Training-specific functional, neural, and hypertrophic adaptations to explosive- vs. sustained-contraction strength training

TY - JOUR

T1 - Training-specific functional, neural, and hypertrophic adaptations to explosive- vs. sustained-contraction strength training

AU - Balshaw, Thomas G.

AU - Massey, Garry J.

AU - Maden-wilkinson, Thomas M.

AU - Tillin, Neale A.

AU - Folland, Jonathan P.

N1 - This study was supported financially by the Arthritis Research UK Centre for Sport, Exercise, and Osteoarthritis (Grant reference 20194). © 2016, 2016 the American Physiological Society. The attached document (embargoed until 05/04/2017) is an author produced version of a paper uploaded in accordance with the publisher’s self- archiving policy. The final published version (version of record) is available online at http://jap.physiology.org/content/120/11/1364. Some minor differences between this version and the final published version may remain. We suggest you refer to the final published version should you wish to cite from it.

PY - 2016/6/1

Y1 - 2016/6/1

N2 - Training specificity is considered important for strength training, although the functional and underpinning physiological adaptations to different types of training, including brief explosive contractions, are poorly understood. This study compared the effects of 12-wks of explosive-contraction (ECT, n=13) vs. sustained-contraction (SCT, n=16) strength training vs. control (CON, n=14) on the functional, neural, hypertrophic, and intrinsic contractile characteristics of healthy young men. Training involved 40 isometric repetitions (x3/wk): contracting as fast and hard as possible for ~1 s (ECT); or gradually increasing to 75% of maximum voluntary torque (MVT) before holding for 3 s (SCT). Torque and EMG during maximum and explosive contractions, torque during evoked octet contractions, and total quadriceps muscle volume (QUADSVOL) were quantified pre- and post-training. MVT increased more after SCT than EST (23 vs. 17%; effect size [ES]=0.69), with similar increases in neural drive, but greater QUADSVOL changes after SCT (8.1 vs. 2.6%; ES=0.74). ECT improved explosive torque at all time points (17-34%; 0.54≤ES≤0.76) due to increased neural drive (17-28%), whereas only late-phase explosive torque (150 ms, +12%; ES=1.48) and corresponding neural drive (18%) increased after SCT. Changes in evoked torque indicated slowing of the contractile properties of the muscle-tendon unit after both training interventions. These results showed training-specific functional changes that appeared to be due to distinct neural and hypertrophic adaptations. ECT produced a wider range of functional adaptations than SCT, and given the lesser demands of ECT this type of training provides a highly efficient means of increasing function.

AB - Training specificity is considered important for strength training, although the functional and underpinning physiological adaptations to different types of training, including brief explosive contractions, are poorly understood. This study compared the effects of 12-wks of explosive-contraction (ECT, n=13) vs. sustained-contraction (SCT, n=16) strength training vs. control (CON, n=14) on the functional, neural, hypertrophic, and intrinsic contractile characteristics of healthy young men. Training involved 40 isometric repetitions (x3/wk): contracting as fast and hard as possible for ~1 s (ECT); or gradually increasing to 75% of maximum voluntary torque (MVT) before holding for 3 s (SCT). Torque and EMG during maximum and explosive contractions, torque during evoked octet contractions, and total quadriceps muscle volume (QUADSVOL) were quantified pre- and post-training. MVT increased more after SCT than EST (23 vs. 17%; effect size [ES]=0.69), with similar increases in neural drive, but greater QUADSVOL changes after SCT (8.1 vs. 2.6%; ES=0.74). ECT improved explosive torque at all time points (17-34%; 0.54≤ES≤0.76) due to increased neural drive (17-28%), whereas only late-phase explosive torque (150 ms, +12%; ES=1.48) and corresponding neural drive (18%) increased after SCT. Changes in evoked torque indicated slowing of the contractile properties of the muscle-tendon unit after both training interventions. These results showed training-specific functional changes that appeared to be due to distinct neural and hypertrophic adaptations. ECT produced a wider range of functional adaptations than SCT, and given the lesser demands of ECT this type of training provides a highly efficient means of increasing function.

U2 - 10.1152/japplphysiol.00091.2016

DO - 10.1152/japplphysiol.00091.2016

M3 - Article

SN - 8750-7587

VL - 120

SP - 1364

EP - 1373

JO - Journal of Applied Physiology

JF - Journal of Applied Physiology

IS - 11

ER -