Estimated aortic stiffness is independently associated with cardiac baroreflex sensitivity in humans: role of ageing and habitual endurance exercise.

We hypothesised that differences in cardiac baroreflex sensitivity (BRS) would be independently associated with aortic stiffness and augmentation index (AI), clinical biomarkers of cardiovascular disease risk, among young sedentary and middle-aged/older sedentary and endurance-trained adults. A total of 36 healthy middle-aged/older (age 55-76 years, n=22 sedentary and n=14 endurance-trained) and 5 young sedentary (age 18-31 years) adults were included in a cross-sectional study. A subset of the middle-aged/older sedentary adults (n=12) completed an 8-week-aerobic exercise intervention. Invasive brachial artery blood pressure waveforms were used to compute spontaneous cardiac BRS (via sequence technique), estimated aortic pulse wave velocity (PWV) and AI (AI, via brachial-aortic transfer function and wave separation analysis). In the cross-sectional study, cardiac BRS was 71% lower in older compared with young sedentary adults (P<0.05), but only 40% lower in older adults who performed habitual endurance exercise (P=0.03). In a regression model that included age, sex, resting heart rate, mean arterial pressure (MAP), body mass index and maximal exercise oxygen uptake, estimated aortic PWV (ß±s.e.=-5.76±2.01, P=0.01) was the strongest predictor of BRS (model R(2)=0.59, P<0.001). The 8-week-exercise intervention improved BRS by 38% (P=0.04) and this change in BRS was associated with improved aortic PWV (r=-0.65, P=0.044, adjusted for changes in MAP). Age- and endurance-exercise-related differences in cardiac BRS are independently associated with corresponding alterations in aortic PWV among healthy adults, consistent with a mechanistic link between variations in the sensitivity of the baroreflex and aortic stiffness with age and exercise.

Effects of sleep on the cardiovascular and thermoregulatory systems: a possible role for hypocretins.

Sleep influences the cardiovascular, endocrine, and thermoregulatory systems. Each of these systems may be affected by the activity of hypocretin (orexin)-producing neurons, which are involved in the etiology of narcolepsy. We examined sleep in male rats, either hypocretin neuron-ablated orexin/ataxin-3 transgenic (narcoleptic) rats or their wild-type littermates. We simultaneously monitored electroencephalographic and electromyographic activity, core body temperature, tail temperature, blood pressure, electrocardiographic activity, and locomotion. We analyzed the daily patterns of these variables, parsing sleep and circadian components and changes between states of sleep. We also analyzed the baroreceptor reflex. Our results show that while core temperature and heart rate are affected by both sleep and time of day, blood pressure is mostly affected by sleep. As expected, we found that both blood pressure and heart rate were acutely affected by sleep state transitions in both genotypes. Interestingly, hypocretin neuron-ablated rats have significantly lower systolic and diastolic blood pressure during all sleep stages (non-rapid eye movement, rapid eye movement) and while awake (quiet, active). Thus, while hypocretins are critical for the normal temporal structure of sleep and wakefulness, they also appear to be important in regulating baseline blood pressure and possibly in modulating the effects of sleep on blood pressure.

Cardiovascular responses to angiotensin II in atherosclerosis.

Atherosclerosis is associated with increased angiotensin II AT1-receptor expression and vascular hyperresponsiveness to angiotensin II. Nevertheless, atherosclerosis is often not accompanied by hypertension. We studied if the hypertensive effect of angiotensin II is more pronounced in atherosclerosis. Rabbits were fed a high-cholesterol diet (n = 10) for 12 weeks, followed by a standard diet for another 6 weeks. Control animals received the standard diet (n = 8) for 18 weeks. After 18 weeks, haemodynamic measurements were performed during a baseline recording and during an intravenous infusion of angiotensin II (0.4 microg kg-1 min-1). Atherosclerosis in the high-cholesterol group was verified by histological and lipidchemical tissue examinations. During angiotensin II infusion, total peripheral resistance (TPR) increased more in the high-cholesterol group than in controls (+81.6 +/- 12.4 vs. +40.6 +/- 9.7 mmHg min L-1, P < 0.05). While cardiac output and stroke volume (SV) decreased more in the high-cholesterol group (P < 0.05), reflex bradycardia was stronger in the control group (P < 0.05), indicating a reduced baroreceptor reflex sensitivity in atherosclerosis. Despite the larger increase in TPR and the reduced baroreceptor reflex sensitivity in the high-cholesterol group, maximum blood pressure response to angiotensin II was similar in both groups. The lack of a greater blood pressure response to angiotensin II in the high-cholesterol group could be the result of the early stages of heart failure. Under resting conditions, heart failure seems to be fully compensated, as baseline haemodynamic parameters were similar in the high-cholesterol group and in controls. However, during angiotensin II infusion, the compensatory mechanisms do not prevent a stronger fall in cardiac output and SV. Therefore, the blood pressure response to angiotensin II is not exaggerated in atherosclerotic animals, as vascular hyperresponsiveness to angiotensin II is opposed by the stronger fall in cardiac output and SV.

