Considering that educational activities are systematic activities that induce changes in students' brains, a neuroscientific understanding of how the brain works when utilizing learning situations and the spaced learning strategy can enhance a convergent perspective on learning and contribute to reframing the concepts of learning and education. Based on this importance, this study aims to understand the neuroscientific mechanisms of learning and the spaced learning strategy and to explore their educational implications. A literature review was conducted within the field of neurobiology, focusing on studies related to learning and spaced learning strategies. This review sought to identify neuronal-level changes observable during learning situations. Synaptic spines present in postsynaptic neurons tend to increase in their formation and elimination during learning, and newly generated synaptic spines around originally stable synaptic spines tend to be maintained for a longer period. When learning is spaced, newly generated synaptic spines can be larger and more stably maintained, which is considered to be associated with the facilitation of long-term potentiation, a mechanism essential for long-term memory formation. Furthermore, spaced learning reduces automatic processing and decreases neural repetition suppression, thereby enhancing the overall activation of brain regions critical for long-term memory consolidation, ultimately improving learning outcomes. This study confirms, at the neuronal level, that learning is a process that transforms the brain rather than merely utilizing it. By integrating neuroscientific knowledge into the understanding of learning and learning strategies, this research contributes to the advancement of educational neuroscience and its practical application, fostering a deeper neuroscientific understanding among educators.