Neurocognitive function and musculoskeletal injury risk in sports: a systematic review

Risk factors for sports injuries – a methodological approach.

Br J Sports Med. 37: 384-392Wilke J. Niederer D. Vogt L. et al.

Head coaches' attitudes towards injury prevention and use of related methods in professional basketball: A survey.

Phys Ther Sport. 32: 133-139

Injury prevention strategies at the FIFA 2014 World Cup: perceptions and practices of the physicians from the 32 participating national teams.

Br J Sports Med. 49: 603-608

Injury risk factors, screening tests and preventative strategies: a systematic review of the evidence that underpins the perceptions and practices of 44 football (soccer) teams from various premier leagues.

Br J Sports Med. 49: 583-589Wilke J. Vogel O. Ungricht S.

Can we measure perceptual-cognitive function on the pitch?.

A framework for and reliability of a sports-related testing battery. Phys Ther Sport. 43: 120-126Elferink-Gemser M.T. et al.

Higher-level cognitive functions in Dutch elite and sub-elite table tennis players.

PloS One. 13e0206151

Executive functions.

Ann Rev Psychol. 64: 135-168

E. K. Miller, J.D. Wallis. Executive Function and Higher-Order Cognition: Definition and Neural Substrates In Encyclopedia of Neuroscience (ed. Squire, L.R.) 99-104 (Academic Press, 2009).

R. Sala-Llonch, D. Bartrés-Faz, C. Jungqué. Reorganization of brain networks in aging: a review of functional connectivity studies. Front Psychol, doi: https://doi.org/10.3389/fpsyg.2015.00663 (2015)

Neuroscience application to non-contact anterior cruciate ligament injury prevention.

Sports Health. 8: 149-152

A prospective video-based analysis of injury situations in elite male football: football incident analysis.

Am J Sports Med. 32: 1459-1465

Video analysis of mechanisms for ankle injuries in football.

Am J Sports Med. 32: 69-79

Injury mechanisms for anterior cruciate ligament injuries in team handball: a systematic video analysis.

Am J Sports Med. 32: 1002-1012

Musculoskeletal injury risk after sport-related concussion: a systematic review and meta-analysis.

Am J Sports Med. 47: 1754-1762

Preferred reporting items for systematic reviews and meta-analyses: the PRISMA statement.

BMJ. 339: b2535

Ethical issues in preparing and publishing systematic reviews.

J Evid Med. 4: 130-134

Acute effects of resistance exercise on cognitive function in healthy adults: a systematic review with multilevel meta-analysis.

Sports Med. 49: 905-916Horsley T. Dingwall O. Sampson M.

Checking reference lists to find additional studies for systematic reviews.

Cochrane Database Syst Rev. 73: 505Scherer R.W. Saldanha I.J.

How should systematic reviewers handle conference abstracts?.

A view from the trenches, Syst Revhttps://doi.org/10.1186/s13643-019-1188-0

The feasibility of creating a checklist for the assessment of the methodological quality both of randomised and non-randomised studies of health care interventions.

J Epidemiol Health. 52: 377-384

S. Taimela, L. et al. Motor ability and personality with reference to soccer injuries. J Sports Med Phys Fit, 30 (1990), pp. 194-201.

J. Dvorak et al. Risk factor analysis for injuries in football players. Possibilities for a prevention program. Am J Sports Med, 28 (2000), pp. 69-74).

Neurocognitive reaction time predicts lower extremity sprains and strains.

Int J Athl Ther Train. 17: 4-9

Utilization of ImPACT testing to measure injury risk in alpine ski and snow-board athletes.

Int J Sports Phys Ther. 11: 498-506Wilkerson G.B. Simpson K.A. Clark R.A.

Assessment and training of visuomotor reaction time for football injury prevention.

J Sport Rehabil. 26: 26-34

S. Ha, et al. Can neurocognitive function predict lower extremity injuries in male collegiate athletes? Int J Environment Res Pub Health, 17 (2020), doi: https://doi.org/10.3390/ijerph17239061 (2020).

Risk factors and subsequent core or lower extremity sprain or strain among collegiate football players.

J Athl Train. 54: 489-496

The relationship between neurocognitive function and noncontact anterior cruciate ligament injuries.

Am J Sports Med. 35: 943-948Eyerly D. Herman D. Tripp B.

Brains and sprains: the relationship between neurocognitive performance and musculoskeletal injury risk in high school athletes.

Pediatr. 146: 69-70

J. Wilke, et al. Perceptual-cognitive function and unplanned athletic movement task performance: a systematic review. Int J Environment Res Pub Health, (2020), doi: https://doi.org/10.3390/ijerph17207481.

Drop-jump landing varies with baseline neurocognition: Implications for anterior cruciate ligament injury risk and prevention.

Am J Sports Med. 44: 2347-2353Shibata S. Takemura M. Miyakawa R.

The influence of differences in neurocognitive function on lower limb kinematics, kinetics, and muscle activity during an unanticipated cutting motion.

Phys Res. 21: 44-52

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

J Sci Med Sport. 23: 82-88

T.G. Almonroeder. Cognitive Contributions to Anterior Cruciate Ligament Injury Risk. PhD Thesis, University of Wisconsin-Milwaukee (2017).

Does Brain Functional Connectivity Contribute to Musculoskeletal Injury?.

A Preliminary Prospective Analysis of a Neural Biomarker of ACL Injury Risk. J Sci Med Sport. 22: 169-174

B.C. Huijgen, et al. Cognitive functions in elite and sub-elite youth soccer players aged 13 to 17 years. PLoS ONE, (2015), doi: https://doi.org/10.1371/journal.pone.0144580

Response training shortens visuo-motor related time in athletes.

Int J Sports Med. 32: 586-590

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