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Humans generally develop a preferred upper and lower extremity. Due to repetitive uneven loading, this gradually results in structural (e.g. increased bone and muscle mass) and functional (e.g. increased strength) adaptations to the dominant side of the body. The corresponding structural and functional asymmetry can be further accentuated by (intensively) practicing a unilateral sport such as tennis, which is very popular. Yet, research on this particular topic is scarce, especially in (pre)adolescent players. Existing studies, which often face methodological shortcomings (e.g. crosssectional designs, small sample sizes, no link to field methods), mainly focus on adults and structural asymmetry of the upper extremity itself, with very little or no attention to whole body structural as well as functional asymmetry. Moreover, the link of both forms of asymmetry with growth and maturation, everyday locomotion, technical skill performance and whole body injury is currently not (fully) understood. Therefore, the main purpose of this research project is to gain comprehensive knowledge on the degree, development and implications of both structural and functional asymmetry during a critical period in life using a longitudinal approach. As such, this project among youth elite tennis players will provide insights on the extent to which structural and/or functional asymmetry is acceptable for being most successful but remaining injury free.
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| Label | Type | Description | Intervention Names |
|---|---|---|---|
| Elite (pre)adolescent tennis players | |||
| Age- and gender-matched controls |
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| Measure | Description | Time Frame |
|---|---|---|
| Anthropometry | Stature (cm) Sitting height (cm) Upper- and lower extremity length (cm) body weight (kg) Body Mass Index (kg/m²) Age at Peak height Velocity (years) Skeletal muscle mass (kg) These values will be determined every two months during a maximum period of three years, expressed as mean and standard deviation and will be used to develop growth charts and velocity curves. | September 2017 - December 2020 |
| Body composition | Dual X-Ray Absorptiometry
Circumferences - upper and lower arm, thigh and calf (in cm) Ultrasound - Muscle thickness ((in mm) of M. Biceps, M. Triceps, M. Rectus Abdominis, Quadriceps and Hamstrings) Bioelectric impedance
These outcome measures will be determined on both the dominant and the non-dominant extremity/side every six months during a maximum period of three years. The side-to-side difference will be calculated using the symmetry index (see outcome measure 4). Every outcome measure described above will be expressed as mean and standard deviation for both the dominant and non-dominant extremity/side | September 2017 - December 2020 |
| Functional test battery | Strength and Power:
Speed and Agility:
Balance and Flexibility:
Motor control and Coordination:
Locomotion pattern: - Ground Reaction Forces (force in N) Every test will be performed unilaterally for both the dominant and non-dominant extremity/side every six months during a maximum period of three years. The side-to-side difference will be calculated using the symmetry index (see outcome measure 4). The mean (plus standard deviation) of every test (dominant and non-dominant test score) will be reported |
| Measure | Description | Time Frame |
|---|---|---|
| Injury incidence | Injury incidence in young elite tennis players (patterns and occurence) will be recorded and reported continuously for a maximum period of three years. | September 2017 - December 2020 |
| Technical tennis skills performance |
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Inclusion Criteria:
Exclusion Criteria:
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Young elite tennis players enrolled in Belgian high-performance tennis academies as well as age- and gender-matched (within two months) controls.
| Name | Role | Phone | Extension | |
|---|---|---|---|---|
| Laurent Chapelle, Msc | Contact | +32477472756 | laurent.chapelle@vub.ac.be |
| Name | Affiliation | Role |
|---|---|---|
| Peter Clarys, PhD | Vrije Universiteit Brussel | Study Director |
| Eva D'Hondt, PhD | Vrije Universiteit Brussel | Study Director |
| Facility | Status | City | State | ZIP | Country | Contacts |
|---|---|---|---|---|---|---|
| Physical Education and Physical Therapy | Brussels | 1050 | Belgium |
Individual Participant Data (IPD) will not be shared or will not be available to other researchers
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| September 2017 - December 2020 |
| Structural and functional asymmetry index | Side-to-side difference (i.e. dominant vs non-dominant extremity/side) will be calculated and expressed as a percentage (extremity symmetry index (%)) for the outcome measures described above (anthropometry, body composition and functional test battery) using following formula: ((measure dominant extremity/measure non-dominant extremity)-1) x 100 | September 2017 - December 2020 |
technical skill of young elite tennis players. - Technical skill performance will be examined by means of video analysis once a year and scored by an independent expert panel. Mean technical ability will be reported.
Tennis specific performance:
- Tennis players will perform the Dutch Technical-Tactical Tennis Test (D4T) once a year. The mean test score will be reported.
| September 2017 - December 2020 |