Effects of hypercapnea and of hypercapnea in combination with hypoxia on midbrain-induced cardiac dysrhythmias

Stimulation of the midbrain during acute combined arterial hypoxia and hypercapnea produces serious cardiac dysrhythmias which are not evoked when stimulation is elicited either with normal arterial blood gas tensions or with isolated mild hypercapnea. The cardiac dysrhythmias are mediated by both enhanced sympathetic and parasympathetic efferent discharge. The results support the concept that increased autonomic activity in combination with acute arterial hypoxia and hypercapnea contribute significantly to the exhibition of serious cardiac rhythm disturbances. Acute hypoxia appears to be the major determinant of such dysrhythmias.     

Neuroexcitatory effects of digoxin in the cat

The effect of intravenous injections of digoxin (20 mug/kg every 15 minutes) on spontaneously occurring activity in autonomic efferent nerves, motor nerves, afferent nerves, electrocardiogram and on arterial blood pressure was evaluated in chloralose-anesthetized cats. Administration of digoxin enhanced neural activity in pre- and postganglionic cardiac synpathetic nerves and this enhancement occurred near the time the disturbances in ventricular rhym were noted. Neural activity continued to increase during ventricular tachycardia and maximum enhancement was observed just proir to ventricular fibrillation. Similar results were observed when digoxin was administered to animals in which neural activity was recorded from preganglionic splanchnic and superior cervical nerves. Digoxin administration also increased discharge frequency from vagus (efferent fibers), phrenic and carotid sinus nerves. Denervation of cardiovascular reflexogenic areas prevented the increased discharge in vagus nerves, reduced it in phrenic nerves, but did not affect nerve discharge in sympathetic nerves. These results suggest that digoxin-induced hyperactivity in synpathetic nerves was related to a central nervous system effect of the drug, whereas the mechanism for the digoxin-induced hyperactivity in vagus nerves involved a peripheral reflex effect of the drug. Both sites were involved in the digoxin-induced hyperactivity in phrenic nerves. Enhancement of cardiac sympathetic nerve activity appeared to be responsible for the ventricular arrhythmias provoked by digoxin as 1) a temporal relationship was observed between augmented nerve activity and arrhythmia development, 2) a centrally acting sympathetic nervous system depressant drug, clonidine, converted the ventricular arrhythmia to normal rhythm, and 3) removal of sympathetic influence to the heart by spinal cord transection decreased the sensitivity of the heart to the arrhythmogenic effect of digoxin. These results suggest that digoxin partially responsible for its cardiotoxic effects.     

Alternate patterns of ventricular activation during supraventricular bigeminy

Several investigators have previously noted that in the presence of bigeminal atrial extrasystoles, the premature beats may exhibit an alternate pattern of ventricular excitation either in the form of alternating left and right bundle-branch block, or alternating right bundle-branch block and normal intraventricular conduction. However, the association of alternating intraventricular conduction with other types of supraventricular bigeminy has rarely been documented. In this report we present five diverse forms of supraventricular bigeminy exhibiting the phenomenon of alternating ventricular excitation on the early beats. Our findings suggest that the exact mechanism of supraventricular bigeminy is irrelevant in terms of subsequent ventricular events. Practically any type of supraventricular bigeminy may result in an alternate pattern of ventricular activation.     

Growth hormone release of interleukin-1 alpha, interferon-gamma and interleukin-4 from murine splenocytes stimulated with staphylococcal protein A, toxic shock syndrome toxin-1 and streptococcal lysin S

1. The role of the renin-angiotensin system in long-term control of sympathetic activity and arterial pressure is reviewed. 2. There is evidence that favours a necessary role for the sympathetic nervous system in long-term arterial pressure regulation. First, appropriate changes in sympathetic activity appear to be produced in response to chronic changes in blood volume or blood pressure. Second, prevention of the normal homeostatic decrease in sympathetic activity in response to an increase in sodium intake produces hypertension. 3. Long-term changes in sympathetic activity cannot be mediated by the baroreceptor reflex, because it adapts to sustained changes in pressure. Therefore, an hypothesis is presented that evokes a key role for angiotensin II (AngII) in determining the chronic level of sympathetic activity. The key feature of this model is that the role of AngII is non-adaptive: chronic changes in extracellular fluid volume produce sustained reciprocal changes in AngII, and long-term increases in AngII produce sustained increases in sympathetic activity. 4. Evidence is reviewed that suggests that a lack of the normal suppression in AngII and/or sympathetic activity in response to an increase in sodium intake produces salt-sensitive hypertension.     

