Dynamic relationship between sympathetic nerve activity and renal blood flow: a frequency domain approach

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Dynamic relationship between sympathetic nerve activity and renal blood flow: a frequency domain approach

Sarah-Jane Guild¹, Paul C. Austin¹, Michael Navakatikyan¹, John V. Ringwood², and Simon C. Malpas¹

¹ Circulatory Control Laboratory, Departments of Physiology and Electrical and Electronic Engineering, University of Auckland, New Zealand; and ² Department of Electronic Engineering, National University of Ireland, Maynooth, County Kildare, Ireland

Blood pressure displays an oscillation at 0.1 Hz in humans that is well established to be due to oscillations in sympatheticnerve activity (SNA). However, the mechanisms that control thestrength or frequency of this oscillation are poorly understood.The aim of the present study was to define the dynamic relationshipbetween SNA and the vasculature. The sympathetic nerves to thekidney were electrically stimulated in six pentobarbital-sodiumanesthetized rabbits, and the renal blood flow response was recorded.A pseudo-random binary sequence (PRBS) was applied to the renalnerves, which contains equal spectral power at frequencies inthe range of interest (<1 Hz). Transfer function analysis revealeda complex system composed of low-pass filter characteristics butalso with regions of constant gain. A model was developed thataccounted for this relationship composed of a 2 zero/4 pole transferfunction. Although the position of the poles and zeros variedamong animals, the model structure was consistent. We also foundthe time delay between the stimulus and the RBF responses to beconsistent among animals (mean 672 ± 22 ms). We propose that theidentification of the precise relationship between SNA and renalblood flow (RBF) is a fundamental and necessary step toward understandingthe interaction between SNA and other physiological mediatorsofRBF.

modeling; pseudo-random binary sequence

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