Changes in isometric force‐ and relaxation‐time, electromyographic and muscle fibre characteristics of human skeletal muscle during strength training and detraining

Häkkinen, Keijo; Alén, Markku; Komi, Paavo V.

doi:10.1111/j.1748-1716.1985.tb07759.x

Cited by 523 publications

(333 citation statements)

References 14 publications

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“…The moderate bivariate correlations between the changes in MVT and agonist EMG in the current study (r = 0.576) were consistent with several previous EMG studies of lower body RT [r = 0.69 (Shima et al 2002); r = 0.74 (Häk-kinen and Komi 1986); r = 0.66 (Häkkinen et al 1985)], but not an elbow flexor RT study (r = 0.187; Erskine et al 2014), which may be significant as the elbow flexors have been found to have a very high level of activation even in the pre-training state (Allen et al 1998;Gandevia et al 1998). In addition, two studies that measured the changes in agonist activation with ITT also found no relationship with individual strength gains after RT (Shima et al 2002;Erskine et al 2010b), although several studies have queried the sensitivity of the ITT to detect changes in activation after RT Harridge et al 1999;Cannon et al 2007;Del Balso and Cafarelli 2007;Tillin et al 2011).…”

Section: Discussionsupporting

confidence: 79%

“…The relationship between the individual changes in strength following training and the putative underpinning neural and morphological adaptations has previously been investigated primarily using bivariate correlations. These studies have reported changes in strength to be both significantly related and unrelated to the changes in neural [significant: agonist electromyography (EMG): r = 0.66-0.74 (Häkkinen et al 1985;Häkkinen and Komi 1986;Shima et al 2002); non-significant: agonist activation assessed with the interpolated twitch technique (ITT): r = −0.124-0.47 (Erskine et al 2010b), antagonist EMG: r = 0.09 (Erskine et al 2010b) or morphological variables [significant: muscle volume assessed via magnetic resonance imaging (MRI): r = 0.48-0.53 (Erskine et al 2014); non-significant: muscle volume assessed via MRI: r = 0.15 (Erskine et al 2010b); muscle fascicle pennation angle (θ p ) assessed via ultrasonography: r = −0.33-0.26 (Nimphius et al 2012)]. Therefore, there is considerable confusion about the contribution of specific physiological variables to the individual changes in strength.…”

Section: Introductionmentioning

confidence: 99%

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Changes in agonist neural drive, hypertrophy and pre-training strength all contribute to the individual strength gains after resistance training

et al. 2017

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(r = 0.461, P = 0.014), and pre-training MVT (r = −0.429, P = 0.023), but not ∆HEMG ANTAG (r = 0.298, P = 0.123) or ∆QUADSθ p (r = −0.207, P = 0.291). Multiple regression analysis revealed 59.9% of the total variance in ∆MVT after RT to be explained by ∆QEMG MVT (30.6%), ∆QUADS VOL (18.7%), and pre-training MVT (10.6%). Conclusions Changes in agonist neural drive, quadriceps muscle volume and pre-training strength combined to explain the majority of the variance in strength changes after knee extensor RT (~60%) and adaptations in agonist neural drive were the most important single predictor during this short-term intervention. Keywords

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Section: Discussionsupporting

confidence: 79%

Section: Introductionmentioning

confidence: 99%

Changes in agonist neural drive, hypertrophy and pre-training strength all contribute to the individual strength gains after resistance training

et al. 2017

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“…Although not specifically measured, this may be caused from a lack of a behavior change to exercise independently after five months training, which supports previous data [17][18][19]. Prior to beginning this exercise program, all participants were living self-declared sedentary lifestyles.…”

Section: Discussionsupporting

confidence: 60%

Effects of Supervised Training Compared to Unsupervised Training on Physical Activity, Muscular Endurance, and Cardiovascular Parameters