Sympathetic modulation of blood pressure variability.

Although sympathetic nervous activity (SNA) displays oscillations synchronous with the heart beat and respiration, and between 0.1-0.4 Hz, it is apparent that each of these frequencies does not have the same effect on the vasculature. Frequencies above 1 Hz do not produce oscillations in the vasculature but instead contribute to the mean level of vasoconstriction. Slower oscillations in SNA result in a cycle of vasoconstriction and vasodilation within the vasculature, the amplitude of which, generally decreases with increasing frequency. Some studies indicate that, within the same species, differences exist in the frequency responses between vascular beds, such as the skin and gut. This differential responsiveness is also found between the medullary and cortical vasculature regions of the rabbit kidney. Low-pass filter properties have been described in the iliac circulation of rats, and evidence has been provided that noradrenaline reuptake mechanisms are not the frequency limiting step of the vasculature response. Recent studies on isolated rat vascular smooth muscle cells suggest that sympathetic modulation of vascular tone is limited by the alpha-adrenoceptor signal transduction into the cells and not by an intrinsic inability of the cells to contract and relax at higher rates.

Contractile function of rat myocardium is less susceptible to hypoxia/reoxygenation after acute infarction.

In this study we tested the hypothesis that induction of heat shock proteins (HSPs) and antioxidant enzymes is a compensatory mechanism, which preserves the contractility of the surviving myocardium after acute myocardial infarction. For this purpose, mechanical function of isolated rat papillary muscles was tested 15 h after experimental myocardial infarction and sham operation, respectively. Contractility of the preparations was compared to the expression of HSP25, HSP72, and glutathione peroxidase activity (GSH-Px) at normoxia and during hypoxia/reoxygenation. At normoxic conditions, rates of isometric contraction and, in particular, of relaxation were significantly higher after acute myocardial infarction than after sham operation. Improved relaxation rates were reflected in 2- to 3-fold higher heat shock protein levels in papillary muscles from rats with myocardial infarction compared to sham operated animals. During hypoxia/reoxygenation, the rates of contraction and relaxation were better preserved after myocardial infarction than after sham surgery. Recovery of relaxation rates during reoxygenation was associated with increased HSP25 levels and enhanced GSH-Px activity after myocardial infarction. In conclusion, heat shock proteins exert a beneficial effect on cardiac muscle relaxation after acute myocardial infarction. Enhanced heat shock protein expression and GSH-Px activity may protect the contractile function of the surviving myocardium against the damaging influence of hypoxia/reoxygenation during the early post-infarct period.

Vascular reactivity and baroreflex function during hyperthermia in conscious rats.

The hemodynamic responses to vasoconstrictor agents are blunted during heating in anesthetized rats. It is unknown whether reflex neural responses to these agents are also altered during hyperthermia. Therefore, the purpose of this study was to determine the effect of hyperthermia on the hemodynamic and baroreflex-mediated sympathetic neural responses to vasoactive agents in conscious, unrestrained rats. The splanchnic sympathetic nerve activity (SpNA) and systemic and regional hemodynamic responses to injections of phenylephrine and sodium nitroprusside were measured during normothermia (37 degrees C) and hyperthermia (41.5 degrees C). The hemodynamic responses to phenylephrine and sodium nitroprusside were blunted with heating, whereas the SpNA responses to both agents were augmented or unchanged. At 41.5 degrees C, the baroreflex curves relating heart rate (HR) and SpNA to mean arterial blood pressure were shifted to the right. The operating range and gain of the blood pressure (BP)-HR reflex were significantly reduced during heating, whereas the operating range of the BP-SpNA reflex was augmented at 41.5 degrees C. These results indicate that heating alters the cardiovascular and sympathetic neural responses to vasoactive agents in vivo. Furthermore, the data suggest that heating differentially affects arterial baroreflex control of HR and SpNA, shifting both curves toward higher BP values but selectively attenuating baroreflex control of HR.

