Pressor and depressor responses after cholinergic blockade in humans

Beat-to-beat blood pressure and heart rate responses to the Valsalva maneuver

Measurement of beat-to-beat blood pressure and heart rate responses to the Valsalva maneuver is the basis for a highly informative autonomic function test. Whereas in the past this measurement required intra-arterial cannulation, the development of finger cuff devices that acquire arterial pressure waveforms indistinguishable from those recorded intra-arterially has made it possible to obtain accurate measurements noninvasively. In a patient with orthostatic hypotension, the pattern of blood pressure responses during and after the release of the maneuver can identify a neurogenic basis: sympathetic neurocirculatory failure. The quantifiable change in cardiac interbeat interval per unit change in systolic pressure during the maneuver can identify baroreflex-cardiovagal failure.

Low-dose atropine amplifies cardiac vagal modulation and increases dynamic baroreflex function in humans

It has been previously known that low-dose atropine (LDA) enhances vagal outflow to the heart. To demonstrate the importance of vagal cardiac modulation in arterial blood pressure (ABP) stability, we evaluated the effect of vagal cardiac stimulation with administration of LDA on ABP fluctuation during dynamic hypertensive and hypotensive stimuli. We assessed changes in RR interval (RRI), ABP, power spectral densities of heart rate variability (HRV) and ABP variability, and spontaneous baroreflex sensitivity (BRS) in 16 healthy volunteers before and after administration of LDA (2 microg/kg). Transient hypertension was induced by phenylephrine (2 microg/kg), whereas hypotension was induced by bilateral thigh cuff deflation after a 3-min suprasystolic occlusion. LDA elicited bradycardia and significantly increased high-frequency (HF, 0.15-0.4 Hz) power of HRV and spontaneous BRS, as determined by transfer function analysis. The increase in systolic blood pressure (SBP) after phenylephrine administration was significantly attenuated by LDA (16+/-2 to 11+/-3 mmHg, P<0.005) and was associated with the augmented reflex bradycardia, whereas the decrease in SBP after cuff deflation was not affected (14+/-5 to 13+/-5 mmHg) with the augmented reflex tachycardia. Increases of HF HRV were correlated significantly and negatively with the increased SBP induced by phenylephrine before and after LDA (r=-0.502, P<0.05). These data suggest that the increased vagal cardiac function induced by LDA augments HR buffering effects, and is important in minimizing arterial pressure fluctuation during dynamic hypertensive stimuli.

Functional Neuroimaging of Sympathetic Innervation of the Heart

Many concepts about acute and chronic effects of stress depend on alterations in sympathetic nerves supplying the heart. Physiologic, pharmacologic, and neurochemical approaches have been used to evaluate cardiac sympathetic function. This article describes a fourth approach that is based on nuclear scanning to visualize cardiac sympathetic innervation and function and relationships between the neuroimaging findings and those from other approaches. Multiple-system atrophy with orthostatic hypotension (formerly the Shy-Drager syndrome) features normal cardiac sympathetic innervation and normal entry of norepinephrine into the coronary sinus (cardiac norepinephrine spillover), in contrast to Parkinson disease with orthostatic hypotension, which features neuroimaging and neurochemical evidence for loss of cardiac sympathetic nerves. This difference may have important implications not only for diagnosis but also for understanding the etiology of Parkinson disease. By analysis of curves relating myocardial radioactivity with time (time-activity curves) after injection of a sympathoneural imaging agent, it is possible to obtain information about cardiac sympathetic function. Abnormal time-activity curves are seen in common disorders such as heart failure and diabetic neuropathy and provide an independent, adverse prognostic index. Analogous abnormalities might help explain increased cardiovascular risk in psychiatric disorders such as melancholic depression.

