Chronic angiotensin-II treatment potentiates HR slowing in Sprague-Dawley rat during acute behavioral stress.

This study examined the effect of 2-week infusion of angiotensin-II (Ang-II; 175 ng/kg/min) via minipump in rats (n=7) upon the mean arterial blood pressure (mBP) and heart rate (HR) response to an acute stress as compared to rats infused with saline (n=7). The acute stress was produced by a classical aversive conditioning paradigm: a 15s tone (CS+) followed by a half second tail shock. Baseline mBP in Ang-II infused rats (167.

Coupling of sympathetic nerve traffic and BP at very low frequencies is mediated by large-amplitude events.

This study explores the functional association between renal sympathetic nerve traffic (NT) and arterial blood pressure (BP) in the very-low-frequency range (i.e., <0.

Heart rate-arterial blood pressure relationship in conscious rat before vs. after spinal cord transection.

This experiment quantified the initial disruption and subsequent adaptation of the blood pressure (BP)-heart rate (HR) relationship after spinal cord transection (SCT). BP and HR were recorded for 4 h via an implanted catheter in neurally intact, unanesthetized rats. The animals were then anesthetized, and their spinal cords were severed at T(1)-T(2) (n = 5) or T(4)-T(5) (n = 6) or sham lesioned (n = 4).

Low-frequency renal sympathetic nerve activity, arterial BP, stationary "1/f noise," and the baroreflex.

The object of this study is to quantify the very low frequency (i.e., <0.

First-order differential-delay equation for the baroreflex predicts the 0.4-Hz blood pressure rhythm in rats.

We have described a 0.4-Hz rhythm in renal sympathetic nerve activity (SNA) that is tightly coupled to 0.4-Hz oscillations in blood pressure in the unanesthetized rat.

Multifiber renal SNA recordings predict mean arterial blood pressure in unanesthetized rat.

The goal of this analysis was to quantify the relationship between renal sympathetic nerve activity (SNA) and mean arterial blood pressure (MAP). We previously recorded renal SNA and MAP in conscious rats during a stressful behavioral stimulus and during a nonstressful stimulus. We then formulated a set of two linear, first-order differential equations that uses our SNA recordings after a time delay (the input) to predict fluctuations in MAP (the output).