Athletic Performance Clinical Trial
— KOMO-BONEOfficial title:
The KOMOtini BONE Study: Evaluation of Sports-Related Osteogenic Potential in School-Aged Children
Verified date | June 2017 |
Source | University of Thessaly |
Contact | n/a |
Is FDA regulated | No |
Health authority | |
Study type | Interventional |
Bone mass develops throughout childhood and adolescence until a peak bone mass is achieved during early adulthood. Fracture risk later in life can be predicted at a large extent by peak bone mass. Occurence of sarcopenia and osteoporosis (i.e. loss of mone mass) during late adulthood has been strongly associated with the degree of bone mineralization during early life. Nearly 50% of total bone mineral content (BMC) reached during adulthood is obtained during pre-adolescence rendering this period critical for skeletal health and is considered as an optimal period for bone/skeletal growth since during this time bones are more adaptable to osteogenic stimuli such as exercise-induced mechanical loading. Organized sport activities and/or nutrition appear to affect profoundly bone mineral density (BMD), BMC, bone geometry, and overall skeletal health during preadolescence offering an effective type of prevention of osteoporosis, a condition very difficult to treat later in life. Evidence suggest that some modes of exercise activities may be more effective (osteogenic) for bone development due to the magnitude and type of mechanical strain placed on long bones causing them to be more dense. Weight-bearing activities (e.g. running, jumping etc.) are believed to be more osteogenic than non-weight bearing activities. However, more research is required in order to determine: i) whether weight-bearing activities are more osteogenic than non weight -bearing activities during childhood and ii) the osteogenic potential of a large number of sport activities used by school-children as compared to a control treatment of no participation in organized sport activities. The present trial attempted to compare a large number of different sport activities in respect to their osteogenic potential based on training variables that are thought to affect osteogenesis while at the same time allows direct comparison of exercise modes that are entirely different. Therefore, the goal of this investigation was to determine the osteogenic potential of a large number of exercise training activities in boys and girls of 8-12 years of age during an entire primary school season.
Status | Active, not recruiting |
Enrollment | 335 |
Est. completion date | December 2017 |
Est. primary completion date | June 2014 |
Accepts healthy volunteers | Accepts Healthy Volunteers |
Gender | All |
Age group | 8 Years to 12 Years |
Eligibility |
Inclusion criteria - were 8-12 years and pre-pubertal - were healthy and had no prior bone fractures or related surgical operation - had not been involved in organized sport activities previously - their body fat was <30%, e) had no history of growth irregularities - were not receiving agents or drugs that affect bone tissue (e.g. Gonadotropin-Releasing Hormone (GnRH) agonists, antiresorptive, bisphosphonates, etc.) Exclusion Criteria: - had prior bone fractures or related surgical operation - had been involved in organized sport activities previously - their body fat was >30% - had history of growth irregularities - were receiving agents or drugs that affect bone tissue (e.g. GnRH agonists, antiresorptive, bisphosphonates, etc.) - missed more than 10% of training sessions |
Country | Name | City | State |
---|---|---|---|
Greece | Laboratory of Physical Education and Sports, Democritus University of Thrace, School of Physical Education & Sports Sciences | Komotini |
Lead Sponsor | Collaborator |
---|---|
Ioannis G. Fatouros | Democritus University of Thrace |
Greece,
Type | Measure | Description | Time frame | Safety issue |
---|---|---|---|---|
Primary | Changes in bone mineral content | Using a whole body, hip (left and right), lumbar spine, and wrist (left and right) scans performed by a dual-energy x-ray absorptiometry scanner. | At baseline and 9 months. | |
Primary | Changes in bone density | Using a whole body, hip (left and right), lumbar spine, and wrist (left and right) scans performed by a dual-energy x-ray absorptiometry scanner. | At baseline and 9 months. | |
Primary | Changes in area of different regions and sub-regions | Using a whole body, hip (left and right), lumbar spine, and wrist (left and right) scans performed by a dual-energy x-ray absorptiometry scanner. | At baseline and 9 months. | |
