Gender disparities in competitive cycling : an analysis of the structural, socio-cultural, and individual factors affecting female participation in Texas

Forrest, Katherine Elizabeth

02 November 2010

Of the 2,858 licensed competitive road cyclists in Texas, female cyclists only account for 12%. The gender disparity in participation numbers suggests possible underlying barriers to entry, recruitment, and retention of female athletes compared to that of male cyclists. The current study sought to understand such issues by exploring the entirety of the competitive road cycling experience of female cyclists in Texas. To accomplish such a task, the current study utilized a mixed methods design consisting of content analysis, interviews, and an online survey. Integrating methods allowed for a more comprehensive understanding of the individual as impacted by structural, socio- cultural, and individual factors and further reveals how such factors are interrelated and mutually reinforcing. Results revealed how socio-culturally informed gendered attitudes and norms heavily impact structural policies, rules, and regulations within competitive cycling. Subsequently, structural factors influenced individual choices, attitudes, and behaviors. Further, results emphasized that individuals are complex beings, and although shaped by their environment, embody personal agency, resistance, and coping. Individual decisions, attitudes, and desires subsequently shaped socio-cultural norms and structural processes. Finally, structural reform strategies are suggested to help increase female participation and retention rates within competitive road cycling in Texas. / text

Females in cycling

Competitive cycling

Female participation

Gender disparities

Female cyclists

Texas

The effect of high intensity resisted cycling with and without explosive resistance training on performance in competitive cyclists

McQuillan, Joe

Unknown Date

Training studies involving competitive runners and road cyclists have shown substantial gains in sprint and endurance performance when sessions of high-intensity interval training were added to their usual training in the competitive phase of a season. Further research has shown large performance benefits in sprint and endurance power (7 - 9%) when cyclists combined explosive single-leg jumps with cycling-specific high-intensity interval training during a competitive season. The aim of the present study was to assess the contribution of the jumps to the gains in performance in competitive cyclists in a randomized control trial.The training protocol for the control group was based on previous experimental work in which the control group (n=8) completed cycle specific interval training followed by a series of explosive single-leg jumps. The experimental group (n=7) carried out the same cycle specific interval training but did not participate in the explosive single-leg jumps. While the current study did not use a true control group, the investigation was carried out in the knowledge that a combination of high intensity interval cycling and explosive single-leg jumps causes changes positive changes in performance. Participants took part in 10 x 30-min sessions consisting four sets of high intensity intermittent cycling (4 x 30-s maximum efforts at 50 - 60 min-1 alternating with 30-s recovery). Between each set of 4 x 30 s sprints the control (ballistic) group carried out one set of explosive single-leg jumps (20 for each leg), while the experimental (continuous) group cycled for 20 s at 50 - 60 min-1.Before and after the training period all cyclists completed an incremental peak power test for assessment of VO2max, lactate threshold, exercise economy and peak power, a 30 s Wingate sprint test and a 20 km time-trial. Relative to the control group the percent mean changes (±90% confidence limits) in the experimental group were: power at 4-mM lactate, -4.2 (±6.3); VO2max, -3.1 (±3.7); mean time-trial power, -0.7 (± 4.7); peak incremental power, -1.7; (±5.0); power at 80% max heart rate, -2.8; (±5.6); Wingate peak power, -4.2; (±7.8). We conclude that high-intensity training may improve performance but the combination of high-intensity training and explosive resistance training in the competitive phase is likely to produce greater gains in trained cyclists than high intensity cycling alone.

Competitive cycling

Randomized controlled trials

Performance gains

High intensity interval training

Explosive single-leg jumps

Training protocols

The effect of high intensity resisted cycling with and without explosive resistance training on performance in competitive cyclists

McQuillan, Joe

Unknown Date

Training studies involving competitive runners and road cyclists have shown substantial gains in sprint and endurance performance when sessions of high-intensity interval training were added to their usual training in the competitive phase of a season. Further research has shown large performance benefits in sprint and endurance power (7 - 9%) when cyclists combined explosive single-leg jumps with cycling-specific high-intensity interval training during a competitive season. The aim of the present study was to assess the contribution of the jumps to the gains in performance in competitive cyclists in a randomized control trial.The training protocol for the control group was based on previous experimental work in which the control group (n=8) completed cycle specific interval training followed by a series of explosive single-leg jumps. The experimental group (n=7) carried out the same cycle specific interval training but did not participate in the explosive single-leg jumps. While the current study did not use a true control group, the investigation was carried out in the knowledge that a combination of high intensity interval cycling and explosive single-leg jumps causes changes positive changes in performance. Participants took part in 10 x 30-min sessions consisting four sets of high intensity intermittent cycling (4 x 30-s maximum efforts at 50 - 60 min-1 alternating with 30-s recovery). Between each set of 4 x 30 s sprints the control (ballistic) group carried out one set of explosive single-leg jumps (20 for each leg), while the experimental (continuous) group cycled for 20 s at 50 - 60 min-1.Before and after the training period all cyclists completed an incremental peak power test for assessment of VO2max, lactate threshold, exercise economy and peak power, a 30 s Wingate sprint test and a 20 km time-trial. Relative to the control group the percent mean changes (±90% confidence limits) in the experimental group were: power at 4-mM lactate, -4.2 (±6.3); VO2max, -3.1 (±3.7); mean time-trial power, -0.7 (± 4.7); peak incremental power, -1.7; (±5.0); power at 80% max heart rate, -2.8; (±5.6); Wingate peak power, -4.2; (±7.8). We conclude that high-intensity training may improve performance but the combination of high-intensity training and explosive resistance training in the competitive phase is likely to produce greater gains in trained cyclists than high intensity cycling alone.

Competitive cycling

Randomized controlled trials

Performance gains

High intensity interval training

Explosive single-leg jumps

Training protocols