Muscular stress is equal when resistance exercise with blood flow restriction is matched in total work volume: A cross‐sectional, cross‐over study

Okita, Koichi; Omokawa, Masashi; Takada, Shingo; Kadoguchi, Tomoyasu; Morita, Noriteru; Yokota, Takashi

doi:10.1111/apha.14097

Cited by 2 publications

References 45 publications

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NMR in living systems

Prior

2024

Nuclear Magnetic Resonance

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This chapter reviews studies published during the period of May 2023 to April 2024 that have applied magnetic resonance spectroscopy to investigate processes occurring in living systems. In Section 1, new hardware, acquisition methods and analytical processes that are applicable to in vivo investigations are presented. Studies in pre-clinical models and the clinical environment are surveyed in Sections 2 and 3, respectively. The review in both these two sections is subdivided into physiological categories, with each of these sub-divided according to the category of disease or the type of metabolic investigation.

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NMR in living systems

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2024

Nuclear Magnetic Resonance

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Differential training benefits and motor unit remodeling in wrist force precision tasks following high and low load blood flow restriction exercises under volume-matched conditions

Lin,

Wong,

Chen

et al. 2024

J NeuroEngineering Rehabil

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Background Blood flow restriction (BFR) resistance training has demonstrated efficacy in promoting strength gains beneficial for rehabilitation. Yet, the distinct functional advantages of BFR strength training using high-load and low-load protocols remain unclear. This study explored the behavioral and neurophysiological mechanisms that explain the differing effects after volume-matched high-load and low-load BFR training. Methods Twenty-eight healthy participants were randomly assigned to the high-load blood flow restriction (BFR-HL, n = 14) and low-load blood flow restriction (BFR-LL, n = 14) groups. They underwent 3 weeks of BFR training for isometric wrist extension at intensities of 25% or 75% of maximal voluntary contraction (MVC) with matched training volume. Pre- and post-tests included MVC and trapezoidal force-tracking tests (0–75%–0% MVC) with multi-channel surface electromyography (EMG) from the extensor digitorum. Results The BFR-HL group exhibited a greater strength gain than that of the BFR-LL group after training (BFR_HL: 26.96 ± 16.33% vs. BFR_LL: 11.16 ± 15.34%)(p = 0.020). However, only the BFR-LL group showed improvement in force steadiness for tracking performance in the post-test (p = 0.004), indicated by a smaller normalized change in force fluctuations compared to the BFR-HL group (p = 0.048). After training, the BFR-HL group activated motor units (MUs) with higher recruitment thresholds (p < 0.001) and longer inter-spike intervals (p = 0.002), contrary to the BFR-LL group, who activated MUs with lower recruitment thresholds (p < 0.001) and shorter inter-spike intervals (p < 0.001) during force-tracking. The discharge variability (p < 0.003) and common drive index (p < 0.002) of MUs were consistently reduced with training for the two groups. Conclusions BFR-HL training led to greater strength gains, while BFR-LL training better improved force precision control due to activation of MUs with lower recruitment thresholds and higher discharge rates.

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Muscular stress is equal when resistance exercise with blood flow restriction is matched in total work volume: A cross‐sectional, cross‐over study

Cited by 2 publications

References 45 publications

NMR in living systems

NMR in living systems

Differential training benefits and motor unit remodeling in wrist force precision tasks following high and low load blood flow restriction exercises under volume-matched conditions

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