Power output of legs during high intensity cycle ergometry: Influence of hand grip

Baker, Julien S.; Gal, J.; Davies, Bruce; Bailey, D.M.; Morgan, Rhian

doi:10.1016/s1440-2440(01)80003-7

Cited by 31 publications

(25 citation statements)

References 9 publications

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“…Data showed that greater PP (derived from 5-s sprints) and MP (derived from 20-s sprints) values were achieved during the traditional with handgrip protocol than in the absence of handlebar grip. These findings are in agreement with previous work done on adults by Baker et al (2001Baker et al ( , 2002 and demonstrated the implication of the arms and the upper body in cycling mechanics. We suggest that by pulling upon the handlebars, the centre of mass of the whole body is maintained at a constant vertical level, so that leg extension can be directed to pushing down on the pedals.…”

Section: Discussionsupporting

confidence: 93%

“…Nevertheless, during growth, some studies (Doré, Diallo, França et al 2000;Mercier, Mercier, Granier et al 1992;Van Praagh, Fellmann, Bedu et al 1990) observed that total fat-free mass (FFM) was a similar or greater predictor of cycling peak power than lean leg or lean thigh volume. Furthermore, using electromyography on trained male adults, Baker, Gal, Davies et al (2001) showed that the intensity of the electrical activity recorded for the forearm musculature during sprint cycling was similar to that recorded during a maximum voluntary hand grip dynamometer contraction. These findings suggest that during highintensity cycle ergometry, there is an important upper body muscle contribution to cycling peak power (pp).…”

Section: Introductionmentioning

confidence: 74%

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Upper Body Contribution During Leg Cycling Peak Power in Teenage Boys and Girls

Doré

Baker

Jammes

et al. 2006

Research in Sports Medicine

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This study investigated gender differences in upper-body contribution to cycle muscle power in 23 adolescents. All subjects performed two 5-s and one 20-s cycling sprint, using two protocols: with handgrip (WG) and without handgrip (WOG). Maximal handgrip strength was assessed for each individual. Absolute peak and mean cycling power was corrected for total fat-free mass (FFM) and for lean leg volume (LLV). Males showed higher cycling performance than females. Peak power and 20-s mean power (flywheel inertia included), but not optimal velocity, were higher WG than WOG. Especially for peak power, absolute differences between both protocols were higher in males than in females, and were significantly related to handgrip strength. The significant contribution of the upper body suggested that, for standardisation of cycle muscle power, total FFM is a more relevant variable compared with LLV. Furthermore, in adolescents, the higher contribution of the upper body musculature in males partly explained gender differences in peak power.

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Section: Discussionsupporting

confidence: 93%

Section: Introductionmentioning

confidence: 74%

Upper Body Contribution During Leg Cycling Peak Power in Teenage Boys and Girls

Doré

Baker

Jammes

et al. 2006

Research in Sports Medicine

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“…In addition, the arms act as anchors during cycling and may help transfer forces from other muscle groups. It has been reported that there is an increased ability to generate power output with the hands holding the handlebars as opposed to not so doing (Baker et al 2001). The use of toe clips has also been shown to increase power output during cycling (Capmal and Vandewalle 1997).…”

Section: Discussionmentioning

confidence: 99%

Power output of the lower limb during variable inertial loading: a comparison between methods using single and repeated contractions

Pearson

Cobbold

Harridge

2004

European Journal of Applied Physiology

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The power-inertial load relationship of the lower limb muscles was studied during a single leg thrust using the Modified Nottingham Power Rig (mNPR) and during cycling exercise in nine young male subjects. The relationship between peak power and inertial load showed a parabolic-like relationship for mNPR exertions, with a peak [937 (SD 246) W] at 0.158 kg m(2), this being significantly (P <0.05) different from the power generated at both the lowest [723 (162) W] and highest [756 (206) W] inertial loads. In contrast, for cycling exercise power output did not differ significantly between inertial loads, except at the lowest inertia where power output was significantly ( P<0.05) less compared with all other inertial loads. Maximum peak power output during cycling was 1,620 (336) W, which was significantly (P <0.05) greater than that recorded on the mNPR. However, a close association was observed between the mean power generated by each method (r=0.84, P<0.05). The results suggest that during a single contraction a range of inertial loads is required to allow peak power to be expressed. Above a certain critical value, this is unnecessary during cycling movements where the load can be repeatedly accelerated.

