Transvascular Pacing of Aorticorenal Ganglia Provides a Testable Procedural Endpoint for Renal Artery Denervation

Objectives: This study sought to develop a method to assess renal sympathetic nerve function through localization and pacing of aorticorenal ganglia (ARG).

Background: Transcatheter renal denervation procedures often fail to produce complete renal denervation because of the lack of a physiological procedural endpoint.

Methods: High-frequency pacing was performed in the inferior vena cava and aorta in sheep (n = 19) to identify ARG pace-capture sites. Group A (n = 5) underwent injection at the ARG pace-capture site for histological verification, group B (n = 6) underwent unilateral irrigated radiofrequency ablation of ARG pace-capture sites and assessment of renal innervation at 1 week post-procedure; and group C (n = 8) underwent ARG pacing before and 2 to 3 weeks after unilateral microwave renal denervation.

Results: ARG pace-capture responses were observed at paired discrete sites above the ipsilateral renal artery eliciting a change in mean arterial blood pressure of 22.2 (interquartile range [IQR]: 15.5 to 34.3 mm Hg; p < 0.001) with concurrent ipsilateral renal arterial vasoconstriction, change in main renal artery diameter of -0.42 mm (IQR: -0.64 to -0.24 mm; p < 0.0001), and without consistent contralateral renal vasoconstriction. Sympathetic ganglionic tissue was observed at ARG pace-capture sites, and ganglion ablation led to significant ipsilateral renal denervation. Circumferential renal denervation resulted in immediate and sustained abolition of ARP pacing-induced renal vasoconstriction and significant ipsilateral renal denervation.

Conclusions: Transvascular ARG pace-capture is feasible and recognized by concurrent hypertensive and ipsilateral renal arterial vasoconstrictive responses. Abolition of ARG pacing-induced vasoconstriction may indicate successful renal sympathetic denervation and serve as a physiological procedural endpoint to guide transcatheter renal denervation.