Your search keyword '"COCHRANE-SNYMAN, KRISTEN C."' showing total 3 results

1. Inter-individual variability in the patterns of responses for electromyography and mechanomyography during cycle ergometry using an RPE-clamp model

Author

Cochrane-Snyman, Kristen C., Housh, Terry J., Smith, Cory M., Hill, Ethan C., Jenkins, Nathaniel D. M., Schmidt, Richard J., and Johnson, Glen O.

Published

2016

2. Time course of changes in neuromuscular responses during rides to exhaustion above and below critical power

Author

Dinyer, Taylor K., Byrd, M. Travis, Cochrane-Snyman, Kristen C., Jenkins, Nathaniel D.M., Housh, Terry J., Schmidt, Richard J., Johnson, Glen O., and Bergstrom, Haley C.

Subjects

Male, Cycle Ergometry, Exercise Tolerance, Onion Skin Scheme, Electromyography, Electrophysiology, Young Adult, Muscular Wisdom, Muscle Fatigue, Exercise Test, Humans, Original Article, Female, Muscle, Skeletal, Mechanomyography, Muscle Contraction

Abstract

Objectives: To examine the time course of changes in electromyographic (EMG) and mechanomyographic (MMG) amplitude (AMP) and mean power frequency (MPF) responses during cycle ergometry to exhaustion performed above (CP+10%) and below (CP-10%) critical power (CP) to infer motor unit activation strategies used to maintain power output. Methods: Participants performed a 3-min all out test to determine CP, and 2 randomly ordered, continuous rides to exhaustion at CP+10% and CP-10%. V̇O2, EMG AMP, EMG MPF, MMG AMP, MMG MPF, and time to exhaustion (Tlim) were recorded. Responses at CP-10% and CP+10% were analyzed separately. Results: At CP-10%, EMG and MMG AMP were significantly greater than the initial 5% timepoint at 100% Tlim. EMG MPF and MMG MPF reflected a downward trend that resulted in no significant difference between timepoints. At CP+10%, EMG AMP was significantly greater than the initial 5% timepoint from 60% to 100% Tlim. MMG AMP was less than the initial 5% timepoint at only 50% Tlim. EMG and MMG MPF were significantly less than the initial 5% timepoint at 20% Tlim and 100% Tlim, respectively. Conclusions: The time-course of changes in EMG and MMG signals were different at CP-10% and CP+10%, but responses observed indicated cycle ergometry to exhaustion relies on similar motor unit activation strategies.

Published

2019

3. Mechanomyographic Amplitude Is Sensitive to Load-Dependent Neuromuscular Adaptations in Response to Resistance Training.

Author

Jenkins, Nathaniel D.M., Miramonti, Amelia A., Hill, Ethan C., Smith, Cory M., Cochrane-Snyman, Kristen C., Housh, Terry J., and Cramer, Joel T.

Subjects

SKELETAL muscle physiology, RESISTANCE training, ISOMETRIC exercise, MOTOR unit, NEUROPHYSIOLOGY, RANGE of motion of joints, MUSCLE contraction, NEUROMUSCULAR system, EXERCISE physiology, MUSCLE strength testing, PHYSIOLOGICAL adaptation, RANDOMIZED controlled trials, LEG, DESCRIPTIVE statistics, BIOMECHANICS, ELECTROMYOGRAPHY, STATISTICAL sampling

Abstract

Jenkins, NDM, Miramonti, AA, Hill, EC, Smith, CM, Cochrane-Snyman, KC, Housh, TJ, and Cramer, JT. Mechanomyographic amplitude is sensitive to load-dependent neuromuscular adaptations in response to resistance training. J Strength Cond Res 35(11): 3265–3269, 2021—We examined the sensitivity of the mechanomyographic amplitude (MMGRMS) and frequency (MMGMPF) vs. torque relationships to load-dependent neuromuscular adaptations in response to 6 weeks of higher- vs. lower-load resistance training. Twenty-five men (age = 22.8 ± 4.6 years) were randomly assigned to either a high- (n = 13) or low-load (n = 12) training group and completed 6 weeks of leg extension resistance training at 80 or 30% 1RM. Before and after 3 and 6 weeks of training, mechanomyography signals were recorded during isometric contractions at target torques equal to 10–100% of the subjects' baseline maximal strength to quantify MMGRMS and MMGMPF vs. torque relationships. MMGRMS decreased from Baseline to weeks 3 and 6 in the high-load, but not low-load group, and was dependent on the muscle and intensity of contraction examined. Consequently, MMGRMS was generally lower in the high- than low-load group at weeks 3 and 6, and these differences were most apparent in the vastus lateralis (VL) and rectus femoris muscles at higher contraction intensities. MMGMPF was greater in the high- than low-load training group independent of time or muscle. The MMGRMS vs. torque relationship was sensitive to load-dependent, muscle-specific neuromuscular adaptations and suggest reductions in neuromuscular activation to produce the same absolute submaximal torques after training with high, but not low loads. [ABSTRACT FROM AUTHOR]

Published

2021