The aim of this study will be to investigate the recovery kinetics of neuromuscular fatigue, muscle microtrauma indicators, performance and oxidative stress factors after three different exercise induced muscle damage (EIMD) protocols in adult Males. Also, this study will determine the comparison among three different eccentric protocols in neuromuscular fatigue, muscle microtrauma indicators, performance and oxidative stress factors. The eccentric protocols will be differentiated in training volume and specifically in the eccentric repetitions in isokinetic dynamometer.
It is known that eccentric exercise induces muscle microtrauma. Also, eccentric type of exercise are associated with inflammatory response. The leukocytes and the immune cells during the phagocytosis process alter the redox status causing secondary muscle damage to the muscle tissue and also increase oxidative stress concentration. Despite of the existence of studies that examine the muscle damage indicators, inflammatory response, performance and neuromuscular fatigue and oxidative stress concentrations after eccentric exercise, however no studies are detected in order to compare the differences among three eccentric protocols. The eccentric protocols will be differentiated in training volume and specifically in the eccentric repetitions in isokinetic dynamometer. Specifically, a randomized, fourth-trial, cross-over, repeated measures design will be applied. Healthy male adults (age 18-30 years) will participate in the present study. Also, it is considered necessary that the participants will not suffer from any musculoskeletal injuries that will limit their ability to perform the exercise protocols. Also the participants will not be smokers and will not consume alcohol and nutritional supplements. In the first phase all participants will sign an informed consent form after they will be informed about all benefits and risks of this study and they will sign a recent historical of musculoskeletal injury or illness form. Subsequently, fasting blood samples will be collected by venipuncture using a disposable needle (20-gauge) in order to measure muscle damage markers (CK), inflammation markers (WBC) and oxidative stress markers (TBARS, PC, GSH, ΤΑC, CAT, UA). After, delayed onset muscle soreness (DOMS) in the knee flexors (KF) and extensors (KE) of both limbs, body weight (BW), height and body composition (DXA method) will be measured in the lab. Completing the first phase, participants will be instructed by a dietitian how to record a 5 days diet recalls estimating the energy intake during the trials will be the same. The knee range of motion (KJRM) will be determined by the use of a goniometer, 24 hours after (second phase). The counter movement jump (CMJ) will be evaluated on a force platform using two force platforms at 1000 Hz, with each foot in parallel on the two platforms providing a separate yet time-synchronized measurement of the data for each leg. During the CMJ will be measured the jump height (cm), the ground reaction force (N), the peak and mean power (W/kg), the vertical stiffness (Kvert, N/m/kg) and the peak rate of force development (RFD, N/s), while at the same time will be evaluated the change in peak and mean normalized EMG during the eccentric and concentric phases of the counter movement jump, for the vastus medialis (VM) and vastus lateralis muscles. Electromyography data will be collected wirelessly at 2.000 Hz using a Myon MA-320 EMG system. The peak eccentric and concentric isokinetic torque of the knee flexors and extensors, in both limbs will be evaluated on an isokinetic dynamometer at 60°/sec. Also, the isometric peak torque of the knee extensors will be evaluated at 65° in both limbs. Finally, Open-circuit spirometry will be utilized for assessment of maximal oxygen consumption (VO2max) using an automated online pulmonary gas exchange system via breath-by-breath analysis during a graded exercise testing on a treadmill. 96 hours after, the participants are going to perform one of the three eccentric protocols randomly, on an isokinetic dynamometer. The eccentric protocol will be performed on a different limb for each trial. The ECC 75 trial will include 75 eccentric maximum repetitions (5 sets, 15 reps/set and recovery period: 30sec.) at 60°/sec. The ECC 150 trial will include 150 eccentric maximum repetitions (10 sets, 15 reps/set and recovery period: 30sec.) at 60°/sec. The ECC 300 trial will include 300 eccentric maximum repetitions (20 sets, 15 reps/set and recovery period: 30sec.) at 60°/sec. The DOMS indicator in the knee flexors (KF) and extensors (KE) of both limbs and the KJRM will be evaluated immediately after each protocol. Also, the (CMJ) will be evaluated on