Resistance Training Effects on Muscle Morphological, Mechanical and Contractile Properties
NCT ID: NCT04845295
Last Updated: 2021-04-19
Study Results
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Basic Information
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COMPLETED
NA
24 participants
INTERVENTIONAL
2019-03-01
2019-05-07
Brief Summary
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Detailed Description
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The subjects were assigned to two experimental groups, based on the duration of the eccentric muscle contraction in resistance training. All participants were fully informed about experimental procedures and potential risks and they signed written informed consent prior to participation in the study. The training intervention was performed twice per week for a 7-week period. Before training intervention, a 2-week familiarization period was conducted. Elbow flexor and knee extensors muscle dimensions and strength were assessed 2 days before and after training intervention, while contractile properties were evaluated 5 days before and after experiment. The number of repetitions, training volume (number of repetitions x number of series), and TUT were recorded after first session of training intervention for both groups.
Muscle strength was assessed by one-repetition maximum test (1RM) for two exercises: elbow flexion on Scott's bench and parallel barbell squat. Each participant had 5 attempts to lift the maximum weight with pauses between trials of 3 minutes.
Muscles cross-section area (CSA) were evaluated by ultrasonic device (Siemens Antares, Erlangen, Germany), using the 2D ellipse diagnostic method with variable high frequency transducer (from 7 MHz to 13 MHz), for 5 muscles: elbow flexor (biceps brachii) and 4 knee extensors (rectus femoris , vastus intermedius, vastus medialis, vastus lateralis). The measurements were performed while the subjects seated with their elbows and knees extended and relaxed. The biceps brachii CSA was measured at two-thirds of the distance from the acromion to the antecubital crease. CSA of rectus femoris was measured at the height of proximal section of its distal third, above musculoskeletal joint. CSA of vastus intermedius and vastus medialis were measured at the height of distal part right above the patella. The visible part of vastus lateralis was measured at the distal third directly above the patella, under rectus femoris level.
The contractile properties of biceps brachii, rectus femoris and vastus lateralis muscles were evaluated by tensiomyography according to the manufacturer's instructions (TMG-Science for Body Evaluation, Ljubljana, Slovenia). The values of contraction time (Tc) and radial deformation (Dm) were taken for analysis. The biceps brachii testing was performed while subjects were in a sitting position with the dominant arm bent at 90°. During the assessment of the knee extensors subjects were lying on the back, where dominant leg was placed on the support, forming a knee angle of 120°. Subjects were asked to perform a voluntary contraction, in order to mark the point of placement of the TMG sensor by the palpation method. Two self-adhesive electrodes (Pals Platinum, model 895220 with multi-stick gel, AxelGaard Manufacturing Co. Ltd) were placed proximal and distal at 3 cm from the marked point, emitting an electrical impulse. A sensor (GK40, Panoptik d.o.o., Ljubljana, Slovenia) was placed between the electrodes to detect muscle changes initiated by electrical stimulation. The initial impulse was 25 milliamperes (mA) and it increased proportionally by 10 mA, until the maximum (muscle no longer responds to electrical stimulus).
Both experimental groups performed two exercises to target elbow flexor and knee extensor muscles: biceps curl on a Scott bench and parallel barbell squat, respectively. All sessions were performed at the same time (13-15 h), with a minimum 48 h rest between sessions on the same days during the week. For both groups, the intensity of load (1RM%) and number of sets were as follows: in the first three weeks the subjects exercises with ̴ 60% of 1RM in 3 sets, while during the next four weeks the load was set at ̴ 70% of 1RM in 4 sets. The difference in training protocols was in the duration of the eccentric phase, where one group performed training with a tempo of 1 seconds for eccentric and concentric phase, while for other group tempo was 4 seconds for eccentric and 1 seconds for concentric phase. All repetitions were performed until muscular failure. The pause between sets was 2 minutes.
Prior to analysis data were checked for normality and that the relevant assumptions for each test were met. Differences in the training volume and the TUT between the groups were determined by an independent t-test. One-way ANCOVA (using baseline values as covariates) was used to examine differences in changes of CSA, 1RM and TMG parameters between the groups. If ANCOVA showed statistical significance, the bonferroni post-hoc test was used for further estimation of differences between groups. Additionally, using sex as between-group factor and baseline values as covariates, ANCOVA was used to determine possible differences between males and females in changes of morphological, mechanical and contractile variables. Relative changes for each variable was derived from Pre to Post change in percentage, and for each participant. Pearson's correlation coefficient was used to examine the association between relative pre-to-post changes of CSA, 1RM and TMG for tested muscles. Data were reported as mean ± standard deviation. The level of significance was set at p \< 0.05. The program used for statistical analysis was Statistical Package for Social Sciences (IBM SPSS Statistics), version 20.0.