Association between supine hypertension and orthostatic hypotension in autonomic failure

Supine hypertension occurs commonly in primary chronic autonomic failure. This study explored whether supine hypertension in this setting is associated with orthostatic hypotension (OH), and if so, what mechanisms might underlie this association. Supine and upright blood pressures, hemodynamic responses to the Valsalva maneuver, baroreflex-cardiovagal gain, and plasma norepinephrine (NE) levels were measured in pure autonomic failure (PAF), multiple-system atrophy (MSA) with or without OH, and Parkinson's disease (PD) with or without OH. Controls included age-matched, healthy volunteers and patients with essential hypertension or those referred for dysautonomia. Baroreflex-cardiovagal gain was calculated from the relation between the interbeat interval and systolic pressure during the Valsalva maneuver. PAF, MSA with OH, and PD with OH all featured supine hypertension, which was equivalent in severity to that in essential hypertension, regardless of fludrocortisone treatment. Among patients with PD or MSA, those with OH had higher mean arterial pressure during supine rest (109+/-3 mm Hg) than did those lacking OH (96+/-3 mm Hg, P=0.002). Baroreflex-cardiovagal gain and orthostatic increments in plasma NE levels were markedly decreased in all 3 groups with OH. Among patients with PD or MSA, those with OH had much lower mean baroreflex-cardiovagal gain (0.74+/-0.10 ms/mm Hg) than did those lacking OH (3.13+/-0.72 ms/mm Hg, P=0.0002). In chronic autonomic failure, supine hypertension is linked to both OH and low baroreflex-cardiovagal gain [corrected]. The finding of lower plasma NE levels in patients with than without supine hypertension suggests involvement of pressor mechanisms independent of the sympathetic nervous system.

Parasympathetic control of cardiac sympathetic activity: normal ventricular function versus congestive heart failure

BACKGROUND

Muscarinic receptors on adrenergic nerve terminals attenuate norepinephrine release. The role of these receptors in the modulation of cardiac norepinephrine release in humans remains uncertain.

METHODS AND RESULTS

Twelve patients with normal left ventricular (LV) function and 18 with congestive heart failure (CHF) were studied. A radiotracer technique was used to measure cardiac norepinephrine spillover (CANESP) in response to intracoronary acetylcholine (ACh, 5x10(-5) Mol), and in response to intracoronary atropine (12 micrograms/min). ACh did not affect CANESP in the group of subjects with normal LV function, but it caused a significant reduction in those with CHF [197 (150 to 302) versus 168 (87 to 288) pmol/min, P<0.05]. Atropine caused a significant increase in CANESP in those with normal LV function [47 (27 to 51) versus 64 (38 to 139) pmol/min, P<0.05], but no change was observed in the CHF group.

CONCLUSIONS

Therefore, in the setting of heart failure and sympathetic activation, muscarinic receptor stimulation decreases CANESP, an effect not observed in patients with preserved LV function. Blockade of muscarinic receptors with atropine increased CANESP in patients with normal LV function, suggesting that cardiac parasympathetic tone has inhibitory effects on cardiac sympathetic activity. This basal inhibition was not observed in CHF patients in response to atropine. The lack of basal parasympathetic inhibition of cardiac sympathetic activity may play a role in the pathogenesis of cardiac sympathetic activation in heart failure.

Pathophysiologic basis for vasodepressor syncope

The current knowledge regarding the pathophysiologic basis of the vasodepressor response was reviewed. The balance of evidence indicates that the mechanoreceptor hypothesis seems unlikely to be the sole afferent alteration that leads to the vasodepressor response. Alternative afferent mechanisms should include neurohumoral mediated sympathoinhibition triggered by opioid mechanisms as well as impaired endothelial and NO responses to orthostatic stress in susceptible individuals. It is possible that impaired cardiovagal and sympathetic outflow control of arterial baroreceptors is enhanced by the aforementioned mechanisms. The role of central sympathoinhibition and vagal excitation triggered directly from pathways within the temporal lobe or triggered by alterations in regional cerebral blood flow should be considered as potential alternative mechanisms. Efferent autonomic outflow during vasodepressor syncope include sympathetic neural outflow withdrawal in addition to activation of parasympathetic outflow to the heart and abdominal viscera. Further human research is needed to understand the underlying mechanisms that result in the described neural and vascular responses.