a force platform using two force platforms at 1000 Hz, with each foot in parallel on the two platforms providing a separate yet time-synchronized measurement of the data for each leg. During the CMJ will be measured the jump height (cm), the ground reaction force (N), the peak and mean power (W/kg), the vertical stiffness (Kvert, N/m/kg) and the peak rate of force development (RFD, N/s), while at the same time will be evaluated the change in peak and mean normalized EMG during the eccentric and concentric phases of the counter movement jump, for the vastus medialis (VM) and vastus lateralis muscles. Electromyography data will be collected wirelessly at 2.000 Hz using a Myon MA-320 EMG system. In addition, the peak eccentric and concentric isokinetic torque of the knee flexors and extensors, in both limbs will be evaluated on an isokinetic dynamometer at 60o/sec. Also, the isometric peak torque of the knee extensors will be evaluated at 65o in both limbs. All the above markers will be evaluated 24, 48 and 192 hours post eccentric protocol, however at these time points, fasting blood samples (20ml) will be collected in order to estimate hematological and biochemical indicators. Α 2 - week washout period will be adapted among trials. After, the participants will perform the process until they complete the trials.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
NONE
Enrollment
10
An acute bout of eccentric exercise will be performed on an isokinetic dynamometer, including 5 sets of 15 repetitions, with 30 sec rest intervals,at 60 degrees/sec.
An acute bout of eccentric exercise will be performed on an isokinetic dynamometer, including 10 sets of 15 repetitions, with 30 sec rest intervals,at 60 degrees/sec.
An acute bout of eccentric exercise will be performed on an isokinetic dynamometer, including 20 sets of 15 repetitions, with 30 sec rest intervals,at 60 degrees/sec.
University o Thessaly, School of Physical Education and Sports Science
Trikala, Greece
Change in white blood cell count
White blood cell count will be measured using an automatic blood analyzer
Time frame: At baseline, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in catalase activity
Concentration of catalase will be measured in red blood cells
Time frame: At baseline, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in uric acid in plasma
concentration of uric acid will be measured in plasma
Time frame: At baseline, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in protein carbonyls in blood
Concentration of protein carbonyls will be measured in red blood cells
Time frame: At baseline, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in total antioxidant capacity
total antioxidant capacity will be measured in serum
Time frame: At baseline, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in reduced glutathione in blood
Concentration of oxidized glutathione will be measured in red blood cells
Time frame: At baseline, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in thiobarbituric acid reactive substances
Thiobarbituric acid will be measured in plasma
Time frame: At baseline, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in Creatine kinase in blood
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Creatine kinase will be measured in plasma
Time frame: At baseline, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in countermovement jump height
Countermovement jump height will be measured using two force platforms at 1000 Hz, with each foot in parallel on the two platforms providing a separate yet time-synchronized measurement of the jump height data for each leg.
Time frame: At baseline, at 1 hour and 24, 48 and 192 hours following the eccentric exercise protocol.
Change in ground reaction force (GRF) during countermovement jump test
The ground reaction force will be measured using two force platforms at 1000 Hz, with each foot in parallel on the two platforms providing a separate yet time-synchronized measurement of the GRF data for each leg.
Time frame: At baseline, at 1 hour and 24, 48 and 192 hours following the eccentric exercise protocol.
Change in peak power during countermovement jump test
The peak power will be measured using two force platforms at 1000 Hz, with each foot in parallel on the two platforms providing a separate yet time-synchronized measurement of the peak power data for each leg.
Time frame: At baseline, at 1 hour and 24, 48 and 192 hours following the eccentric exercise protocol.
Change in mean power during countermovement jump test
The mean power will be measured using two force platforms at 1000 Hz, with each foot in parallel on the two platforms providing a separate yet time-synchronized measurement of the mean power data for each leg.
