Background Sustainable athletic performance requires maintaining motor intent stability under physiological stress. Current injury prediction approaches focus on isolated biomechanical markers rather than integrated physiological system dynamics. Objective To develop and validate through comprehensive simulation the Wesam Al Attar Singularity evaluation-infinity (WASe-∞) framework for predicting motor intent collapse by integrating neuromuscular, cognitive, and coordination factors into a unified risk assessment model with clear pathways for empirical validation. Methods A rigorous simulation-based approach was employed using parameters derived from published biomechanics datasets. The WASe-∞ framework integrates five physiological domains through a weighted convergence equation with coefficients derived through systematic three-stage optimization including comprehensive sensitivity analysis. The foundational model was validated using 60 simulated athlete profiles across four sports over 60-minute sessions, generating 360,000 data points for analysis with built-in AI integration capabilities. Results The WASe-∞ framework achieved strong predictive performance within the controlled simulation environment with an area under the curve of 0.930 and 95% confidence interval of 0.915–0.946. Risk stratification revealed realistic distributions: 20.5% low-risk, 58.2% moderate-risk, 20.0% high-risk, and 1.4% critical-risk measurements. Sport-specific differences emerged with swimming showing highest mean scores (0.727 ± 0.210) and running lowest (0.605 ± 0.178), consistent with epidemiological data indicating elevated shoulder injury risk in competitive swimmers (40%–70% prevalence). Strong factor correlations supported theoretical foundations with comprehensive sensitivity analysis confirming framework robustness (AUC remained 0.90 for coefficient variations up to ±15%). Conclusion This foundational study establishes the WASe-∞ framework as a theoretically robust foundation for future empirical validation with human athletic populations. The simulation-based validation demonstrates strong theoretical validity while providing clear performance benchmarks and detailed protocols for subsequent real-world validation studies. The framework's architecture positions it for integration with emerging multimodal sensor technologies, representing a critical step toward transforming injury prevention from reactive treatment to proactive risk management.
Wesam Saleh A. Al Attar (Tue,) studied this question.