Vascular response to angiotensin II in atherosclerosis: role of the baroreflex.

High-cholesterol alimentation is associated with an induction of angiotensin-converting enzyme and angiotensin II receptor expression within the vascular wall of the aorta. Despite an enhanced pressure response to angiotensin II in atherosclerotic conscious rabbits, angiotensin II-induced contraction was reduced in isolated vascular rings from the aorta and unchanged in those from the iliac artery. We, therefore, investigated whether cholesterol-induced atherosclerosis enhances overall vascular responsiveness to angiotensin II in intact animals and whether an altered arterial baroreflex sensitivity can explain the discrepancy between experiments in intact animals and isolated blood vessels. Rabbits were maintained on a high-cholesterol diet (2 g/d cholesterol plus 20 mL/d sunflower seed oil, n=11) or on a standard diet (n=12) for 12 weeks. Total serum lipids markedly increased (P<0.05). Tissue examinations 6 weeks after termination of the high-cholesterol diet revealed distinct atherosclerosis and elevated cholesterol content in the aorta (P<0.05). A high-cholesterol diet did not change baseline hemodynamic parameters. However, angiotensin II-induced increases in total peripheral resistance were larger in the atherosclerotic animals (86.3+/-13.0 versus 41.9+/-9.7 mm Hg. L(-1). min, P<0.05). In addition, the blood pressure pulse interval relationship was markedly reduced (slope: 0.80+/-0.14 versus 0. 49+/-0.06 ms/mm Hg, P<0.05), which suggested that the baroreflex blunted the angiotensin II response to a lesser extent in atherosclerotic animals. In conclusion, the overall vascular responsiveness to angiotensin II is increased in the atherosclerotic rabbit as indicated by the larger increase in total peripheral resistance. An attenuation of the arterial baroreflex sensitivity may contribute to this effect.

Blood pressure control in eNOS knock-out mice: comparison with other species under NO blockade.

Changes in arterial blood pressure (ABP) lead to changes in vascular shear stress. This mechanical stimulus increases cytosolic Ca2+ in endothelial cells, which in turn activates the endothelial isoform of the nitric oxide synthase. The subsequently formed NO reaches the adjacent vascular smooth muscle cells, where it reduces vascular resistance in order to maintain ABP at its initial level. Thus, NO may play an important role as a physiological blood pressure buffer. Previous data on the importance of eNOS for blood pressure control are reviewed with special emphasis on the fact that endogenous nitric oxide can buffer blood pressure variability (BPV) in dogs, rats and mice. In previous studies where all isoforms of the nitric oxide synthase were blocked pharmacologically, increases in blood pressure and variability were observed. Thus, we set out to clarify which isoform of the nitric oxide synthase is responsible for this BPV controlling effect. Hence, blood pressure control was studied in knock-out mice lacking specifically the gene for endothelial nitric oxide synthase with their respective wild-type controls. One day after surgery, under resting conditions, blood pressure was increased by 47 mmHg (P < 0.05), heart rate was lower (-77 beats min-1, P < 0.05), and BPV doubled (P < 0.05). Based on these results, we conclude that chronic blood pressure levels are influenced by eNOS and that there is a blood pressure buffering effect of endogenous nitric oxide which is mediated by the endothelial isoform of the nitric oxide synthase.

Frequency response characteristics of sympathetic transmission to skin vascular smooth muscles in rats.

Sympathetic modulation of cutaneous vasomotor waves in humans is most effective at frequencies up to 0.1 Hz. In contrast, sympathetic modulation of mesenteric vasomotor waves in rats is strongest in the frequency band between 0.2 and 0.75 Hz. Therefore, we addressed the question as to whether these different frequency response characteristics are due to species- or organ-specific disparities. Eleven Sprague-Dawley rats were instrumented with catheters in the carotid artery and in the jugular vein, together with electrodes on the centrally sectioned left lumbar sympathetic trunk (LST) and laser Doppler flow probes directed to the plantar surface of the skin of the left and right hind paws. In anesthetized rats, the LST was electrically stimulated at eight different stimulation frequencies, and the responses in laser Doppler blood flow were recorded in the skin of the ipsilateral and contralateral paw. At stimulation frequencies <0.2 Hz, LST stimulation induced corresponding oscillations in skin blood flow in the ipsilateral, but not in the contralateral, paw. These dynamic responses to LST stimulation in the ipsilateral paw were strongest at 0.05 and 0.075 Hz. At higher stimulation frequencies a tonic vasoconstriction was observed. It is concluded that organ-specific disparities exist in sympathetic transmission to vascular smooth muscles, whereas no species-specific differences are apparent in sympathetic transmission to cutaneous blood vessels of humans and rats.

