A biomechanical model correlating shoulder kinetics to pain in young baseball pitchers

• Published in: Journal of human kinetics Vol. 34; no. 1; pp. 15 - 20
• Main Authors: Keeley, David W., Oliver, Gretchen D., Dougherty, Christopher P.
• Format: Journal Article
• Language: English
• Published: Poland Versita 01.10.2012; Akademia Wychowania Fizycznego w Katowicach
• Subjects: baseball; injury; kinetics; youth; baseball; injury; kinetics; youth
• ISSN: 1640-5544; 1899-7562
• DOI: 10.2478/v10078-012-0059-8

Previous work has postulated that shoulder pain may be associated with increases in both peak shoulder anterior force and peak shoulder proximal force. Unfortunately these relationships have yet to be quantified. Thus, the purpose of this study was to associate these kinetic values with reported shoulder pain in youth baseball pitchers. Nineteen healthy baseball pitchers participated in this study. Segment based reference systems and established calculations were utilized to identify peak shoulder anterior force and peak shoulder proximal force. A medical history questionnaire was utilized to identify shoulder pain. Following collection of these data, the strength of the relationships between both peak shoulder anterior force and peak shoulder proximal force and shoulder pain were analyzed. Although peak anterior force was not significantly correlated to shoulder pain, peak proximal force was. These results lead to the development of a single variable logistic regression model able to accurately predict 84.2% of all cases and 71.4% of shoulder pain cases. This model indicated that for every 1 N increase in peak proximal force, there was a corresponding 4.6% increase in the likelihood of shoulder pain. The magnitude of peak proximal force is both correlated to reported shoulder pain and capable of being used to accurately predict the likelihood of experiencing shoulder pain. It appears that those pitchers exhibiting high magnitudes of peak proximal force are significantly more likely to report experiencing shoulder pain than those who generate lower magnitudes of peak proximal force.