Sheng-Gang Li

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. In previous work, the relationship between SNA and fluctuations in mean arterial blood pressure (MAP) was described by a set of two first-order differential equations. We have now modified our earlier model to test the feasibility that the 0.4-Hz rhythm can be explained by the baroreflex without requiring a neural oscillator. In this baroreflex model, a linear feedback term replaces the sympathetic drive to the cardiovascular system. The time delay in the feedback loop is set equal to the time delay on the efferent side, approximately 0.5 s (as determined in the initial model), plus a time delay of 0.2 s on the afferent side for a total time delay of approximately 0.7 s. A stability analysis of this new model yields feedback resonant frequencies close to 0.4 Hz. Because of the time delay in the feedback loop, the proportional gain may not exceed a value on the order of 10 to maintain stability. The addition of a derivative feedback term increases the systems stability for a positive range of derivative gains. We conclude that the known physiological time delay for the sympathetic portion of the baroreflex can account for the observed 0.4-Hz rhythm in rat MAP and that the sensitivity of the baroreceptors to the rate of change in blood pressure, as well as average blood pressure, would enhance the natural stability of the baroreflex.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. In previous work, the relationship between SNA and fluctuations in mean arterial blood pressure (MAP) was described by a set of two first-order differential equations. We have now modified our earlier model to test the feasibility that the 0.4-Hz rhythm can be explained by the baroreflex without requiring a neural oscillator. In this baroreflex model, a linear feedback term replaces the sympathetic drive to the cardiovascular system. The time delay in the feedback loop is set equal to the time delay on the efferent side, ∼0.5 s (as determined in the initial model), plus a time delay of 0.2 s on the afferent side for a total time delay of ∼0.7 s. A stability analysis of this new model yields feedback resonant frequencies close to 0.4 Hz. Because of the time delay in the feedback loop, the proportional gain may not exceed a value on the order of 10 to maintain stability. The addition of a derivative feedback term increases the systems stability for a positive range of derivative gains. We conclude that the known physiological time delay for the sympathetic portion of the baroreflex can account for the observed 0.4-Hz rhythm in rat MAP and that the sensitivity of the baroreceptors to the rate of change in blood pressure, as well as average blood pressure, would enhance the natural stability of the baroreflex.

Sympathetic nervous activity and arterial pressure responses during rest and acute behavioral stress in SHR versus WKY rats

The object of this experiment is to compare changes in renal sympathetic nerve activity (SNA), mean arterial blood pressure (MAP) and heart rate (HR) during rest and behavioral stress in 12-14 week old spontaneously hypertensive rats (SHR; N = 12) and normotensive Wistar-Kyoto (WKY; N = 12) controls. Animals were behaviorally trained by following a 15 s auditory conditional stimulus (CS+) with a 1/2 s tail shock. Resting MAP was higher (p < 0.001) in SHR (154 +/- 3 mmHg, mean +/- SEM) compared to WKY (116 +/- 3 mmHg); conversely, there was no difference in the average resting HR. The pattern of the SNA and MAP changes during the CS+ was similar across groups, but the amplitude was larger in the SHR. The CS+ stress stimulus evoked an initial transient MAP increase averaging 14 +/- 2 mmHg in the SHR compared to 4 +/- 1 mmHg in the WKY. This pressor response was preceded by a sudden burst of SNA averaging 177 +/- 22% over baseline in SHR versus 105 +/- 13% for the WKY. HR decreased in SHR only during the second component of the CS+ trial despite the large increase in SNA. We conclude that (1) SHR have higher reactivity than WKY to stress in SNA and MAP; (2) both SHR and WKY have greater SNA and MAP responses to CS+ than CS-(i.e., the discriminative paradigm was effective); (3) control of sympathetic and parasympathetic nervous activity during sustained stress differs remarkably in hypertensive and normotensive subjects; and (4) SHR blood pressure effector mechanisms may have a higher responsiveness to sympathetic nervous activity as compared to WKY.

