Hélio Roesler scite author profile

The aim of this study was to examine the contact phase during the lateral push-off in the turn of front crawl swimming to determine which biomechanical variables (maximum normalized peak force, contact time, impulse, angle of knee flexion, and total turn time within 15 m) contribute to the performance of this turn technique. Thirty-four swimmers of state, national, and international competitive standard participated in the study. For data collection, the following equipment was used: an underwater force platform, a 30-Hz VHS video camera, and a MiniDv digital camera within an underwater box. Data are expressed as descriptive statistics. Inferential analyses were performed using Pearson's correlation and multiple linear regressions. All variables studied had a significant relationship with turn performance. We conclude that a turn executed with a knee flexion angle of between 100° and 120° provides optimum peak forces to generate impulses that allow the swimmer to lose less time in the turn without the need for an excessive force application and with less energy lost.

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Effect of Gender, Cadence, and Water Immersion on Ground Reaction Forces During Stationary Running

Fontana

Haupenthal²,

Ruschel

et al. 2012

J Orthop Sports Phys Ther

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In vivo vastus lateralis force–velocity relationship at the fascicle and muscle tendon unit level

Fontana

Roesler

Herzog

2014

Journal of Electromyography and Kinesiology

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Kinematic, kinetic and EMG analysis of four front crawl flip turn techniques

Pereira

Ruschel

Hubert

et al. 2015

Journal of Sports Sciences

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This study aimed to analyse the kinematic, kinetic and electromyographic characteristics of four front crawl flip turn technique variants. The variants distinguished from each other by differences in body position (i.e., dorsal, lateral, ventral) during rolling, wall support, pushing and gliding phases. Seventeen highly trained swimmers (17.9 ± 3.2 years old) participated in interventional sessions and performed three trials of each variant, being monitored with a 3-D video system, a force platform and an electromyography (EMG) system. Studied variables: rolling time and distance, wall support time, push-off time, peak force and horizontal impulse at wall support and push-off, centre of mass horizontal velocity at the end of the push-off, gliding time, centre of mass depth, distance, average and final velocity during gliding, total turn time and electrical activity of Gastrocnemius Medialis, Tibialis Anterior, Biceps Femoris and Vastus Lateralis muscles. Depending on the variant, total turn time ranged from 2.37 ± 0.32 to 2.43 ± 0.33 s, push-off force from 1.86 ± 0.33 to 1.92 ± 0.26 BW and centre of mass velocity during gliding from 1.78 ± 0.21 to 1.94 ± 0.22 m · s(-1). The variants were not distinguishable in terms of kinematical, kinetic and EMG parameters during the rolling, wall support, pushing and gliding phases.

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Ground reaction forces in shallow water running are affected by immersion level, running speed and gender

Haupenthal

Fontana

Ruschel

et al. 2013

Journal of Science and Medicine in Sport

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Hélio Roesler

Dynamometric analysis of the maximum force applied in aquatic human gait at 1.3m of immersion

The history of some fundamental concepts in bone biomechanics

Vertical reaction forces and kinematics of backward walking underwater

Analysis of the lateral push-off in the freestyle flip turn

Effect of Gender, Cadence, and Water Immersion on Ground Reaction Forces During Stationary Running

In vivo vastus lateralis force–velocity relationship at the fascicle and muscle tendon unit level

Kinematic, kinetic and EMG analysis of four front crawl flip turn techniques

Ground reaction forces in shallow water running are affected by immersion level, running speed and gender

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