Proceedings of the International scientific and practical conference “Science in the Modern World” (January 19-21, 2026) / Publisher website: www.naukainfo.com. - Cambridge, United Kingdom, 2026. - 203 p.

178 space, increases. The effectiveness of turn stabilization is largely determined by the ability of the central nervous system to integrate these signals and generate adequate motor responses under conditions of sensory uncertainty [10]. An important factor in the stability of rotational elements is the spatiotemporal organization of movement, in particular the rhythmicity and phase coordination of the actions of body segments. Disruption of temporal synchronization between the movements of the trunk, the free leg, and the upper limbs can lead to an asymmetrical distribution of inertial forces, which negatively affects the stability of the axis of rotation. In this context, the precision of the rhythmic structure of movement acts not only as an aesthetic but also as a biomechanical factor that ensures the uniform progression of the rotational process. An equally significant aspect is the individual variability of postural strategies among gymnasts of different levels of preparedness. Even under identical external conditions of turn execution, athletes may demonstrate different stabilization strategies, which manifest in differences in muscle activation, the nature of compensatory movements, and the choice of support strategy. Such individualization of motor solutions indicates the adaptive nature of postural control and emphasizes the need for a personalized approach to the analysis of rotational element technique. In the context of the training process, turn stability should be considered not only as a result of automated motor skills but also as an indicator of the functional readiness of the neuromuscular system. Increased training load, fatigue, or emotional stress may affect the effectiveness of postural regulation by increasing the amplitude of oscillations and reducing the accuracy of performing rotational elements. This indicates the appropriateness of using stability indicators as markers of the athlete’s current state and as a means of monitoring adaptation to training loads. Considering the above, the analysis of the stability of rotational elements in rhythmic gymnastics should be expanded by taking into account sensory, spatiotemporal, and individual-typological factors. Such a multidimensional approach makes it possible to view the turn not as an isolated technical element but as the result of a complex interaction between biomechanical and neurophysiological