Maximal torque- and power-pedaling rate relationships for elite sprint cyclists in laboratory and field tests

Gardner, Andrew S.; Martin, James C.; Martin, David T.; Barras, Martin; Jenkins, David G.

doi:10.1007/s00421-007-0498-4

Cited by 93 publications

(110 citation statements)

References 18 publications

(39 reference statements)

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“…The parabolic power-crank velocity relationship seen in this study emphasises the influence of crank rate on peak power. The optimum velocity for maximum power output was 125 rpm, which is surprisingly similar to the ω opt during elite track cycling (~ 129 rpm (Dorel et al 2005;Gardner et al 2007)). The relatively short upper limbs and greater crank length of grinding compared to cycling (250 vs 170 mm (Dorel et al 2005)) would be expected to lead to a greater joint excursion during each revolution with grinding.…”

Section: Minmentioning

confidence: 55%

“…This may have an important bearing on the selection of gear ratios and the optimisation of power production during big-boat sailing. During elite sprint cycling a polynomial power-velocity relationship has been described (Martin et al 1997;Dorel et al 2005;Gardner et al 2007), and contrary to the hyperbolic force-velocity relationship of isolated muscle (Wilkie 1949), the relationship between torque and velocity appears to be linear (Martin et al 1997;Dorel et al 2005;Gardner et al 2007;Sprague et al 2007). Similar results have been found during seated arm cranking (Vandewalle et al 1989;Vanderthommen et al 1997).…”

Section: Introductionmentioning

confidence: 99%

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Aerobic power and peak power of elite America’s Cup sailors

2009

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Big-boat yacht racing is one of the only able bodied sporting activities where standing armcranking ('grinding') is the primary physical activity. However, the physiological capabilities of elite sailors for standing arm-cranking have been largely unreported. The purpose of the study was to assess aerobic parameters, VO 2peak and lactate threshold (OBLA), and anaerobic performance, torque-and power-crank velocity relationships and therefore peak power (P max ) and optimum crank-velocity (ω opt ), of America's Cup sailors during standing arm-cranking. Thirty-three elite professional sailors performed a step test to exhaustion, and a subset of ten grinders performed maximal 7 s isokinetic sprints at different crank velocities, using a standing arm-crank ergometer. VO 2peak was 4.7(0.5) L/min (range: 3.6-5.5 L/min) at a power output of 332(44) W (range: 235-425 W). OBLA occurred at a power output of 202(31) W (61% of W max ) and VO 2 of 3.3(0.4) L/min (71% of VO 2peak ). The torque-crank velocity relationship was linear for all participants (r=0.9(0.1)). P max was 1420(37) W (range: 1192-1617 W), and ω opt was 125(6) rpm. These data are among the highest upper-body anaerobic and aerobic power values reported. The unique nature of these athletes, with their high fat-free mass and specific selection and training for standing arm cranking, likely accounts for the high values. The influence of crank velocity on peak power implies that power production during on-board 'grinding' may be optimised through the use of appropriate gear-ratios and the development of efficient gear change mechanisms.

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Section: Minmentioning

confidence: 55%

Section: Introductionmentioning

confidence: 99%

Aerobic power and peak power of elite America’s Cup sailors

2009

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“…Previous field-based BMX research has shown that peak power output (2087 ± 157W) occurred at a cadence of 212 ± 3.5revs·min -1 (Herman et al, 2009). Gardner et al (2007 ascertained that peak power (1791 ± 169W) occurred at much lower cadences (128 ± 7revs·min -1 ) in velodrome track sprint cyclists.…”

Section: Introductionmentioning

confidence: 91%

“…This graph was used to extrapolate an optimal theoretical cadence that elicited peak power (122 ± 18revs·min -1 ). Previous studies in this area (Sergeant et al, 1981;Vandewalle et al, 1985;Martin et al, 2007), albeit in other cycling disciplines, suggested that the parabolic shape used to identify optimal relationships cannot be used to accurately ascertain the relationship from a single test. Subsequently, the actual optimal cadence to elicit peak power in BMX cyclists may be different from that reported by Debraux and Bertucci (2011).…”

