Int J Sports Med 2013; 34(12): 1093-1098
DOI: 10.1055/s-0033-1337949
Training & Testing
© Georg Thieme Verlag KG Stuttgart · New York

Effects of Slackline Training on Balance, Jump Performance & Muscle Activity in Young Children

L. Donath
1   Institute of Exercise and Health Sciences, University of Basel, Switzerland
,
R. Roth
1   Institute of Exercise and Health Sciences, University of Basel, Switzerland
,
A. Rueegge
1   Institute of Exercise and Health Sciences, University of Basel, Switzerland
,
M. Groppa
1   Institute of Exercise and Health Sciences, University of Basel, Switzerland
,
L. Zahner
1   Institute of Exercise and Health Sciences, University of Basel, Switzerland
,
O. Faude
1   Institute of Exercise and Health Sciences, University of Basel, Switzerland
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Publikationsverlauf



accepted after revision 08. Februar 2013

Publikationsdatum:
22. Mai 2013 (online)

Abstract

The study investigated the effects of slackline training (rope balancing) on balance, jump performance and muscle activity in children. Two primary-school classes (intervention, n=21, INT: age: 10.1 (SD 0.4) y, weight: 33.1 (4.5) kg; control, n=13, CON: age: 10.0 (SD 0.4) y, weight: 34.7 (7.4) kg) participated. Training was performed within 6 weeks, 5 times per week for 10 min each day. Balance (static and dynamic stance), countermovement jumps, reverse balancing on beams (3, 4.5 and 6 cm width), slackline standing (single- and double-limb) and electromyographic activity (soleus, gastrocnemius, tibialis anterior) were examined. INT significantly improved single- and double-limb slackline standing (double limb: 5.1 (3.4) s–17.2 (14.4) s; right leg: 8.2 (5.8) s–38.3 (36.0) s; left leg: 10.6 (5.8) s–49.0 (56.3) s; p<0.001; 0.17<ηp²<0.22). Reduced left-leg dynamic sway (−20.8%, p=0.06, ηp²=0.10), improved 4.5 cm balancing (+18.5%, p=0.08, ηp²=0.10) and decreased muscle activity during slackline standing for the mm. soleus (−23%, p=0.10, ηp²=0.18) and tibialis anterior (−26%, p=0.15, ηp²=0.14) was observed for INT. Jump performance remained unchanged (p=0.28, ηp²=0.04). In conclusion, daily slackline training results in large slackline-specific balance improvements. Transfer effects to static and dynamic stance, reverse balancing or jumping performance seemed to be restricted.

 
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