Expression of cardiac angiotensin-converting enzyme after myocardial infarction.

AIM: To localize cardiac angiotensin-converting enzyme (ACE) during left ventricular repair after myocardial infarction (MI). METHODS: Cardiac ACE was examined by immunohistochemical staining using monoclonal and polyclonal antibodies against ACE 24 h, 1 wk, 2 wk, 3 wk, and 6 wk after coronary artery ligation in rats. Immunofluorescent double staining technique was applied to distinguish the cells which express ACE. RESULTS: ACE staining was confined to the endothelial cells and distributed in normal cardiac tissue in a gradient pattern along the vascular tree: present around the whole circle of arterial endothelium, present in about 20% of the capillaries, and absent in the veins. One week after MI, ACE expression was noted in the granulation tissue. Three weeks after MI, necrosis within the infarction was replaced by granulation tissue and fibrous tissue which showed strong over-expression of ACE. Six weeks after MI, the region with positive ACE staining regressed and the area with high collagen content on the endocardial side showed only weak ACE stain. Most of the ACE-positive cells in the ACE-over-expression-area were endothelial cells. A few macrophages seen in these regions were also ACE-positive. CONCLUSION: Cardiac ACE was over expressed during the process of tissue repair following MI, reaching a peak in 3 wk. Endothelial cells took the most part of ACE expression.

Enhanced blood pressure variability in eNOS knockout mice.

It has been shown previously that endogenous nitric oxide can buffer arterial blood pressure variability in dogs and rats. In these former studies, all isoforms of the nitric oxide synthase were blocked pharmacologically and an increased blood pressure variability was observed. Thus the question as to which isoform of the nitric oxide synthase is responsible for the blood pressure buffering effect of endogenous nitric oxide remains unraveled. In the present study, we therefore compared blood pressure variability in knockout mice that lack specifically the gene for endothelial nitric oxide synthase with their respective wild-type controls. One day after carotid artery cannulation, blood pressure was recorded in these conscious mice. During resting conditions, blood pressure variability was markedly enhanced in knockout mice compared with wild-type mice (10.5+/-1.5 mm Hg2 vs 6.0+/-0.8 mm Hg2, P<0.05). Power spectral analysis revealed that this increase in blood pressure variability is manifested at low frequencies that range from 0.05 to 0.40 s-1 (Hz) (5.1+/-1.0 mm Hg2 vs 2.5+/-0.5 mm Hg2, P<0.05). On the basis of these results, we conclude that the blood pressure buffering effect of endogenous nitric oxide is mediated by the endothelial isoform of the nitric oxide synthase. In addition, endothelial nitric oxide is most effective in buffering blood pressure oscillations at frequencies that range from 0.05 to 0.40 s-1 (Hz) in conscious mice.

Correlation integral of blood pressure as a marker for exercise intensities.

The purpose of this study was to test the hypothesis that the correlation integral technique detects altered regulation of cardiovascular function during graded treadmill exercise. Arterial blood pressure (BP) was measured via telemetry before and during graded treadmill exercise in Sprague-Dawley rats. During treadmill running at mild, moderate, and heavy exercise intensities, the slope of the correlation integrals (SCI) continuously increased from 5.45 +/- 0.17 to 7.12 +/- 0.18, 7.92 +/- 0.23, and 8.40 +/- 0.23, respectively. However, corresponding changes in pulse interval, blood pressure, and systolic blood pressure with increasing workload were not consistently observed. Low-frequency, midfrequency, and high-frequency powers of BP were not different between adjacent exercise grades; only the low-frequency component of pulse interval was different between resting state and mild exercise, and BP variance was significantly different between mild and moderate grades. Comparison of the SCI values with those obtained from surrogate data sets suggests that these differences originate mainly from nonlinear components in the cardiovascular control system. These findings support the hypothesis that SCI detects alterations in cardiovascular regulation associated with graded exercise. Furthermore, SCI may be superior to linear techniques in detecting altered regulation with changing exercise intensities.

