Are biomechanical stability deficits during unplanned single-leg landings related to specific markers of cognitive function?

Florian Giesche; Jan Wilke; Tobias Engeroff; Daniel Niederer; Helena Hohmann; Lutz Vogt; Winfried Banzer

doi:10.1016/j.jsams.2019.09.003

Are biomechanical stability deficits during unplanned single-leg landings related to specific markers of cognitive function?

J Sci Med Sport. 2020 Jan;23(1):82-88. doi: 10.1016/j.jsams.2019.09.003. Epub 2019 Oct 1.

Authors

Florian Giesche¹, Jan Wilke², Tobias Engeroff³, Daniel Niederer², Helena Hohmann², Lutz Vogt², Winfried Banzer³

Affiliations

¹ Division of Preventive and Sports Medicine, Institute of Occupational, Social and Environmental Medicine, Goethe-University Frankfurt, Germany. Electronic address: giesche@sport.uni-frankfurt.de.
² Division of Sports Medicine and Exercise Physiology, Institute of Sports Sciences, Goethe-University Frankfurt, Germany.
³ Division of Preventive and Sports Medicine, Institute of Occupational, Social and Environmental Medicine, Goethe-University Frankfurt, Germany.

PMID: 31628001
DOI: 10.1016/j.jsams.2019.09.003

Abstract

Objectives: Cognitive skills such as working memory or inhibitory control are suggested to have an impact on injury risk during time-constrained athletic movements. Thus, the aim of this study was to gain further insights into the cognitive processes associated with biomechanical stability in unplanned jump-landings.

Design: Cross-sectional.

Methods: Twenty male participants (27±4years) performed 70 counter-movement jumps with single-leg landings on a pressure plate. Equally balanced and in randomized order, these were to be performed either planned (landing leg indicated before take-off) or unplanned (visual cue during flight). Biomechanical stability was estimated from vertical peak ground reaction force (pGRF), time to stabilization (TTS), center of pressure path length (COP), and the number of standing errors (ground touch with free leg). In addition, decision-making was assessed as the amount of landing errors (wrong/both feet) in the unplanned condition. Cognitiive function was measured using computerized as well as pen-and-paper-testing.

Results: Unplanned landings produced higher COP values (p<0.001, d=1.1) and more standing errors (p<0.001, d=0.9) than the pre-planned condition. Decreased postural stability (COP) was related to lower inhibitory control (p=0.036, r=0.48). There was a correlation between the increase in standing errors and better cognitive flexibility/working memory (p=0.037, r=-0.48) and short-term memory (p=0.028, r=0.50). The opposite was found for the unplanned landing errors: poor decision-making was associated with deficits in cognitive flexibility/working memory (p=0.022, r=0.54) and short-term memory (p=0.019, r=-0.55).

Conclusions: Cognitive function may be an important, but under-researched moderator of unplanned jump-landing safety. Further research should elucidate the development of training methods aiming to improve movement-related decision-making and landing stability under time constraints.

Keywords: ACL; Anticipation; COINS; Neurocognition; Non-contact injuries.

Publication types

Observational Study

MeSH terms

Adult
Biomechanical Phenomena*
Cognition*
Cross-Sectional Studies
Decision Making
Humans
Male
Memory, Short-Term
Postural Balance*
Young Adult