Hemodynamic Response to Upright Resistance Exercise: Effect of Load and Repetition

INTRODUCTION/PURPOSEUpright resistance exercise causes large transient fluctuations in blood pressure during and immediately after the performance. We examined the effect of resistance load and the number of repetitions on the middle cerebral artery blood flow velocity (MCAv) response during and aft...

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Bibliographic Details
Published in:Medicine and science in sports and exercise 2014-03, Vol.46 (3), p.479-487
Main Authors: PERRY, BLAKE G, SCHLADER, ZACHARY J, BARNES, MATTHEW J, COCHRANE, DARRYL J, LUCAS, SAMUEL J E, MüNDEL, TOBY
Format: Article
Language:English
Subjects:
Adult
Biological and medical sciences
Blood Flow Velocity - physiology
Cerebrovascular Circulation - physiology
Exercise - physiology
Fundamental and applied biological sciences. Psychology
Human physiology applied to population studies and life conditions. Human ecophysiology
Humans
Male
Medical sciences
Middle Cerebral Artery - physiology
New Zealand
Posture - physiology
Resistance Training - methods
Space life sciences
Vertebrates: body movement. Posture. Locomotion. Flight. Swimming. Physical exercise. Rest. Sports
Weight-Bearing - physiology
Young Adult
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Summary:INTRODUCTION/PURPOSEUpright resistance exercise causes large transient fluctuations in blood pressure during and immediately after the performance. We examined the effect of resistance load and the number of repetitions on the middle cerebral artery blood flow velocity (MCAv) response during and after upright squatting exercise. METHODSHealthy males (n = 12; mean ± SD26 ± 5 yr) completed 30%, 60%, and 90% of their six-repetition maximum load, completing two and six repetitions of these loads during two visits (order randomized). Beat-to-beat MCAv, blood pressure, and continuous end-tidal PCO2 during exercise, at nadir, and during recovery are reported as the change from preexercise standing baseline. RESULTSDuring exercise, MCAvmean increased 31% ± 16% (P < 0.001) across all loads (P = 0.74) and repetitions (P = 0.89), whereas mean arterial pressure (MAP) increased (all P < 0.05) as load and repetitions increased (e.g., 122 ± 9 (two repetitions) vs 135 ± 11 mm Hg (six repetitions) and 128 ± 13 vs 143 ± 14 mm Hg, at 30% and 60%, respectively). Within the six-repetition sets, peak MCAvmean remained unchanged across the set (P = 0.61), whereas MAP increased (P = 0.003). The 90% load produced the lowest MCAvmean nadir (pooled means, −18 ± 6 vs −10 ± 7 cm·s, P < 0.001 vs 30%) and MAP nadir (−34 ± 7 and −43 ± 5 mm Hg, for two and six repetitions, respectively; P < 0.001) after exercise. Postexercise MCAvmean reductions occurred via a selective, load-dependent (P < 0.001) decrease in diastolic MCAv. MCAvmean remained below baseline for the longest period after the 90% six-repetition set (10 s postexercise, P < 0.01) and took the longest to recover (14.8 ± 6.9 s, P = 0.002). CONCLUSIONThese data indicate that higher relative loads produce a greater postexercise hypotension and result in a proportionate reduction in MCAvmean.
ISSN:0195-9131
1530-0315
DOI:10.1249/MSS.0b013e3182a7980f