vuelta, and classic European races show a unique progression of road cycling speed in the last 20 years. | Q51697415 | ||
| A 'ramp-sprint' protocol to characterise indices of aerobic function and exercise intensity domains in a single laboratory test. | Q51719810 | ||
| Speed trends of major cycling races: does slower mean cleaner? | Q51722424 | ||
| Parameters of the 3-Minute All-Out Test: Overestimation of Competitive-Cyclist Time-Trial Performance in the Severe-Intensity Domain. | Q51757432 | ||
| Bayesian detection of abnormal values in longitudinal biomarkers with an application to T/E ratio. | Q51939506 | ||
| Effect of oral creatine ingestion on parameters of the work rate-time relationship and time to exhaustion in high-intensity cycling. | Q52188557 | ||
| Relationship of critical velocity to marathon running performance. | Q52284785 | ||
| The accuracy of the critical velocity test for predicting time to exhaustion during treadmill running | Q52426462 | ||
| A high velocity treadmill running test to assess endurance running potential. | Q52696084 | ||
| The Athlete Biological Passport: an integral element of innovative strategies in antidoping. | Q53092998 | ||
| Current markers of the Athlete Blood Passport do not flag microdose EPO doping. | Q53115109 | ||
| P275 | copyright license | Creative Commons Attribution 4.0 International | Q20007257 |
| P6216 | copyright status | copyrighted | Q50423863 |
| P304 | page(s) | 643 | |
| P577 | publication date | 2018-06-06 | |
| P1433 | published in | Frontiers in Physiology | Q2434141 |
| P1476 | title | The Critical Power Model as a Potential Tool for Anti-doping | |
| P478 | volume | 9 |
| Q93387272 | Annual banned-substance review: Analytical approaches in human sports drug testing | cites work | P2860 |
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