Syncope and the autonomic nervous system

The autonomic nervous system plays a central role in the maintenance of hemodynamic stability. Dysfunction of this complex regulatory system can lead to the development of loss of consciousness. This article summarizes our current understanding of the role of the autonomic nervous system in maintaining a stable blood pressure and heart rate under normal and abnormal physiologic conditions. The role of baroreceptors, mechanoreceptors, chemoreceptors, vascular reactivity, and the interaction of these sensor systems with the central nervous system as a whole are reviewed. Current concepts related to the mechanisms of unexplained syncope and the "state-of-the-art" diagnostic and treatment options are also discussed.

Usefulness of head-up tilt test in evaluating patients with syncope of unknown origin and negative electrophysiologic study

The vasovagal nature of syncope, which remained unexplained despite full clinical and electrophysiologic investigation, was evaluated by means of 60 degrees head-up tilt test for 60 minutes. Thirty patients (17 men and 13 women, mean age 65 years, 19 with and 11 without organic heart disease) with 1 to 28 (mean 5) episodes of syncope of unknown origin were studied. Head-up tilt test was considered positive if syncope developed in association with hypotension, bradycardia, or both. During baseline head-up tilt 15 patients (50%) had a positive response. Ten patients had a vasodepressor response (marked hypotension without marked bradycardia) and 5 had a mixed response (marked hypotension with marked bradycardia). None of 8 control subjects became symptomatic during the test. Baseline head-up tilt test was positively reproducible in 10 of 14 patients (71%). Nine of these 10 patients underwent serial head-up tilt tests after drug administration to determine the pathogenesis of vasovagal syncope. Atropine prevented tilt-induced syncope in 3 of 8 patients (37.5%), propranolol in 2 of 8 (25%) and etilephrine in 7 of 7 (100%). Seven patients received long-term drug treatment with drugs selected on the basis of acute drug testing. One responder to atropine received transdermal scopolamine and 6 received etilephrine. None of these 7 patients had syncopal recurrences or death during a mean follow-up of 12 months. Head-up tilt is a very sensitive and highly specific test to unmask susceptibility to vasovagal reaction in patients with syncope of unknown origin. Withdrawal of alpha-sympathetic stimulation is a principal mechanism responsible for vasodilation and syncope during head-up tilt.(ABSTRACT TRUNCATED AT 250 WORDS)

Atrial natriuretic factor and autonomic nervous system function in man

To delineate a possible interaction of atrial natriuretic peptide ANF-(99-126) with autonomic nervous system function in humans, a spectrum of indices were assessed in 10 healthy young men during a 90 min iv administration of a) synthetic ANF-(99-126) 50 micrograms bolus followed by 0.025 micrograms.kg-1.min-1, b) the potent vasodilator sodium nitroprusside (SNP) 0.35 micrograms.kg-1. min-1, or c) vehicle 0.9% NaCl40 ml and 20% albumin 5 ml, in random sequence. Plasma immunoreactive ANF (irANF) rose from 32 to 1700 pg.ml-1 during the ANF-(99-126) infusion and was stable during SNP or vehicle. Infusion of ANF-(99-126) and SNP, but not vehicle, decreased diastolic blood pressure (BP) on average by -9 and -7.5%, respectively; systolic BP was largely unchanged. Heart rate (HR, + 15 and 12%) or plasma norepinephrine (NE) rose similarly during ANF-(99-126) and SNP infusions, and the systolic BP response to orthostasis was similar (-18 mmHg). The following autonomic indices did not differ significantly after the 3 infusions: responses of HR and NE to orthrostasis; reflex bradycardic response to phenylephrine (PE)-induced rise in systolic BP (+ 20 mmHg); responses of BP to hyperventilation, PE, or 3 min of sustained handgrip; and beat-to-beat variation (R-R interval) during deep breathing. The immediate orthostatic HR response (30/15 R-R interval ratio) fell similarly during infusion of ANF-(99-126) or nitroprusside. The findings indicate that in healthy men the function of the autonomic nervous system is not notably impaired by high circulating ANF levels.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of atropine on adrenergic responsiveness and reflex vasoconstriction in humans