Roles of cardiac output and peripheral resistance in mediating blood pressure response to stress in rats

The change in arterial blood pressure (BP) in response to presentation of an acute behavioral stress (i.e., classical conditioning) in rat includes an initial rapid rise (C1) followed by a delayed, but more sustained, pressor response (C2). The purpose of this experiment is to determine the patterns of change in cardiac output (CO) and total peripheral vascular resistance (TPR) that are associated with the behaviorally induced pressor response. A blood flow probe was implanted around the ascending aorta, and a catheter was implanted in a femoral artery in 10 male Sprague-Dawley rats. The rats were trained by a 15-s tone (CS+) followed by a 0.5-s tail shock; another tone (CS-), never followed by shock, served as a behavioral control. BP responded to the stressful stimulus (CS+) by a rapid C1 increase (8 ± 1 mmHg; mean ± SE) followed by the delayed C2 response (2 ± 0.3 mmHg); the unconditioned response to shock was a 9 ± 2 mmHg increase in BP. The C1 BP increase produced a significant increase in TPR (10 ± 1 dyn ⋅ s/cm5); CO was not significantly changed. TPR decreased during C2 (-4 ± 2 dyn ⋅ s/cm5), whereas CO was significantly increased (2 ± 1 ml/min). These data contribute to our understanding of how the autonomic nervous system organizes the cardiovascular response to a suddenly perceived behavioral stress.The change in arterial blood pressure (BP) in response to presentation of an acute behavioral stress (i.e., classical conditioning) in rat includes an initial rapid rise (C1) followed by a delayed, but more sustained, pressor response (C2). The purpose of this experiment is to determine the patterns of change in cardiac output (CO) and total peripheral vascular resistance (TPR) that are associated with the behaviorally induced pressor response. A blood flow probe was implanted around the ascending aorta, and a catheter was implanted in a femoral artery in 10 male Sprague-Dawley rats. The rats were trained by a 15-s tone (CS+) followed by a 0.5-s tail shock; another tone (CS-), never followed by shock, served as a behavioral control. BP responded to the stressful stimulus (CS+) by a rapid C1 increase (8 +/- 1 mmHg; mean +/- SE) followed by the delayed C2 response (2 +/- 0.3 mmHg); the unconditioned response to shock was a 9 +/- 2 mmHg increase in BP. The C1 BP increase produced a significant increase in TPR (10 +/- 1 dyn.s/cm5); CO was not significantly changed. TPR decreased during C2 (-4 +/- 2 dyn.s/cm5), whereas CO was significantly increased (2 +/- 1 ml/min). These data contribute to our understanding of how the autonomic nervous system organizes the cardiovascular response to a suddenly perceived behavioral stress.

Ablation of posterior atrial ganglionated plexus potentiates sympathetic tachycardia to behavioral stress

The role of the posterior atrial ganglionated plexus (PAGP) in heart rate (HR) control was tested in unanesthetized dogs ( n = 8). Resting HR was unchanged before (85 ± 20 beats/min, mean ± SD) versus after (87 ± 18 beats/min) surgical ablation of these intrinsic cardiac ganglia (PAGPX). However, the peak tachycardia to a 30-s stressful stimulus was significantly increased ( P < 0.05) from +53 ± 22 beats/min before the denervation to +77 ± 13 beats/min after PAGPX. Conversely, the peak HR increase during the stress after β-adrenergic blockade was the same before (36 ± 24 beats/min) versus after (38 ± 14 beats/min) PAGPX. Moreover, the HR response to a neutral behavioral stimulus, which is mediated primarily by withdrawal of parasympathetic inhibition of the sinoatrial (SA) node, was unaltered by PAGPX. Thus the augmented tachycardia subsequent to PAGPX was attributable primarily to increased sympathetic action at the SA node. These findings indicate that a major role of PAGP parasympathetic neurons is to inhibit sympathoexcitatory effects on HR, probably either via interactions between neurons comprising the intrinsic plexus(es) or perhaps via presynaptic inhibition of sympathetic neurotransmitter release. This organization would allow parasympathetic ganglia within the PAGP to selectively modify sympathetic input to the SA node independent of direct vagal inhibition of pacemaker activity.The role of the posterior atrial ganglionated plexus (PAGP) in heart rate (HR) control was tested in unanesthetized dogs (n = 8). Resting HR was unchanged before (85 +/- 20 beats/min, mean +/- SD) versus after (87 +/- 18 beats/min) surgical ablation of these intrinsic cardiac ganglia (PAGPX). However, the peak tachycardia to a 30-s stressful stimulus was significantly increased (P < 0.05) from +53 +/- 22 beats/min before the denervation to +77 +/- 13 beats/min after PAGPX. Conversely, the peak HR increase during the stress after beta-adrenergic blockade was the same before (36 +/- 24 beats/min) versus after (38 +/- 14 beats/min) PAGPX. Moreover, the HR response to a neutral behavioral stimulus, which is mediated primarily by withdrawal of parasympathetic inhibition of the sinoatrial (SA) node, was unaltered by PAGPX. Thus the augmented tachycardia subsequent to PAGPX was attributable primarily to increased sympathetic action at the SA node. These findings indicate that a major role of PAGP parasympathetic neurons is to inhibit sympathoexcitatory effects on HR, probably either via interactions between neurons comprising the intrinsic plexus(es) or perhaps via presynaptic inhibition of sympathetic neurotransmitter release. This organization would allow parasympathetic ganglia within the PAGP to selectively modify sympathetic input to the SA node independent of direct vagal inhibition of pacemaker activity.