Frequency response characteristics of sympathetically mediated vasomotor waves in humans.

In a recent study, we demonstrated that transmission from peripheral sympathetic nerves to vascular smooth muscles is strongest in the frequency band from 0.2 to 0.5 Hz in conscious rats. In contrast, sympathetic modulation of vasomotor tone in humans is suggested to be reflected in the power spectrum of arterial blood pressure in a frequency range centered around approximately 0.1 Hz. Therefore, we addressed whether frequency response characteristics of sympathetic transmission from peripheral sympathetic nerves to vascular smooth muscles in humans differ from those in rats. In 12 male subjects, skin-sympathetic fibers of the left median nerve were electrically stimulated via microneurography needles with stimulation frequencies ranging from 0.01 to 0.5 Hz. Simultaneously, blood flow in the innervated skin area at the palm of the ipsilateral hand was recorded by a laser-Doppler device. The skin blood flow in the same area of the contralateral hand was recorded as a control. Median nerve stimulation produced transient decreases in skin blood flow in the ipsilateral hand. At frequencies ranging from 0.025 to 0.10 Hz, median nerve stimulation evoked high-power peaks at the same frequencies in the skin blood flow power spectra of the ipsilateral but not of the contralateral hand. The greatest responses were found in the frequency range from 0.075 to 0.10 Hz. Therefore, these data indicate that the transmission from peripheral sympathetic nerves to cutaneous vascular smooth muscles in humans is slower than in rats. In addition, the frequency range believed to be most important in sympathetic modulation of vasomotor activity in humans corresponds to the frequency band of the greatest response of cutaneous vascular smooth muscle contraction to sympathetic nerve stimulation.

Decreased susceptibility of contractile function to hypoxia/reoxygenation in chronic infarcted rat hearts.

Cardiac hypertrophy is associated with modifications in Ca2+ transport processes, enzymes of energy metabolism and antioxidant capacity. It is unknown whether these changes occur in infarct-induced hypertrophy with regard to an altered susceptibility to ischemia/reperfusion injury. We examined changes in sarcoplasmic reticulum (SR) Ca2+ transport, creatine kinase (CK) system, and the antioxidant enzymes glutathionperoxidase (GSH-Px) and superoxide dismutase (SOD) in rats 6 weeks after infarction due to coronary ligation (MI). Phenotypic modifications v sham operation (SHAM) were related to the contractile response of hypertrophied papillary muscle to hypoxia/reoxygenation for 30 min each. Under aerobic conditions we observed in MI v SHAM: decreases in isometric contraction and relaxation rate, a reduced Vmax-equivalent of sarcomeric shortening, a faster twitch-to-twitch decay of post-rest potentiation (PRC) which correlated closely to the decrease in SR Ca2+ uptake (-25%), a decrease in CK activity (-20%), reduced CK-MI and CK-MM, increased CK-MB and CK-BB, and enhanced activities of SOD (40%) and GSH-Px (50%). During hypoxia, an initial increase in peak force (PF) was followed by a slower PF decline in MI v SHAM. Reoxygenation caused a recovery of PF to approximately 30% in both groups; rates of contraction and relaxation recovered better in MI. In SHAM but not MI, twitch-to-twitch decay of PRC was accelerated after reoxygenation v aerobic control. The results suggest that adaptive changes in SR Ca2+ handling, CK isoenzymes and antioxidant enzymes may contribute to higher resistance against reduced oxygen supply and reoxygenation in hypertrophy due to MI.

Frequency-response characteristics of autonomic nervous system function in conscious rats.

To characterize the efferent pathway from the hypothalamic paraventricular nucleus (PVN) to peripheral autonomic neurons and finally to selected effector organs, we stimulated the PVN in 10 conscious rats at frequencies ranging from 0.05 to 2.0 Hz. Simultaneously, blood pressure, heart rate, splanchnic sympathetic nerve activity, and mesenteric artery blood flow were measured. The sinus node of the heart responded to PVN stimulation via the parasympathetic pathway (during beta 1-adrenergic blockade) up to a stimulation frequency of 2.0 Hz, whereas the sympathetically mediated response (during muscarinic blockade) was limited to stimulation frequencies < 0.5 Hz. The splanchnic nerve responded to PVN stimulation with synchronous discharges up to stimulation frequencies of 2.0 Hz, whereas the oscillatory component of the vasoconstrictor response of the mesenteric artery was negligible beyond stimulation frequencies of 1.0 Hz. We conclude that sympathetic transmission to the heart is at least four times slower than parasympathetic transmission. In addition, the time-limiting step in sympathetic transmission from the hypothalamus to vascular smooth muscle contraction and pacemaker activity of the sinus node may be located at the site of synaptic transmission to the adrenergic receptors.