To determine whether cholinergic mechanisms contribute to blood pressure regulation, we examined the effects of atropine on pressor responses to phenylephrine and vasoconstrictor responses to the cold pressor test (CPT) and lower body negative pressure (LBNP) in 16 healthy subjects. Heart rate, blood pressure and cardiac index were significantly increased, and central venous pressure (CVP) was significantly decreased after atropine (0.04mg/kg). After atropine, pressor responses to phenylephrine at doses of 20, 40 and 80 micrograms were significantly increased by 101, 112 and 93% (p less than 0.001); however, atropine attenuated pressor responses to CPT (p less than 0.001) and forearm vasoconstrictor responses to LBNP. In 6 propranolol-treated subjects, atropine also augmented pressor responses to phenylephrine but attenuated pressor responses to CPT. These results suggest that atropine augments the pressor response to an alpha-agonist, which may be partly explained by inhibition of compensatory vascular responses mediated by cholinergic mechanisms.

Regional vascular effects of serotonin and ketanserin in young, healthy subjects

The local hemodynamic effects of serotonin (5-hydroxytryptamine; 5-HT) and the selective 5-HT2 antagonist ketanserin were investigated in the forearm of 20 healthy volunteers. Single doses of 5-HT (0.1-80 ng/kg/min) and ketanserin (5-125 ng/kg/min) were administered intra-arterially. The relative alpha 1-adrenergic receptor and 5-HT2 blocking potencies of ketanserin were investigated using intra-arterial infusions of cumulative doses of methoxamine (0.1, 0.3, and 0.5 microgram/kg/min), tyramine (0.25, 0.50, and 1.25 microgram/kg/min), and 5-HT (10, 30, and 80 ng/kg/min) together with a low dose (5 ng/kg/min) and a high dose (50 ng/kg/min) of ketanserin. Forearm blood flow was measured by venous occlusion plethysmography. Heart rate and intra-arterial blood pressure were recorded semicontinuously. Intra-arterial infusion of 5-HT induced an initial transient vasodilatation, followed by a steady vasodilatation for the low doses of 5-HT (0.1-10 ng/kg/min; p less than 0.05). A steady vasoconstriction was only obtained at the highest dose of 5-HT. Ketanserin induced a dose-dependent increase in forearm blood flow from 15 ng/kg/min (p less than 0.05) onward. The vasodilatation induced by 5-HT (1 ng/kg/min) was significantly enhanced by ketanserin (125 ng/kg/min; p less than 0.05), whereas the vasoconstriction elicited by 5-HT (80 ng/kg/min) was reversed by ketanserin (50 ng/kg/min; p less than 0.05), thus confirming that 5-HT2 receptors were stimulated by 5-HT.(ABSTRACT TRUNCATED AT 250 WORDS)

Stress-induced activation of the sympathetic nervous system

Discrepancies between perceptions of internal or external circumstances and innate or acquired expectations lead to patterned stress responses involving several homeostatic systems, of which the sympathoadrenomedullary system (SAMS) is one. Severe, generalized threats such as hypoglycaemia, hypoxia, haemorrhage, circulatory collapse, and fight/flight situations elicit generalized SAMS activation, including cardiac stimulation, splanchnic, cutaneous, and renal vasoconstriction, and usually preserved skeletal muscle blood flow. Patterned sympathetic neural responses, resulting in redistribution of blood volume or changes in glandular activity, occur during orthostasis, exercise, altered environmental temperature, the postprandial state, and performance of attention-requiring tasks. In all these situations, SAMS activity is co-ordinated with that of the parasympathetic nervous system, the pituitary-adrenocortical system, and probably several neuropeptide systems. Although acute stress-induced SAMS activation can be a health hazard, the role of chronically repeated, stress-induced SAMS activation in the development of cardiovascular disease remains unclear. Benzodiazepines, beta-adrenoceptor blockers, and alpha 2-adrenoceptor agonists can attenuate effects of stress-induced SAMS activation, but pressor responses often are maintained.

