The role of central vasopressin receptors in the modulation of autonomic cardiovascular controls: a spectral analysis study

Although it has been suggested that vasopressin (VP) acts within the central nervous system to modulate autonomic cardiovascular controls, the mechanisms involved are not understood. Using nonpeptide, selective V(1a), V(1b), and V(2) antagonists, in conscious rats, we assessed the roles of central VP receptors, under basal conditions, after the central application of exogenous VP, and after immobilization, on cardiovascular short-term variability. Equidistant sampling of blood pressure (BP) and heart rate (HR) at 20 Hz allowed direct spectral analysis in very-low frequency (VLF-BP), low-frequency (LF-BP), and high-frequency (HF-BP) blood pressure domains. The effect of VP antagonists and of exogenous VP on body temperature (T(b)) was also investigated. Under basal conditions, V(1a) antagonist increased HF-BP and T(b), and this was prevented by metamizol. V(1b) antagonist enhanced HF-BP without affecting T(b), and V(2) antagonist increased VLF-BP variability which could be prevented by quinapril. Immobilization increased BP, LF-BP, HF-BP, and HF-HR variability. V(1a) antagonist prevented BP and HR variability changes induced by immobilization and potentiated tachycardia. V(1b) antagonist prevented BP but not HR variability changes, whereas V(2) antagonist had no effect. Exogenous VP increased systolic arterial pressure (SAP) and HF-SAP variability, and this was prevented by V(1a) and V(1b) but not V(2) antagonist pretreatment. Our results suggest that, under basal conditions, VP, by stimulation of V(1a), V(1b), and cognate V(2) receptors, buffers BP variability, mostly due to thermoregulation. Immobilization and exogenous VP, by stimulation of V(1a) or V(1b), but not V(2) receptors, increases BP variability, revealing cardiorespiratory adjustment to stress and respiratory stimulation, respectively.