The Impact of Exercise in Defined Spaces on Basketball Players’ Lactic Acid Levels and Fatigue Index Development
摘要
Basketball is a high-intensity competitive game that requires the athletes to have anaerobic as well as aerobic fitness, which means that basketball players need to sustain high rates of movement, repeated sprinting efforts, and high-intensity activity over prolonged periods of time. In comparison, the use of endurance and recovery regimes assist in maximizing players’ performance and minimizing fatigue. The purpose of this study was to examine the effects of structured endurance training on lactic acid metabolism, fatigue tolerance, and speed endurance in professional basketball players. Although previous publications primarily focus on broad-based conditioning and recovery methods there is an absence of data specific to the effect of specific basketball-oriented movement exercises, administered purely in training environments on physiological markers, as measured by lactic acidosis and fatigue indexes. To address this issue, a focused six-week endurance training program was developed and applied on professional players, including pre- and post-training assessment using biochemical and performance measures. Methods: The study utilized a quantitative experimental method. The tools used in this study included portable lactate analyzer, RAST (Repeated Anaerobic Sprint Tests) and Sprint endurance tests to observe physiological adaptations. The study found that well-designed endurance training is correlated with considerably lower levels of lactic acid, as well as better fatigue resistance and speed endurance, demonstrating tangible performance gain from sport induction anaerobic conditioning. These results indicate the importance of scientifically validated endurance-periodized workout programs using HIIT, short-burst sprint drills, and corrective/rehabilitative recovery work for basketball performance outputs optimization. What’s more, it provides coaching and testing insight that coaches, trainers and sport scientists will find useful and which reveal conditioning methods designed to maximize the use of energy and duration of peak performance. By filling in the gaps within current literature, the findings of this study add to the domains of sports physiology and training methodologies, providing a structured methodology for maximizing endurance training in the context of competition basketball. Moreover, future works need to investigate individualized training adaptations, innovative sports technologies, or real-time fatigue and load monitoring systems to further improve elite sports endurance conditioning models.