The hemodynamic effects of sympathetic stimulation combined with parasympathetic blockade in man

To define the effects of circulating norepinephrine and epinephrine on cardiac function and to determine whether left ventricular function is influenced by parasympathetic mechanisms during catecholamine stimulation, hemodynamic changes were investigated in healthy young human subjects who were supine and awake during infusion of intravenous norepinephrine alone (125 ng/kg/min) (n = 6), norepinephrine (125 ng/kg/min) plus epinephrine (50 ng/kg/min) (n = 6), and norepinephrine plus epinephrine plus parasympathetic blockade induced by atropine (2 mg intravenously) (n = 5). Ejection fraction and changes in cardiac volumes were measured by radionuclide ventriculography. During the infusion of norepinephrine plus epinephrine, plasma norepinephrine increased from 358 +/- 35 to 1782 +/- 123 pg/ml (mean +/- SE) and plasma epinephrine increased from 31 +/- 5 to 355 +/- 90 pg/ml (both p less than .01 vs baseline). These increases in plasma catecholamines were associated with increases in the heart rate (58 +/- 3 to 67 +/- 2 beats/min, p = NS), systolic blood pressure (113 +/- 3 to 140 +/- 6 mm Hg, p less than .01), ejection fraction (0.64 +/- 0.02 to 0.72 +/- 0.02 ejection fraction units, p less than .01), stroke volume (+41 +/- 5%, p less than .01), and cardiac output (+54 +/- 8%, p less than .01), and a decrease in systemic vascular resistance (-31 +/- 3%, p less than .01).(ABSTRACT TRUNCATED AT 250 WORDS)

Carotid sinus hypersensitivity: evaluation of the vasodepressor component

The basis of the vasodepressor response in patients with carotid sinus hypersensitivity (CSH) is unknown, and prevention of recurrent vasodepressor-induced hypotension in these patients has not been possible. In this study we assessed the effectiveness of atrioventricular sequential pacing and pharmacologic interventions in the prevention of carotid sinus massage (CSM)-induced vasodepressor responses in eight patients with CSH. Maintenance of constant heart rate (80 beats/min) and atrioventricular synchrony (atrioventricular interval 150 msec) with sequential pacing did not significantly alter mean CSM-induced fall in systolic pressure (CSM control, -60 +/- 12 mm Hg vs CSM with atrioventricular sequential pacing, -48 +/- 19 mm Hg). Similarly, neither pharmacologic muscarinic blockade nor combined muscarinic and beta-adrenergic blockade significantly attenuated CSM-induced fall in systolic pressure (CSM with atropine, -43 +/- 16 mm Hg; CSM with atropine plus propranolol, -47 +/- 18 mm Hg; both p = NS vs atrioventricular sequential pacing alone). On the other hand, intravenous norepinephrine and oral ephedrine blunted the CSM-induced drop in systolic pressure (CSM with norepinephrine, -19 +/- 12 mm Hg; CSM with ephedrine, -21 +/- 11 mm Hg; both p less than .01 vs atrioventricular sequential pacing alone). Thus, vasodepressor responses were not prevented by control of heart rate, maintenance of atrioventricular synchrony, pharmacologic muscarinic blockade, or combined muscarinic and beta-adrenergic blockade, but were attenuated by drugs believed to be predominantly alpha-adrenergic agonists. Consequently, atrioventricular sequential pacing alone may be inadequate to prevent hypotension in patients with pronounced vasodepressor responses, whereas administration of vasoconstrictors such as ephedrine may diminish symptoms.