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“…The with-grip protocol yielded significantly greater (P<0.05) peak mechanical power output than the without-grip protocol, suggesting a significant contribution from the upper body to the maximal power output measured in the legs (Baker et al 2001b). In addition, as a first step towards quantifying the involvement of the upper body during leg cycle ergometry, surface electromyographs of the forearm musculature were recorded whilst performing each of the test protocols.…”

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confidence: 86%

High intensity exercise cycle ergometer performance: the influence of handgrip and resistive force selection

Baker

2001

Eur J Appl Physiol

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Sir:I read with interest the recent article by Dore´et al. (2001), in particular the section that suggested: ''tissues other than solely lean leg muscle mass (such as the arms, trunk and gluteus maximus) contribute to high intensity cycling performance, and that the external resistive force should be matched to the capability of the active muscle tissue''.I would like to elaborate a little on the contribution of the upper body to high intensity leg power measured using cycle ergometry and the selection of resistive forces.We recently examined the performance of the legs when influenced by activity in the upper body, as shown by handgrip, during high intensity cycle ergometry, and the relationship between total body mass (TBM) and fat free mass (FFM). The with-grip protocol yielded significantly greater (P<0.05) peak mechanical power output than the without-grip protocol, suggesting a significant contribution from the upper body to the maximal power output measured in the legs (Baker et al. 2001b). In addition, as a first step towards quantifying the involvement of the upper body during leg cycle ergometry, surface electromyographs of the forearm musculature were recorded whilst performing each of the test protocols. During the with-grip ergometer tests, the intensity of the electrical activity recorded from the forearm musculature was greater than the intensity of electrical activity recorded from the forearm musculature during 100% isometric voluntary handgrip dynamometer contractions. This suggests maximal isometric-type forearm muscle contraction during the with-grip leg ergometry tests.Researchers should be mindful of this observation both when allocating ergometer loads, and when analysing blood borne metabolites.Isometric contraction has been shown to cause occlusion of the blood vessels passing through and between the activated muscles (Libonati et al. 1998). It is likely that blood samples taken from an antecubital vein, immediately after exercise, would also contain some blood from a tissue that had been occluded, and would not be representative of leg muscle blood. Equally, the subsequent reperfusion of arm musculature during relaxation would have an unknown effect on the concentration of blood-borne metabolites.We have also examined resistive force selection based on TBM and FFM (Baker et al. 2001a) using a traditional handgrip protocol. Increases (P<0.05) in mean (SD) peak power output (PPO) were found using the FFM protocol [1,015 (165) W TBM vs 1,099 (172) W FFM].Significant decreases (P<0.05) were observed for both resistive force selection [7.6 (1.4) kg TBM vs 6.7 (1.1) kg FFM] and for the time taken to reach PPO [3.8 (1.4) s TBM vs 2.9 (1) s FFM]. However, pedal velocity increased (P<0.01) when the two protocols were compared [129.4 (8.2) revolutionsAEmin -1 TBM vs 136.3 (8) revolutionsAEmin )1 FFM]. Rating of perceived exertion was (P<0.05) greater for FFM [18.4 (1.6) TBM vs 19.8 (0.4) FFM]. No differences in power or associated values were found between protocols for mean power output , fatigue...

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Power output of legs during high intensity cycle ergometry: Influence of hand grip

Cited by 31 publications

References 9 publications

Upper Body Contribution During Leg Cycling Peak Power in Teenage Boys and Girls

Upper Body Contribution During Leg Cycling Peak Power in Teenage Boys and Girls

Power output of the lower limb during variable inertial loading: a comparison between methods using single and repeated contractions

High intensity exercise cycle ergometer performance: the influence of handgrip and resistive force selection

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