Your search keyword '"Madison Pearson"' showing total 2 results

1. Criterion Validity, and Interunit and Between-Day Reliability of the FLEX for Measuring Barbell Velocity During Commonly Used Resistance Training Exercises

Author

Jonathon Weakley, Daniel Chalkley, Harry F. Dorrell, Amador García-Ramos, Rich D. Johnston, Andrew D. Townshend, Matthew Morrison, Michael H. Cole, and Madison Pearson

Subjects

Adult, Male, Adolescent, Weight Lifting, Correlation coefficient, Coefficient of variation, Physical Therapy, Sports Therapy and Rehabilitation, Squat, 030204 cardiovascular system & hematology, Bench press, Motion, Young Adult, bench press, 03 medical and health sciences, 0302 clinical medicine, One-repetition maximum, Statistics, Criterion validity, Humans, Orthopedics and Sports Medicine, Reliability (statistics), Mathematics, back squat, Data Collection, Lasers, Reproducibility of Results, Resistance Training, C600 Sports Science, 030229 sport sciences, General Medicine, Confidence interval, mean concentric velocity, Female, measurement, velocity-based training

Abstract

Weakley, J, Chalkley, D, Johnston, R, García-Ramos, A, Townshend, A, Dorrell, H, Pearson, M, Morrison, M, and Cole, M. Criterion validity, and interunit and between-day reliability of the FLEX for measuring barbell velocity during commonly used resistance training exercises. J Strength Cond Res 34(6): 1519-1524, 2020-The aim of this study was to assess the criterion validity, interunit reliability (accounting for technological and biological variance), and between-day reliability of a novel optic laser device (FLEX) for quantifying mean concentric velocity. To assess the validity against a three-dimensional motion capture system and interunit reliability with both technological and biological variation, 18 men and women completed repetitions at 20, 40, 60, 80, 90, and 100% of one repetition maximum in the free-weight barbell back squat and bench press. To assess interunit (technological only) reliability, a purpose-built, calibrated rig completed a set protocol with 2 devices. To assess between-day reliability of the technology, the same protocol was repeated 21 days later. Standardized bias, typical error of the estimate (TEE; %), and Pearson's correlation coefficient (r) were used to assess validity, whereas typical error and coefficient of variation (CV%) were calculated for reliability. Overall, TEE (±90 CL) between the FLEX and criterion measure was 0.03 (±0.004) and 0.04 (±0.005) m·s in the back squat and bench press, respectively. For measures of reliability, overall interunit technological variance (CV% [± 90% confidence interval]) was 3.96% (3.83-4.12) but increased to 9.82% (9.31-10.41) and 9.83% (9.17-10.61) in the back squat and bench press, respectively, when biological variance was introduced. Finally, the overall between-day reliability was 3.77% (3.63-3.91). These findings demonstrate that the FLEX provides valid and reliable mean concentric velocity outputs across a range of velocities. Thus, practitioners can confidently implement this device for the monitoring and prescription of resistance training loads.

Published

2020

2. Velocity Loss Thresholds Reliably Control Kinetic and Kinematic Outputs during FreeWeight Resistance Training

Author

Nicholas Dalton-Barron, Amador García-Ramos, Matthew Morrison, Madison Pearson, Jonathon Weakley, and Carlos Ramirez-Lopez

Subjects

Health, Toxicology and Mutagenesis, Coefficient of variation, lcsh:Medicine, Squat, Kinematics, 030204 cardiovascular system & hematology, Concentric, Kinetic energy, Article, 03 medical and health sciences, 0302 clinical medicine, Velocity-based training, Statistics, Humans, Muscle Strength, Exercise, Mathematics, reliability, Training prescription, lcsh:R, Public Health, Environmental and Occupational Health, Resistance training, Relative velocity, training prescription, Reproducibility of Results, 030229 sport sciences, Reliability, Crossover study, Biomechanical Phenomena, Kinetics, resistance training, velocity-based training

Abstract

Exercise velocity and relative velocity loss thresholds (VLTs) are commonly used in velocity-based resistance training. This study aims to quantify the between-day reliability of 10%, 20%, and 30% VLTs on kinetic and kinematic outputs, changes in external load, and repetition characteristics in well-trained athletes. Using a repeated, counter-balanced crossover design, twelve semi-professional athletes completed five sets of the back squat with an external load corresponding to a mean concentric velocity of ~0.70 m&middot, s&minus, 1 and a VLT applied. The testing sessions were repeated after four weeks of unstructured training to assess the long-term reliability of each VLT. A coefficient of variation (CV) &lt, 10% was used to classify outputs as reliable. Kinetic and kinematic outputs and external load were largely reliable, with only peak power during sets 2&ndash, 5 within the 10% VLT condition demonstrating a CV &gt, 10% (CV: 11.14&ndash, 14.92%). Alternatively, the repetitions completed within each set showed large variation (CV: 18.92&ndash, 67.49%). These findings demonstrate that by utilizing VLTs, kinetic and kinematic outputs can be prescribed and replicated across training mesocycles. Thus, for practitioners wishing to reliably control the kinetic and kinematic stimulus that is being applied to their athletes, it is advised that a velocity-based approach is used.

Published

2020