Sympathetic control of BP and BP variability in borderline hypertensive rats on high- vs. low-salt diet.

This experiment tested the effect of a high-salt diet on the interaction between arterial blood pressure (BP) and sympathetic nerve activity (SNA) at rest and during a controlled behavioral stress at an early stage in the development of hypertension in borderline hypertensive rats (BHR). Ten rats were maintained on a high-salt diet (8% NaCl) while 14 were fed a low-salt diet (0.8% NaCl) for 8 wk. They were trained in a Pavlovian paradigm by following a conditional stimulus tone (CS+) with a 0.5-s shock. SNA and BP were measured by implanted electrodes around the left renal nerve and a catheter in the femoral artery, respectively. There were no detectable between-group differences in BP or in BP variability in the resting animal at the end of the 8-wk dietary treatment. Moreover, there were no significant between-group differences in the changes in SNA evoked by the CS+ tone. Conversely, the amplitude of the initial conditional increase in BP was significantly ( P< 0.05) larger in the high-salt (6 ± 0.6 mmHg; mean ± SEM) compared with the low-salt (4 ± 0.4 mmHg) group. In addition, the BP excursion (peak/trough) during CS+ was larger in the high (18.2 ± 6.1 mmHg)- vs. low-salt (5.8 ± 0.4 mmHg) diet-fed subjects. The ratio of the average percent change in mean BP to the average percent change in SNA at the beginning of CS+ was 0.029 ± 0.004 for the low-salt group and 0.041 ± 0.006 for the high-salt group. We find that, before the development of overt hypertension, the enhanced conditional BP response in the high-salt BHR appears to reside at the interface between changes in SNA and the effector response and not within the central nervous system. These observations help explain the increasing BP variability typically observed with the development of hypertension in humans.This experiment tested the effect of a high-salt diet on the interaction between arterial blood pressure (BP) and sympathetic nerve activity (SNA) at rest and during a controlled behavioral stress at an early stage in the development of hypertension in borderline hypertensive rats (BHR). Ten rats were maintained on a high-salt diet (8% NaCl) while 14 were fed a low-salt diet (0.8% NaCl) for 8 wk. They were trained in a Pavlovian paradigm by following a conditional stimulus tone (CS+) with a 0.5-s shock. SNA and BP were measured by implanted electrodes around the left renal nerve and a catheter in the femoral artery, respectively. There were no detectable between-group differences in BP or in BP variability in the resting animal at the end of the 8-wk dietary treatment. Moreover, there were no significant between-group differences in the changes in SNA evoked by the CS+ tone. Conversely, the amplitude of the initial conditional increase in BP was significantly (P < 0.05) larger in the high-salt (6 +/- 0.6 mmHg; mean +/- SEM) compared with the low-salt (4 +/- 0.4 mmHg) group. In addition, the BP excursion (peak/trough) during CS+ was larger in the high (18.2 +/- 6.1 mmHg)- vs. low-salt (5.8 +/- 0.4 mmHg) diet-fed subjects. The ratio of the average percent change in mean BP to the average percent change in SNA at the beginning of CS+ was 0.029 +/- 0.004 for the low-salt group and 0.041 +/- 0.006 for the high-salt group. We find that, before the development of overt hypertension, the enhanced conditional BP response in the high-salt BHR appears to reside at the interface between changes in SNA and the effector response and not within the central nervous system. These observations help explain the increasing BP variability typically observed with the development of hypertension in humans.

Norepinephrine levels in discrete brain nuclei in borderline hypertensive rats exposed to compound stressors.

The borderline hypertensive rat (BHR) appears to be an appropriate model for investigating the role of the environment in producing hypertension. Previous studies have demonstrated that the BHR shows chronic blood pressure elevations to both stress and high salt intake. Other studies suggest that interactions between the brain and kidney play an important role in initiating this hypertension. The central noradrenergic system has been implicated in these effects, especially in the hypothalamus. Because exercise has been found to attenuate stress-induced hypertension in the BHR, the current study sought to examine the impact of stressors paired with exercise (salt intake or stress) with those combining stress and high salt. Male BHR were exposed to either control, salt plus stress, salt plus exercise, or stress plus exercise conditions for either 2 or 6 months, beginning at 2 months of age. Following sacrifice, brain nuclei in the brain stem and hypothalamus were removed using the Palkovits micropunch technique. Punches were analyzed for NE content via liquid chromatography with electrochemical detection. Compared with the control condition, chronic salt plus stress led to reductions in NE content, especially in the hypothalamus. Compared with salt plus stress, the exercise conditions were associated with elevated NE levels, especially in the early phases of exposure to the treatment. The possible role of exercise training in preventing a central nervous system trigger from inducing hypertension in the BHR is discussed.