Conditions
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Study Design
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RANDOMIZED
PARALLEL
TREATMENT
DOUBLE
Study Groups
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Fast Tempo
Performed training intervention with a tempo of 1 second for eccentric and 1 second for concentric phase
resistance training
Both experimental groups performed two exercises to target elbow flexor and knee extensor muscles: biceps curl on a Scott bench and parallel barbell squat, respectively. All sessions were performed at the same time (13-15 h), with a minimum 48 h rest between sessions on the same days during the week. For both groups, the intensity of load (1RM%) and number of sets were as follows: in the first three weeks the subjects exercises with ̴ 60% of 1RM in 3 sets, while during the next four weeks the load was set at ̴ 70% of 1RM in 4 sets. All repetitions were performed until muscular failure. The pause between sets was 2 minutes.
Slow Tempo
Performed training intervention with a tempo of 4 seconds for eccentric and 1 second for concentric phase
resistance training
Both experimental groups performed two exercises to target elbow flexor and knee extensor muscles: biceps curl on a Scott bench and parallel barbell squat, respectively. All sessions were performed at the same time (13-15 h), with a minimum 48 h rest between sessions on the same days during the week. For both groups, the intensity of load (1RM%) and number of sets were as follows: in the first three weeks the subjects exercises with ̴ 60% of 1RM in 3 sets, while during the next four weeks the load was set at ̴ 70% of 1RM in 4 sets. All repetitions were performed until muscular failure. The pause between sets was 2 minutes.
Interventions
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resistance training
Both experimental groups performed two exercises to target elbow flexor and knee extensor muscles: biceps curl on a Scott bench and parallel barbell squat, respectively. All sessions were performed at the same time (13-15 h), with a minimum 48 h rest between sessions on the same days during the week. For both groups, the intensity of load (1RM%) and number of sets were as follows: in the first three weeks the subjects exercises with ̴ 60% of 1RM in 3 sets, while during the next four weeks the load was set at ̴ 70% of 1RM in 4 sets. All repetitions were performed until muscular failure. The pause between sets was 2 minutes.
Eligibility Criteria
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Inclusion Criteria
Exclusion Criteria
20 Years
35 Years
ALL
Yes
Sponsors
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University of Belgrade
OTHER
Responsible Party
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Vladimir Ilic
Associate Professor
Principal Investigators
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Vladimir Ilic
Role: PRINCIPAL_INVESTIGATOR
Faculty of Sport and Physical Education, University of Belgrade
Locations
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Faculty of Sport and Physical Education
Belgrade, , Serbia
Countries
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References
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Hackett DA, Davies TB, Orr R, Kuang K, Halaki M. Effect of movement velocity during resistance training on muscle-specific hypertrophy: A systematic review. Eur J Sport Sci. 2018 May;18(4):473-482. doi: 10.1080/17461391.2018.1434563. Epub 2018 Feb 12.
Schoenfeld BJ. The mechanisms of muscle hypertrophy and their application to resistance training. J Strength Cond Res. 2010 Oct;24(10):2857-72. doi: 10.1519/JSC.0b013e3181e840f3.
Davies TB, Kuang K, Orr R, Halaki M, Hackett D. Effect of Movement Velocity During Resistance Training on Dynamic Muscular Strength: A Systematic Review and Meta-Analysis. Sports Med. 2017 Aug;47(8):1603-1617. doi: 10.1007/s40279-017-0676-4.
Pisot R, Narici MV, Simunic B, De Boer M, Seynnes O, Jurdana M, Biolo G, Mekjavic IB. Whole muscle contractile parameters and thickness loss during 35-day bed rest. Eur J Appl Physiol. 2008 Sep;104(2):409-14. doi: 10.1007/s00421-008-0698-6. Epub 2008 Feb 23.
Pryor RR, Sforzo GA, King DL. Optimizing power output by varying repetition tempo. J Strength Cond Res. 2011 Nov;25(11):3029-34. doi: 10.1519/JSC.0b013e31820f50cb.
Kojic F, Mandic D, Ilic V. Resistance training induces similar adaptations of upper and lower-body muscles between sexes. Sci Rep. 2021 Dec 6;11(1):23449. doi: 10.1038/s41598-021-02867-y.
Other Identifiers
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2316/19-2
Identifier Type: -
Identifier Source: org_study_id
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