Applications of the Critical Power Model to Dynamic Constant External Resistance Exercise: A Brief Review of the Critical Load Test

• Published in: Sports (Basel) Vol. 9; no. 2; p. 15
• Main Authors: Bergstrom, Haley C., Dinyer, Taylor K., Succi, Pasquale J., Voskuil, Caleb C., Housh, Terry J.
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 21.01.2021; MDPI
• Subjects: Anaerobic threshold; Aviation; critical load; critical power; dynamic constant external resistance exercise; Ergometry; Estimates; Exercise; Exercise intensity; exercise intensity domains; Fatigue; Human performance; Mathematical models; Physiology; Review; Strength training; critical load; exercise intensity domains; fatigue; critical power; dynamic constant external resistance exercise
• ISSN: 2075-4663; 2075-4663
• DOI: 10.3390/sports9020015

The study and application of the critical power (CP) concept has spanned many decades. The CP test provides estimates of two distinct parameters, CP and W′, that describe aerobic and anaerobic metabolic capacities, respectively. Various mathematical models have been used to estimate the CP and W′ parameters across exercise modalities. Recently, the CP model has been applied to dynamic constant external resistance (DCER) exercises. The same hyperbolic relationship that has been established across various continuous, whole-body, dynamic movements has also been demonstrated for upper-, lower-, and whole-body DCER exercises. The asymptote of the load versus repetition relationship is defined as the critical load (CL) and the curvature constant is L′. The CL and L′ can be estimated from the same linear and non-linear mathematical models used to derive the CP. The aims of this review are to (1) provide an overview of the CP concept across continuous, dynamic exercise modalities; (2) describe the recent applications of the model to DCER exercise; (3) demonstrate how the mathematical modeling of DCER exercise can be applied to further our understanding of fatigue and individual performance capabilities; and (4) make initial recommendations regarding the methodology for estimating the parameters of the CL test.