Time frame: At baseline, at 1 hour and 24, 48 and 192 hours following the eccentric exercise protocol.
Change in vertical stifness during countermovement jump test
The vertical stiffness will be measured using two force platforms at 1000 Hz, with each foot in parallel on the two platforms providing a separate yet time-synchronized measurement of vertical stifness data for each leg.
Time frame: At baseline, at 1 hour and 24, 48 and 192 hours following the eccentric exercise protocol.
Change in peak rate of force develpemnt during countermovement jump test
The Peak rate of force development will be measured using two force platforms at 1000 Hz, with each foot in parallel on the two platforms providing a separate yet time-synchronized measurement of the Peak RFD data for each leg.
Time frame: At baseline, at 1 hour and 24, 48 and 192 hours following the eccentric exercise protocol.
Change in peak normalized EMG during the eccentric and concentric phases of the counter movement jump
Electromyography data will be collected wirelessly at 2.000 Hz using a Myon MA-320 EMG system (Myon AG, Schwarzenberg, Switzerland) for the vastus medialis (VM) and vastus lateralis muscles.
Time frame: At baseline, at 1 hour and 24, 48 and 192 hours following the eccentric exercise protocol.
Change in mean normalized EMG during the eccentric and concentric phases of the counter movement jump
Electromyography data will be collected wirelessly at 2.000 Hz using a Myon MA-320 EMG system (Myon AG, Schwarzenberg, Switzerland) for the vastus medialis (VM) and vastus lateralis muscles.
Time frame: At baseline, at 1 hour and 24, 48 and 192 hours following the eccentric exercise protocol.
Change in knee range of motion
Knee range of motion will be measured by goniometer
Time frame: At baseline, at 1 hour and 24, 48 and 192 hours following the eccentric exercise protocol.
Change in eccentric isokinetic knee extensors peak torque
Eccentric isokinetic knee extensors peak torque will be assessed on an isokinetic dynamometer
Time frame: At baseline, 1 hour, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in concentric isokinetic knee extensors peak torque
Concentric isokinetic knee extensors peak torque will be assessed on an isokinetic dynamometer
Time frame: At baseline, 1 hour, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in eccentric isokinetic knee flexors peak torque
Eccentric isokinetic knee flexors peak torque will be assessed on an isokinetic dynamometer
Time frame: At baseline, 1 hour, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in concentric isokinetic knee flexors peak torque
Concentric Iisokinetic knee flexors peak torque will be assessed on an isokinetic dynamometer
Time frame: At baseline, 1 hour, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in isometric peak torque
The isometric peak torque will be assessed on an isokinetic dyanmometer
Time frame: At baseline, 1 hour, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in fatigue index of isometric torque during 10 second
Fatigue rate during MVIC will be estimated through the percent drop of peak torque between the first and the last three seconds of a 10-secong maximal isometric contraction.
Time frame: At baseline, 1hour, at 24, 48 and 192 hours following the eccentric exercise protocol.
Change in delayed onset of muscle soreness (DOMS) in the knee flexors (KF) and extensors (KE) of both limbs
Muscle soreness (KF and KE) will be assessed during palpation of the muscle belly and the distal region
Time frame: At baseline, 1 hour, at 24, 48 and 192 hours following the eccentric exercise protocol.
Body weight
Body weight will be measured on a beam balance with stadiometer
Time frame: At baseline
Body height
Body height will be measured on a beam balance with stadiometer
Time frame: At baseline
Body fat
Body fat will be measured by using Dual-emission X-ray absorptiometry
Time frame: At baseline
Dietary intake
Dietary intake will be assessed using 5 -day diet recalls
Time frame: Over a 5 -day period at baseline
Maximal oxygen consumption (VO2max)
Maximal oxygen consumption will be measured by open circuit spirometry via breath by breath method
Time frame: At baseline