Theta-shaking mitigates cognitive-emotional decline via subiculum and ventral septum metabolic plasticity.

Aging-associated cognitive decline remains a major challenge in gerontology; few non-invasive interventions provide both mechanistic insight and translational feasibility. We investigated whether low-frequency "theta-shaking" whole-body vibration (5 ​Hz) could modulate cognitive function, emotional behavior, and metabolic plasticity in a senescence-accelerated mouse model. Senescence-accelerated mouse prone-10 mice were exposed to theta-shaking stimulation for 30 weeks. Spatial memory was assessed using Y-maze spontaneous alternation test, and anxiety-related behavior was evaluated using marble burying test. Histological and immunohistochemical analyses were conducted to assess neuronal density and protein expression in specific brain regions. Theta-shaking subjected mice exhibited delayed yet significant improvements in spatial memory at 20 (p ​= ​0.017) and 30 (p ​= ​0.018) weeks. Anxiety-related behavior shows a biphasic pattern: an initial increase at 20 weeks (p ​< ​0.001) followed by stabilization at 30 weeks. Histological analysis revealed preserved neuronal density in the subiculum (p ​< ​0.001) and elevated proliferator-activated receptor gamma coactivator 1-alpha (PGC1α) expression in the Cornu Ammonis 1, subiculum, and lateral septum (all p ​< ​0.05). Notably, mitochondrial biogenesis appeared to be intervention's primary target, as shown by robust PGC1α upregulation, while brain-derived neurotrophic factor revealed a trend-level increase (p ​= ​0.062), and neurotrophin-3 expression remained unchanged. Frequency-tuned mechanical stimulation induced region-specific neural neurometabolic adaptations, supporting theta-shaking as a non-pharmacological, low-exertion strategy to counteract brain aging. These findings offer promising translational potential, especially for individuals with limited mobility.