Fennell¹,

Kyleneperoutky²,

Glickman³

2016

MOJOR

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Evidence has suggested that among untrained individuals, supervised exercise interventions may elicit greater health benefits and long-term exercise adherence compared to unsupervised exercise interventions.Purpose: This study focused on determining the effectiveness of a five-month supervised exercise intervention compared to a five-week unsupervised duration at a university work-site for faculty and staff members on physical activity behavior, muscular endurance, and cardiovascular health.Methods: An exercise intervention met three times per week for five months to undergo 60 minutes of structured, group exercise led by fitness professionals. This was followed by 5 weeks of independent exercise. Data collected included physical activity behavior via a validated accelerometer, muscular endurance, and cardiovascular health. Results:Repeated measures ANOVA at three time periods were conducted and post-hoc paired samples t-tests to determine where the main effect occurred. The data indicated that participation in a five-month supervised exercise program resulted in improvements of physical activity behavior (p=0.003) and increased muscular endurance via push-ups (p=0.002) and curl-ups (p<0.001). A fiveweek unsupervised program resulted in decreased physical activity behavior, decreased muscular endurance back to baseline levels, and increased resting heart rate (p=0.005). Conclusion:This study suggests that supervised exercise programs for previously sedentary individuals are effective in improving overall fitness. While a period of unsupervised exercise may result in less physical activity and decrease in muscular endurance and cardiovascular health.

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“…The early phase of RFD is thought to be determined mainly by the neural drive to the muscle, as well as the muscle fiber type composition [2,[7][8][9]. Late phase RFD is largely influenced by maximal strength and most likely muscle mass, as suggested by studies reporting parallel changes in maximal muscle strength and contractile RFD 150-250 ms from the onset of contraction [1,2,7,8,[10][11][12][13]. Nevertheless, little is known about the correlation between muscle mass and RFD in power athletes.…”

Section: Introductionmentioning

confidence: 99%

The Importance of Lean Body Mass for the Rate of Force Development in Taekwondo Athletes and Track and Field Throwers

Kavvoura

Zaras

Stasinaki

et al. 2018

JFMK

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Abstract:The rate of force development (RFD) is vital for power athletes. Lean body mass (LBM) is considered to be an essential contributor to RFD, nevertheless high RFD may be achieved by athletes with either high or low LBM. The aim of the study was to describe the relationship between lower-body LBM and RFD, and to compare RFD in taekwondo athletes and track and field (T&F) throwers, the latter having higher LBM when compared to taekwondo athletes. Nine taekwondo athletes and nine T&F throwers were evaluated for countermovement jumping, isometric leg press and leg extension RFD, vastus lateralis (VL), and medial gastrocnemius muscle architecture and body composition. Lower body LBM was correlated with RFD 0-250 ms (r = 0.81, p = 0.016). Taekwondo athletes had lower LBM and jumping power per LBM. RFD was similar between groups at 30-50 ms, but higher for throwers at 80-250 ms. RFD adjusted for VL thickness was higher in taekwondo athletes at 30 ms, but higher in throwers at 200-250 ms. These results suggest that lower body LBM is correlated with RFD in power trained athletes. RFD adjusted for VL thickness might be more relevant to evaluate in power athletes with low LBM, while late RFD might be more relevant to evaluate in athletes with higher LBM.

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Changes in isometric force‐ and relaxation‐time, electromyographic and muscle fibre characteristics of human skeletal muscle during strength training and detraining

Cited by 523 publications

References 14 publications

Changes in agonist neural drive, hypertrophy and pre-training strength all contribute to the individual strength gains after resistance training

Changes in agonist neural drive, hypertrophy and pre-training strength all contribute to the individual strength gains after resistance training

Effects of Supervised Training Compared to Unsupervised Training on Physical Activity, Muscular Endurance, and Cardiovascular Parameters

The Importance of Lean Body Mass for the Rate of Force Development in Taekwondo Athletes and Track and Field Throwers

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