Elite Athletes: Trunk Mobility, Lower Extremity Flexibility, and Functional Balance Across Sports

Patellofemoral pain syndrome (PFPS) is a common overuse condition in adolescent athletes and is associated with pain, performance limitations, and reduced participation in sports activities. Increasing evidence suggests that PFPS is not limited to local knee pathology, but is influenced by proximal neuromuscular control, dynamic alignment, and soft-tissue flexibility. The dynamic Q angle, which reflects frontal-plane knee alignment during functional tasks, has been proposed as a clinically meaningful indicator of patellofemoral loading; however, the interaction between dynamic alignment, core endurance, and flexibility parameters in adolescent elite athletes remains insufficiently explored.

This cross-sectional observational study was conducted to examine the relationships among dynamic Q angle, core muscle endurance, hip and lower extremity flexibility, and functional status in elite adolescent athletes with and without PFPS. A total of 75 track-and-field athletes aged 15-18 years were included. Participants were allocated into two groups: athletes diagnosed with PFPS and healthy controls. Dynamic Q angle was assessed using digital two-dimensional video analysis of the step-down test. Core endurance was evaluated using the McGill endurance test battery (flexor, extensor, and lateral plank tests). Flexibility was assessed using the Straight Leg Raise, Modified Thomas, and Ober tests. Functional status was measured with the Lower Extremity Functional Scale (LEFS). All side-dependent measurements were analyzed on the index limb (symptomatic side in the PFPS group and matched limb in controls).

Group differences and correlations among variables were examined, and multiple regression analyses were performed to identify predictors of the dynamic Q angle. The results demonstrated that athletes with PFPS exhibited a significantly higher dynamic Q angle, reduced core extension and lateral endurance, decreased hip flexor and iliotibial band flexibility, and lower functional scores compared with controls. In the PFPS group, hip flexor tightness and functional capacity were significant predictors of the dynamic Q angle, explaining a substantial proportion of its variance.

These findings indicate that PFPS in adolescent athletes represents a multidimensional biomechanical syndrome characterized by the interaction of proximal stability, flexibility restrictions, and dynamic alignment alterations. The study highlights the clinical importance of comprehensive assessment strategies that incorporate core endurance, hip flexibility, and functional performance measures, rather than focusing solely on isolated knee-level factors. The results may contribute to the development of targeted prevention and rehabilitation strategies for adolescent athletes at risk of PFPS.