Abstract
Pain is caused by tissue injury, inflammatory disease, pathogen invasion, or neuropathy. The perception of pain is attributed to the neuronal activity in the brain. However, the dynamics of neuronal activity underlying pain perception are not fully known. Herein, we examined theta-oscillation dynamics of local field potentials in the primary somatosensory cortex of a mouse model of formalin-induced pain, which usually shows a bimodal behavioral response interposed between pain-free periods. We found that formalin injection exerted a reversible shift in the theta-peak frequency toward a slower frequency. This shift was observed during nociceptive phases but not during the pain-free period and was inversely correlated with instantaneous pain intensity. Furthermore, instantaneous oscillatory analysis indicated that the probability of slow theta oscillations increased during nociceptive phases with an association of augmented slow theta power. Finally, cross-frequency coupling between theta and gamma oscillations indicated that the coupling peak frequency of theta oscillations was also shifted toward slower oscillations without affecting coupling strength or gamma power. Together, these results suggest that the dynamic changes in theta oscillations in the mouse primary somatosensory cortex represent the ongoing status of pain sensation.
Highlights
Pain is caused by tissue injury, inflammatory disease, pathogen invasion, or neuropathy
The dynamic relationship between theta-range oscillation and pain sensation remains unknown. It remains unclear whether theta oscillation changes are dynamically associated with time-dependent changes in pain sensation, and whether pain-relevant changes in theta oscillations influence oscillatory activities in the higher frequency range according to theta-oscillation dynamics
Together these results suggest that the dynamic changes in theta oscillations in the mouse S1 cortex represent the ongoing status of pain sensation
Summary
Pain is caused by tissue injury, inflammatory disease, pathogen invasion, or neuropathy. We found that formalin injection exerted a reversible shift in the theta-peak frequency toward a slower frequency This shift was observed during nociceptive phases but not during the pain-free period and was inversely correlated with instantaneous pain intensity. Crossfrequency coupling between theta and gamma oscillations indicated that the coupling peak frequency of theta oscillations was shifted toward slower oscillations without affecting coupling strength or gamma power Together, these results suggest that the dynamic changes in theta oscillations in the mouse primary somatosensory cortex represent the ongoing status of pain sensation. The findings presented here demonstrate that formalin injection exerts a reversible shift of the theta-peak frequency toward slower frequencies This shift was observed during nociceptive phases but not during the pain-free period and inversely correlated with the instantaneous pain intensity. Data are presented as mean ± SEM; **P < 0.01; *P < 0.05 vs. baseline values; a repeated measures ANOVA with a post hoc Dunnett’s multiple comparison test
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