Effect of Multiple Set on Intramuscular Metabolic Stress During Low-intensity Resistance Exercise with Blood Flow Restriction

Overview

Journal Eur J Appl Physiol

Specialty Physiology

Date 2012 Mar 15

PMID 22415101

Citations 56

Authors

Tadashi Suga

Koichi Okita

Shingo Takada

Masashi Omokawa

Tomoyasu Kadoguchi

Takashi Yokota

Kagami Hirabayashi

Masashige Takahashi

Noriteru Morita

Masahiro Horiuchi

Shintaro Kinugawa

Hiroyuki Tsutsui

Affiliations

Soon will be listed here.

Abstract

Our previous study reported that intramuscular metabolic stress during low-intensity resistance exercise was significantly enhanced by combining blood flow restriction (BFR); however, they did not reach the levels achieved during high-intensity resistance exercise. That study was performed using a single set of exercise; however, usual resistance exercise consists of multiple sets with rest intervals. Therefore, we investigated the intramuscular metabolic stress during multiple-set BFR exercises, and compared the results with those during multiple-set high-intensity resistance exercise. Twelve healthy young subjects performed 3 sets of 1-min unilateral plantar flexion (30 repetitions) with 1-min intervals under 4 different conditions: low intensity (L, 20% 1 RM) and high intensity (H, 65% 1 RM) without BFR, and L with intermittent BFR (IBFR, only during exercise) and with continuous BFR (CBFR, during rest intervals as well as exercise). Intramuscular metabolic stress, defined as intramuscular metabolites and pH, and muscle fiber recruitment were evaluated by 31P-magnetic resonance spectroscopy. The changes of intramuscular metabolites and pH during IBFR were significantly greater than those in L but significantly lower than those in H. By contrast, those changes in CBFR were similar to those in H. Moreover, the fast-twitch fiber recruitment, evaluating by a splitting Pi peak, showed a similar level to H. In conclusion, the multiple sets of low-intensity resistance exercise with continuous BFR could achieve with the same metabolic stress as multiple sets of high-intensity resistance exercise.

Citing Articles

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