This study aims at investigating the metabolic cost of several fundamental exercises with Kettlebell. Kettlebell training has become a popular training modality that is efficiently used to improve cardiovascular status and physical performance. Despite its widespread use and popularity the metabolic cost of exercises using kettlebell remains to be elucidated. Therefore, the metabolic cost of various fundamental exercise with kettlebell will be determined to aid the planning of exercise training programs.
Ten healthy young adults will be assigned to this study. Participants will initially undergo a baseline assessment of their anthropometrics, body composition (by DXA), resting metabolic rate (RMR), cardiorespiratory fitness (VO2max), muscular strength \[maximal strength (1RM) and muscular endurance\] and functional capacity. After baseline screening, participants will execute in different days (one exercise per day) one set of each of the following 7 exercises: (1) plank with kettlebell pass, (2) swings, (3) overhead squat-thrusters, (4) lunges with motion hands, (5) single leg deadlift, (6) wood chop και (7) snatch, in two different conditions: (i) 30 sec and (ii) 45 sec exercise duration, in a random order. Prior to each exercise resting heart rate, blood lactate concentration, oxygen consumption and rate of perceived exertion will be recorded. Heart rate and oxygen consumption (through portable gas analyzer) will be continuously monitored during the exercise and after the end of it, until the oxygen consumption reach the pre-exercise values (excess post-exercise oxygen consumption). Blood lactate and rate of perceived exertion will be reassessed post-exercise.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
SCREENING
Masking
NONE
Enrollment
10
Both arms include an exercise intervention consisted of 7 different exercises with kettlebell: (1) plank with kettlebell pass, (2) swings, (3) overhead squat-thrusters, (4) lunges with motion hands, (5) single leg deadlift, (6) wood chop και (7) snatch
Laboratory of Exercise Physiology, Exercise Biochemistry and Sports Nutrition, Department of Physical Education and Sport Science, University of Thessaly
Trikala, Karyes, Greece
Change in exercise energy expenditure
Total energy expenditure (kcals) during the exercise will be assessed by summing the kcals of the oxidative system, the glycolytic system and the excess post-exercise oxygen consumption.
Time frame: At pre-exercise, during and up to 15 minutes after the exercise (a single set lasting 30 or 45 seconds)
Change in aerobic energy expenditure
The contribution of oxidative system in exercise energy expenditure will be assessed by the change in oxygen consumption during the exercise using a portable gas analyzer.
Time frame: At pre-exercise and during the exercise (a single set lasting 30 or 45 seconds)
Change in anaerobic energy expenditure
The contribution of glycolytic system to exercise energy expenditure will be assessed by the change in blood lactate concentration after the exercise
Time frame: At pre-exercise and post-exercise (a single set lasting 30 or 45 seconds)
Change in recovery energy expenditure
The contribution of excess post-exercise oxygen consumption in exercise energy expenditure will be assessed by the change in oxygen consumption after the exercise using a portable gas analyzer
Time frame: At pre-exercise and up to 15 minutes after the exercise (a single set lasting 30 or 45 seconds)
Change in blood lactate concentration
Blood lactate concentration will be assessed using a portable analyzer
Time frame: At pre-exercise and 4 minutes after the exercise session
Change in heart rate
Heart rate will be continuously monitored using a wearable heart rate monitor
This platform is for informational purposes only and does not constitute medical advice. Always consult a qualified healthcare professional.
Time frame: At pre-exercise, during and up to 15 minutes after the exercise session.
Change in rate of perceived exertion
Rate of perceived exertion will be assessed using the Borg scale (0-10)
Time frame: At pre-exercise and post-exercise session.
Change in respiratory exchange ratio
Respiratory exchange ratio will be assessed using a portable gas analyzer
Time frame: At pre-exercise, during and up to 15 minutes after the exercise session.