Parasympathetic response to acute stress is attenuated in young Zucker obese rats

We compared arterial blood pressure (BP) and heart rate (HR) control in 9- to 11-week old obese Zucker rats (n=10; weight=452+/-45 g, average+/-SD) to age-matched, lean Zucker animals (n=13; weight=280+/-46 g). BP was measured by indwelling catheter. Baseline pressure was 113.1+/-7.0 mm Hg in the lean vs. 111.7+/-5.6 in the obese rats (NS). Baseline HR was 413+/-43 in the lean vs. 422+/-22 bpm in the obese animals (NS). Rats were classically conditioned by following a 15-second tone (CS+) with a 0.5-second tail shock. There were no between-group differences in the BP response to CS+. Conversely, heart rate (HR) decreased significantly (p<0.05) more during the last 10 s of the tone in the lean group (-46.0+/-21.5 bpm) vs. the obese (-17.8+/-21.7 bpm). This bradycardia was blocked by atropine. Finally, the change in HR divided by the change in arterial BP (DeltaHR/DeltaBP) following an intravenous bolus of phenylephrine (PE; 5 microg/kg) and following sodium nitroprusside (NP; 5 microg/kg) was determined. The DeltaHR/DeltaBP following PE was smaller in the obese (n=6; -1.36+/-0.60) vs. lean (n=5; -2.80+/-0.92); there was no difference in the response following NP. These data indicate that the BP response to a behavioral challenge did not differ in the obese rat vs. the lean animal, but that the obese subjects had an attenuated parasympathetic response to the stress, probably secondary to alterations in baroreflex function.

Autonomic nervous control of heart rate orienting and alpha responses in dog

The object of this experiment is to study the autonomic nervous control of alpha responses elicited in classical conditioning. Twenty-two mongrel dogs were trained in classical discriminative conditioning. Typical two-phase tachycardic responses were observed in positive (CS+) trials while only the earliest, phase 1, response was observed in negative (CS-) trials. The phase 1 response, which was identical in CS+ and CS-trials, was compared in dogs before and after selective SA-nodal parasympathectomy (N=7) and beta-adrenergic blockade (N=11). The phase 1 tachycardic response was eliminated by selective SA-nodal parasympathectomy but not by beta-adrenergic blockade. We conclude that the phase 1 response observed in both CS+ and CS-trials with similar time sequence and magnitude is an alpha response. The heart rate orienting response results from a withdrawal of parasympathetic activity with little or no change in sympathetic tone.

Effects of a high salt diet on blood pressure responses to acoustic stimuli in borderline hypertensive rats (BHR)

The borderline hypertensive rat (BHR) responds to environmental and dietary stressors with elevated blood pressure. The first two months of a high salt diet appear to be the time of greatest sensitivity to salt effects on the blood pressure of BHR. The current study was conducted to examine whether exposure to salt diets varying in duration for up to two months differentially affects baseline blood pressures (systolic, SBP, and diastolic, DBP) and blood pressure responses to novel acoustic stimuli in BHR and normotensive Wistar-Kyoto (WKY) rats. Male BHR and WKY were fed a control (1%) salt diet or a high (8%) salt diet for 1, 1.5, 2.5, or 8.5 weeks. SBP and DBP responses to an acoustic stimulus (85 dB, 3 kHz) were measured upon completion of the diets at 12 weeks of age. Ten acoustic trials (one stimulus/minute) were presented and blood pressure responses were recorded in 2-second blocks spanning the 10 seconds prior to and following stimulus presentation. BHR had higher resting SBP and DBP than WKY, and 8.5 weeks of 8 percent salt increased SBP markedly in BHR. SBP and DBP labilities in the initial trial were greater in BHR than WKY with high salt diet durations of 2.5 and 8.5 weeks producing greater lability in later trials. Few differences were noted in pressor responses, but BHR had more dramatic depressor responses than WKY in early trials, and BHR pressures had a more dramatic return to baseline. It appears that genetic history and salt diet can affect blood pressure lability and recovery in response to novel stimuli in genetically susceptible animals.