Hip Muscle Strength Predicts Noncontact Anterior Cruciate Ligament Injury in Male and Female Athletes : a Prospective Study / Khalil Khayambashi, Navid Ghoddosi, Rachel K. Straub, Christopher M. Powers
Material type:
Continuing resourceISSN: 1552-3365Subject(s): anterior cruciate ligament (ACL) injury | noncontact | prospective study | knee injury prevention | hip abduction strength | hip external rotation strength
In:
The American Journal of Sports Medicine -- 2016 v. 44, n. 2 p. 355-361Summary: Background: Prospective studies have reported that abnormal movement patterns at the trunk, hip, and knee are associated
with noncontact anterior cruciate ligament (ACL) injuries. Impaired hip strength may underlie these abnormal movement patterns,
suggesting that diminished hip strength may increase the risk of noncontact ACL injury.
Purpose: To determine whether baseline hip strength predicts future noncontact ACL injury in athletes.
Study Design: Case-control study; Level of evidence, 3.
Methods: Before the start of the competitive season, isometric hip strength (external rotation and abduction) was measured bilaterally by use of a handheld dynamometer in 501 competitive athletes (138 female and 363 male athletes) participating in various
sports. During the sport season, ACL injury status was recorded, and injured athletes were further classified based on the mechanism of injury (noncontact vs contact). After the season, logistic regression was used to determine whether baseline hip strength
predicted future noncontact ACL injury. Receiver operating characteristic (ROC) curves were constructed independently for each
strength measure to determine the clinical cutoff value between a high-risk and low-risk outcome.
Results: A total of 15 noncontact ACL injuries were confirmed (6 females, 9 males), for an overall annual incidence of 3.0% (2.5%
for males, 4.3% for females). Baseline hip strength measures (external rotation and abduction) were significantly lower in injured
athletes compared with noninjured athletes (P = .003 and P \ .001, respectively). Separate logistic regression models indicated
that impaired hip strength increased future injury risk (external rotation: odds ratio [OR] = 1.23 [95% CI, 1.08-1.39], P = .001;
abduction: OR = 1.12 [95% CI, 1.05-1.20], P = .001). Clinical cutoffs to define high risk were established as external rotation
strength 20.3% BW (percentage of body weight) or abduction strength 35.4% BW.
Conclusion: Measures of preseason isometric hip abduction and external rotation strength independently predicted future noncontact ACL injury status in competitive athletes. The study data suggest that screening procedures to assess ACL injury risk
should include an assessment of isometric hip abduction and/or external rotation strength.
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Bibliografía: p.361
Background: Prospective studies have reported that abnormal movement patterns at the trunk, hip, and knee are associated
with noncontact anterior cruciate ligament (ACL) injuries. Impaired hip strength may underlie these abnormal movement patterns,
suggesting that diminished hip strength may increase the risk of noncontact ACL injury.
Purpose: To determine whether baseline hip strength predicts future noncontact ACL injury in athletes.
Study Design: Case-control study; Level of evidence, 3.
Methods: Before the start of the competitive season, isometric hip strength (external rotation and abduction) was measured bilaterally by use of a handheld dynamometer in 501 competitive athletes (138 female and 363 male athletes) participating in various
sports. During the sport season, ACL injury status was recorded, and injured athletes were further classified based on the mechanism of injury (noncontact vs contact). After the season, logistic regression was used to determine whether baseline hip strength
predicted future noncontact ACL injury. Receiver operating characteristic (ROC) curves were constructed independently for each
strength measure to determine the clinical cutoff value between a high-risk and low-risk outcome.
Results: A total of 15 noncontact ACL injuries were confirmed (6 females, 9 males), for an overall annual incidence of 3.0% (2.5%
for males, 4.3% for females). Baseline hip strength measures (external rotation and abduction) were significantly lower in injured
athletes compared with noninjured athletes (P = .003 and P \ .001, respectively). Separate logistic regression models indicated
that impaired hip strength increased future injury risk (external rotation: odds ratio [OR] = 1.23 [95% CI, 1.08-1.39], P = .001;
abduction: OR = 1.12 [95% CI, 1.05-1.20], P = .001). Clinical cutoffs to define high risk were established as external rotation
strength 20.3% BW (percentage of body weight) or abduction strength 35.4% BW.
Conclusion: Measures of preseason isometric hip abduction and external rotation strength independently predicted future noncontact ACL injury status in competitive athletes. The study data suggest that screening procedures to assess ACL injury risk
should include an assessment of isometric hip abduction and/or external rotation strength.
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