Primary | Changes in bone resorption | By measuring blood levels of sclerostin, calcium, phosphorus, magnesium, creatinine, alkaline phosphatase (ALP), vitamin D (if budget allows), serum procollagen type 1 aminoterminal propeptide (P1NP, if budget allows) and isomer of the Carboxy-terminal telopeptide of type 1 collagen (CTX-1, if budget allows). | At baseline and 9 months. | |
Primary | Changes in cardiorespiratory performance | Using a shuttle run test | At baseline and 9 months. | |
Primary | Changes in muscle power performance of the lower limbs | Using long jump test, standing long jump test, countermovement jump test and the Abalakov jump. | At baseline and 9 months. | |
Primary | Changes in flexibility performance | Using the sit and reach test | At baseline and 9 months. | |
Primary | Changes in muscle strength | Using handgrip dynamometry (left and right arm) | At baseline and immediately after the completion of training. | |
Primary | Changes in motor performance | Using a standard motor ability test battery | At baseline and 9 months. | |
Primary | Changes in stature (cm) | At baseline and 9 months. | ||
Primary | Changes in seated height (cm) | At baseline and 9 months. | ||
Primary | Changes in body mass (kg) | At baseline and 9 months. | ||
Primary | Changes in body mass index (BMI) | Calculated as body mass (kg) divided by the height (m) squared. | At baseline and 9 months. | |
Primary | Changes in arm span | At baseline and 9 months. | ||
Primary | Changes in tibia length | At baseline and 9 months. | ||
Primary | Changes in biacromial length | At baseline and 9 months. | ||
Primary | Changes in chest width | At baseline and 9 months. | ||
Primary | Changes in waist circumference | At baseline and 9 months. | ||
Primary | Changes in hip circumference | At baseline and 9 months. | ||
Primary | Changes in forearm length | At baseline and 9 months. | ||
Primary | Changes in hand length | At baseline and 9 months. | ||
Primary | Changes in body fat mass | Body composition was measured using a dual-energy x-ray absorptiometry scanner (DEXA). DEXA instrumentation allowed the measurement of regional (legs, arms, trunk) weight, body fat (%), and fat mass (kg). | At baseline and 9 months. | |
Primary | Changes in lean body mass | Body composition was measured using a dual-energy x-ray absorptiometry scanner (DEXA). DEXA instrumentation allowed the measurement of regional (legs, arms) weight, lean mass (kg). | At baseline and 9 months. | |
Secondary | Changes in sexual maturation | Sexual maturation was assessed using the Tanner scale with stages of sexual maturation, orchidometer for boys. Potentially sexual maturation will be assessed also using measurement of hormonal concentration in the blood (if budget allows). | At baseline and 9 months. | |
Secondary | Changes in diet intake | Food intake was measured using diet recalls. Participants and their parents were instructed how to record the type and the quantity of solid and liquid foods consumed daily. Daily caloric intake as well daily intake of all nutrients was estimated using a nutritional software. | At baseline, after 4,5 months of training and after 9 months of training. | |
Secondary | Changes in habitual physical activity | Daily habitual physical activity was measured using an accelerometer. | At baseline, after 4,5 months of training and after 9 months of training. | |
Secondary | Changes in training intensity | Training intensity was measured in two consecutive training sessions for each sport activity at three time points during the intervention. Training intensity was assessed using the following: a) heart rate responses using heart rate monitors, b) accelerometry (except for swimming), c) GPS instrumentation (global positioning system) for outdoor activities only. | At baseline, after 4,5 months of training and after 9 months of training. | |
Secondary | Changes in training volume | Training volume was measured in two consecutive training sessions for each sport activity at three time points during the intervention. Training volume was measured using the following: a) total distance covered using GPS instrumentation and accelerometry for outdoor activities, b) accelerometry for indoor activities, c) recording of total meters covered during a session for swimming and d) total vertical jump number. | At baseline, after 4,5 months of training and after 9 months of training. |
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