Effects of angiotensin-converting enzyme inhibition and angiotensin II AT1 receptor antagonism on cardiac parameters in left ventricular hypertrophy.

Left ventricular hypertrophy (LVH) is considered to be an independent risk factor giving rise to ischemia, arrhythmia, and left ventricular dysfunction. In this article, we summarize recent studies performed in our laboratory to investigate (1) the contribution of the renin-angiotensin system to the cardiac remodeling process, which is triggered by myocardial infarction (MI) or hypertension-induced cardiac hypertrophy; (2) the effects of angiotensin-converting enzyme (ACE) inhibition and angiotensin AT1 receptor antagonism on cardiac parameters, such as myocardial infarct size, cardiac hypertrophy, heart function, and myocardial metabolism; (3) the mechanism of an ACE inhibitor-induced increase in cardiac capillary density in spontaneously hypertensive rats (SHR) and stroke prone SHR (SHR-SP). We observed that AT1 receptor gene expression in rat vascular smooth muscle cells (but not in rat coronary endothelial cells) was markedly enhanced after an ischemic insult in vitro. In a rat model in which MI was induced by coronary artery ligation, the AT1 receptor mRNA levels were transiently increased after MI and reached a peak level 24 hours post-MI. The AT2 receptor gene expression increased in a pattern similar to that of the AT1 receptor. ACE expression at the protein level in the repairing scar, which was demonstrated by monoclonal antibody staining, started to increase 2 weeks after MI and reached a peak level 3 weeks post-MI. Furthermore, long-term treatment with an ACE inhibitor limited infarct size, prevented cardiac hypertrophy, and improved heart function in the rat MI model. In SHR-SP, long-term treatment with either an ACE inhibitor or an AT1 receptor antagonist improved cardiac function and metabolism. Cardiac metabolism was even improved after low-dose ACE inhibitor treatment, which did not prevent hypertension and cardiac hypertrophy. In both SHR and SHR-SP, we found that the ACE inhibitor ramipril significantly increased capillary length density independently of its antihypertensive and antihypertrophic actions. Most of the cardiac effects of the ACE inhibitor could be abolished by a bradykinin B2 receptor antagonist. Thus, these cardiac effects of ACE inhibitors can be ascribed, at least under our experimental conditions, to ACE inhibitor-induced bradykinin potentiation.

Modulation of baroreflex sensitivity and spectral power of blood pressure by heat stress and aging.

To investigate the effects of hyperthermia and aging on baroreceptor-heart rate reflex sensitivity (BRS), cardiovascular parameters were recorded during a progressive rise in core temperature in conscious mature and senescent Fischer 344 rats. BRS was calculated from spontaneous changes in blood pressure and interbeat interval. Low- (LF, 0.01-0.20 Hz) and mid- (MF, 0.2-0.5 Hz) frequency blood pressure power were also determined. In both age groups, hyperthermia caused an increase in blood pressure, renal resistance, and LF but no changes in renal nerve activity, whereas a tachycardia was only observed in the older rats. Increases in BRS (0.80 +/- 0.14 vs. 1.72 +/- 0.34 ms/mmHg, P < 0.05) and MF (3.10 +/- 0.55 vs. 7.81 +/- 1.89 mmHg2, P < 0.05) and a positive correlation between BRS and MF (r = 0.50, P < 0.01) were observed with heating in mature but not senescent rats. These results indicate that LF, which increased with elevated core temperature, may be modulated by thermal stimuli. The augmented BRS in the mature group may contribute to the hemodynamic adjustments that occur with hyperthermia, whereas the lack of an increase in BRS during heat stress in the senescent group suggests that baroreceptor reflex modulation is impaired with aging. The positive correlation between BRS and MF in mature rats, together with the lack of an increase in renal sympathetic nerve activity, indicates that MF may reflect the modulating influence of the efferent sympathetic portion of the baroreceptor reflex loop on arterial blood pressure rather than merely the activity of the peripheral sympathetic nervous system.

