Your search keyword '"Zea G"' showing total 2 results

1. Relationship between serum creatine kinase activity following exercise-induced muscle damage and muscle fibre composition.

Author

Magal M, Dumke CL, Urbiztondo ZG, Cavill MJ, Triplett NT, Quindry JC, McBride JM, and Epstein Y

Subjects

Adult, Anaerobiosis, Biopsy, Humans, Male, Pain blood, Physical Exertion physiology, Physical Fitness physiology, Quadriceps Muscle metabolism, Weight Lifting physiology, Young Adult, Creatine Kinase blood, Exercise physiology, Muscle Fatigue physiology, Muscle Fibers, Fast-Twitch metabolism, Muscle Fibers, Slow-Twitch metabolism, Oxygen Consumption

Abstract

In this study, we examined the relationship between serum creatine kinase activity following exercise-induced muscle damage and muscle fibre composition. Seventeen untrained males volunteered and underwent a .[Vdot]O2max test, Wingate test, and an exercise-induced muscle damage protocol. Muscle soreness and blood samples were recorded before, immediately after, and 24, 48, 72, and 96 h after exercise. Biopsy samples from the vastus lateralis were collected one week after exercise-induced muscle damage and were assessed for muscle fibre composition. There was no significant relationship (P > 0.05) between muscle fibre composition and creatine kinase activity. A significant positive correlation (P < 0.05) was observed between soreness 48 h after exercise and type II and IIb fibres, and a significant negative correlation (P < 0.05) was observed between soreness 48 h after exercise and type I muscle fibres. Significant positive correlations were observed between soreness 48 h after exercise and the fatigue index, relative average power, and relative anaerobic capacity. Our results suggest that creatine kinase activity following exercise-induced muscle damage may not be related to muscle fibre proportions, and higher post-exercise muscular pain may be related to a predominance of type II muscle fibres and higher anaerobic capabilities.

Published

2010

2. Mechanical efficiency during repetitive vertical jumping.

Author

McCaulley, Grant, Cormie, Prue, Cavill, Michael J., Nuzzo, James, Urbiztondo, Zea G., McBride, Jeffrey, McCaulley, Grant O, Nuzzo, James L, and McBride, Jeffrey M

Subjects

MEDICAL care research, BIOENERGETICS, STRETCH reflex, MUSCLES, MALES, LEG physiology, TENDON physiology, SKELETAL muscle physiology, DYNAMICS, ELASTICITY, ELECTROMYOGRAPHY, ENERGY metabolism, ENERGY transfer, EXERCISE, EXERCISE tests, RANGE of motion of joints, KINEMATICS, MUSCLE contraction, MUSCLE strength, RESTRAINT of patients, STRETCH (Physiology), TIME, WORK measurement, BODY movement, OXYGEN consumption

Abstract

The purpose of this study was to compare mechanical efficiency between repeated static jumps (SJ), countermovement jumps (CMJ), drop jumps from 75% of maximum CMJ jump height (75DJ) and drop jumps from 125% of maximum CMJ height (125DJ). Subjects included eight jump-trained males. All subjects completed 30 continuous repetitions in the SJ, CMJ, 75DJ, and 125DJ. Oxygen consumption, peak force and center of mass displacement for each repetition during the four jumping patterns were measured. ME was calculated from a combination of force-time curves, displacement-time curves and lactate-corrected oxygen consumption values. In addition, muscle activity was recorded from the vastus medialis, vastus lateralis and biceps femoris using surface electromyography (EMG). 125DJ and 75DJ resulted in significantly (P < or = 0.05) greater ME in comparison to CMJ and SJ. CMJ resulted in significantly greater ME in comparison to SJ. In addition, braking phase muscle activity was significantly greater in 125DJ and 75DJ in comparison to CMJ. Negative work was significantly different between 125DJ, 75DJ and CMJ (125DJ > 75DJ > CMJ). There was a significant positive correlation (r = 0.68) between ME and negative work performed across 125DJ, 75DJ and CMJ. These findings suggest that stretch-shortening cycle movements, which include a strenuous braking phase combined with simultaneous high muscle activity, increase ME. This may be due to optimal muscle-tendon unit kinetics and usage of stored elastic energy. [ABSTRACT FROM AUTHOR]

Published

2007