Section: Introductionmentioning

confidence: 99%

Effect of cadence selection on peak power and time of power production in elite BMX riders: A laboratory based study

Rylands

Roberts

Hurst

et al. 2016

Journal of Sports Sciences

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The aims of this study were to analyse the optimal cadence for peak power production and time to peak power in bicycle motocross (BMX) riders. Six male elite BMX riders volunteered for the study. Each rider completed 3 maximal sprints at a cadence of 80, 100, 120 and 140revs·min -1 on a laboratory Schoberer Rad Messtechnik (SRM) cycle ergometer in isokinetic mode. The riders' mean values for peak power and time of power production in all three tests were recorded. The BMX riders produced peak power (1105± 139W) at 100revs·min -1 with lower peak power produced at 80revs·min -1 (1060± 69W), 120revs·min -1 (1077± 141W) and 140revs·min -1 (1046± 175W).The lowest time of power production was attained at 120revs·min -1 in 2.5± 1.07s.Whilst cadence of 80revs·min -1 (3.5 ± 0.8) 100revs·min -1 (3.00 ± 1.13) and 140revs·min -1 (3.50 ± 0.88) all recorded a higher time of power production. The results indicate that the optimal cadence for producing peak power and reducing the time to peak power is attained at a comparatively low cadence for a cycling sprint event. These findings will both enable riders to select optimal gear ratios and have an impact on training focus.

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“…Nowadays, sports training professionals use different devices for training control in an increasingly widespread way (Gardner, Martin, Martin, Barras, & Jenkins, 2007;Halson, 2014;Mroczek, Kawczynski, Superlak, & Chmura, 2013), particularly the portable and easy-to-use ones. The development and improvement of practical and accessible evaluation methods to accurately measure performance are thus issues of high interest for creating individual workout plans.…”

Section: Introductionmentioning

confidence: 99%

Untitled

2017

JPES

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Abstract:Problem Statement: The aim of our study was to analyse the influence of body cooling through fan airflow, in acute physiological responses of elite cyclists during a maximal progressive exercise with four stages. Approach: Nine male cyclists, from the sub-23 and elite category (average age, 26.11 ± 5.11 years-old; average weight, 68.69 ± 7.28 kg; average height, 172.87 ± 3.53 cm) performed, in random order, two discontinued maximum cycling tests with progressive increments: one with fan airflow ~10km/h-1 (~3m.s-1), and the other without it, with an initial load of 150 Watts (W), and an increase of 50 Wevery 6-minute long stage, until exhaustion. In both test conditions, the heart rate (HR), oxygen consumption (VO2), blood lactate concentration [La], tympanic temperature (TT), and rating of perceived exertion (RPE), were measured. Results: When the test conditions were compared, no significant differences were found between the stages for HR and RPE. Significant differences were noted for La, only at the 4th stage of the test (p=0.008). The VO2max was significantly different between the protocols (p=0.004), with significant variations at stage 2 (p=0.033), and 3 (p=0.028). TT was significantly lower (p<0.05) during all the four stages of the protocol. With the exception of HR, all the registered maximum values were significantly different (p>0.05) between the two test conditions and were achieved in the stage in which each subject reached VO2max. Conclusions: The speed of airflow at ~10 km.h-1 does seem to induce significant variations in the acute physiological responses of elite cyclists, as seen during a discontinued maximal progressive cycling test.

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Maximal torque- and power-pedaling rate relationships for elite sprint cyclists in laboratory and field tests

Cited by 93 publications

References 18 publications

Aerobic power and peak power of elite America’s Cup sailors

Aerobic power and peak power of elite America’s Cup sailors

Effect of cadence selection on peak power and time of power production in elite BMX riders: A laboratory based study

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