Frequency response characteristic of sympathetic-mediated vasomotor waves in conscious rats.

Power spectrum analysis of arterial blood pressure (BP) and heart rate (HR) has been used to investigate autonomic nervous system activity. Sympathetic-mediated vasomotor tone has been attributed to the BP power at frequencies between 0.05 and 0.15 Hz in humans and dogs and between 0.2 and 0.8 Hz in rats. In contrast, it has been suggested that the sympathetic nervous system is too sluggish to transmit frequencies higher than 0.017 Hz in dogs. Thus we investigated the frequency-response characteristics of the transmission of peripheral sympathetic nerve discharge to peripheral vascular resistance and arterial blood pressure in conscious rats. Eleven rats were instrumented with arterial catheters, nerve electrodes on the sympathetic splanchnic nerve, and flow probes on the superior mesenteric artery. The splanchnic nerve was cut proximal to the electrode to avoid afferent nerve stimulation. The next day the nerve was stimulated at frequencies of 0.05, 0.1, 0.2, 0.5, 1.0, and 2.0 Hz while mesenteric blood flow, BP, and HR were recorded in conscious rats. Mesenteric resistance (MR) was calculated off-line. Nerve stimulation at 0.05, 0.1, 0.2, 0.5, and 1.0 Hz significantly increased the power in MR at these respective frequencies. The greatest response was found between 0.2 and 0.5 Hz. These oscillations in MR were translated to oscillations in BP, but not in HR. Nerve stimulation on the second day, when the nerve was degenerated, did not elicit oscillations in MR or BP. We conclude that the peripheral sympathetic nervous system in rats can transmit signals at frequencies higher than those traditionally assigned to sympathetic vasomotor activity in several species, including humans, and may even overlap with the respiration-related high-frequency range.

Aging is not accompanied by sympathetic hyperresponsiveness to air-jet stress.

It has been postulated that sympathetic nervous system reactivity to acutely applied stress is increased with age. We investigated the autonomic and hemodynamic adjustments to air-jet stress in 9 mature (12-mo-old) and 11 senescent (24-mo-old) Fischer 344 rats. Rats were instrumented with arterial and venous catheters, flow probes around the renal artery, and nerve electrodes on the ipsilateral renal nerve. After the rats recovered from surgery, blood pressure, heart rate, renal blood flow, and renal sympathetic nerve activity were recorded during control conditions and during an 8-min continuous air-jet application. Renal resistance and the low (0.01-0.20 Hz)- and mid-frequency (0.20-0.50 Hz) power of blood pressure were computed off-line. The air jet induced an increase in blood pressure, heart rate, renal resistance, renal nerve activity, and blood pressure power in the low- and mid-frequency ranges in both groups. Blood pressure and low-frequency blood pressure power increased less, and the elevations in renal resistance and renal nerve activity were of shorter duration in senescent compared with mature rats. These data suggest that sympathetic responsiveness to air-jet stress is not enhanced with increasing age.

Blood-pressure variability is buffered by nitric oxide.

The baroreflex constitutes the only hitherto known buffer of rapid blood pressure oscillations. In order to investigate the influence of nitric oxide (NO) and the sinoaortic and cardiopulmonary baroreflex pathways on the dynamic properties of blood pressure control, we determined the power spectra of 24-h blood pressure time series of conscious dogs. This was done in the intact state (n = 6), during blockade of NO synthesis via the false substrate NG-nitro-L-arginine ((L-NNA), 16.5 +/- 2 mg/kg body weight i.v., n = 5) and in animals devoid of baroreceptor reflexes (n = 5). After L-NNA, blood pressure (BP) increased by roughly 20 mmHg to 137 +/- 6 mmHg (P < 0.01), heart rate decreased from 97 +/- 6 to 68 +/- 3 beats/min (P < 0.01). The power of blood pressure variations within the frequency range 0.1-0.5 Hz was tripled by L-NNA (P < 0.05). By comparison total sinoaortic and cardiopulmonary denervation increased power of slower oscillations ( < 0.1 Hz) by a factor of 4.7 (P < 0.05). Thus, NO and the baroreceptor reflex both play an important role as physiological blood pressure buffers, NO for rapid (0.1-0.5 Hz) and the baroreflex for slower fluctuations ( < 0.1 Hz).