Reflex control of cardiac sympathetic nerve activity in anesthetized rats

Reflex control of sympathetic outflow to the heart was evaluated by recording the efferent discharges of the interior cardiac sympathetic nerves in anesthetized rats. The reflex responses of inferior cardiac sympathetic nerve activity (ICNA) to arterial baroreceptor loading by phenylephrine and to arterial/atrial baroreceptor unloading by hemorrhagic hypotension were compared with those of renal sympathetic nerve activity (RNA) and adrenal sympathetic nerve activity (ANA). The reflex decrease in ICNA to the phenylephrine-induced graded increase in arterial blood pressure was smaller than that of RNA or ANA. Thus ICNA is less sensitive to arterial baroreceptor stimulation. Hemorrhage produced a volume-dependent decrease in ICNA. The response was significantly smaller than that in RNA and was directionally opposite to that in ANA. Cervical vagotomy but not sinoaortic denervation abolished the hemorrhage-induced ICNA response, suggesting an important role of vagal pathways. These findings demonstrate that the reflex responses of sympathetic outflow to the heart were quantitively and qualitatively different from those to the kidney and the adrenal gland, indicating the regional control of sympathetic nerve activity in the regulation of cardiovascular functions.     

Baroreflex impairment by low sodium diet in mild or moderate essential hypertension

Low sodium intake is the most widely used nonpharmacological approach to the treatment of hypertension. Although nonpharmacological treatment is by definition regarded as safe, the suggestion has been made that low sodium intake is not totally devoid of inconveniences, and animal data have shown it to be accompanied by an impairment of reflex blood pressure control and homeostasis. However, no data exist on this issue in humans. In mild essential hypertensive patients (age, 34.1+/-3.3 years [mean+/-SEM]), we measured beat-to-beat arterial blood pressure (finger photoplethysmographic device), heart rate (electrocardiogram), and efferent postganglionic muscle sympathetic nerve activity (microneurography) at rest and during baroreceptor stimulation and deactivation, induced by stepwise intravenous infusions of phenylephrine and nitroprusside, respectively. Measurements were performed at the end of three dietary periods, ie, after 8 days of regular sodium intake (210 mmol NaCl/d), low sodium intake (20 mmol NaCl/d) with unchanged potassium intake, and again regular sodium intake. Compared with the initial regular sodium diet, low sodium intake reduced urinary sodium excretion, whereas urinary potassium excretion was unchanged. Systolic blood pressure was significantly (P<.05), although slightly, reduced, whereas diastolic blood pressure was unaffected. Muscle sympathetic nerve activity was increased by 23.1+/-5.2% (P<.05). The increase was accompanied by a clear-cut impairment of the baroreceptor ability to modulate muscle sympathetic nerve activity, ie, by a 43.9+/-5.7% (P<.01) reduction in the sensitivity of the baroreceptor-muscle sympathetic nerve activity reflex compared with the control condition. Baroreceptor modulation of heart rate was also impaired, although to a smaller and less consistent extent. When regular sodium intake was restored, all the above-mentioned parameters and baroreflex responses returned to the values observed at the initial regular sodium diet. These data raise evidence that in humans sodium restriction may impair the arterial baroreflex. This may be responsible for the sympathetic activation occurring in this condition and for the impairment of blood pressure homeostasis.     

Central nervous system control of cardiac rhythm

Stimulation of sites in the midbrain reticular formation and in the posterior hypothalamus of the cat resulted in a large to modest rise of arterial pressure and the induction of cardiac dysrhythmias. Most frequently, these arrhythmias developed upon cessation of brain stem stimulation but also occurred during the stimulus period in 5 of 23 cats studied. The arrhythmias disappeared upon cooling and reappeared upon rewarming the vagus nerves. The ventricular dysrhythmias also were abolished by methylscopolamine, by bilateral vagatomy, or by extirpation of the stellate ganglia. Simultaneous stimulation of both distal end of the cut right vagus nerve and the decentralized right stellate ganglion caused arrhythmias similar to those observed after diencephalic stimulation. These data are interpreted to indicate that the cardiac arrhythmias evoked by brain stem stimulation result from the interplay of both sympathetic and parasympathetic influences on the heart. The response patterns of a population of medullary neurons activated by carotid sinus nerve stimulation were modified by condition stimuli to posterior hypothalamic sites. From studies on unit activity of brain stem areas known to participate in cardiovascular adjustment, a schema is proposed of hypothalamic-medulla interaction as a central mechanism that may account for the development of ventricular arrhythmias.     

Neurally mediated syncope: a review of cardiac and arterial receptors

This article reviews the basic physiology of the reflexogenic areas of the heart and the mechano- and baroreceptors that regulate cardiovascular and autonomic homeostasis, all of which contribute to our understanding of the pathogenesis of neurally mediated syncope. The mechanisms of neurally mediated syncope may involve excessive activation of ventricular receptors that trigger severe hypotension and bradycardia. Thus, neurally mediated syncope may be the clinical expression of the Bezold-Jarisch reflex, which occurs in situations of increased sympathetic activity, perhaps as a result of heightened cardiac receptor sensitivity. The arterial baroreceptors exert a ubiquitous influence on the heart and circulation, and serve primarily to buffer transient changes in arterial pressure by transmitting sensory information regarding their stretch to the central nervous system. This information, in conjunction with cardiac receptor input, elicits alterations in neural efferent output from sympathetic and parasympathetic fibers to provide subtle, continuous regulation of beat-to-beat cardiovascular hemodynamics to an array of physiologic and psychological stressors.     

Baroreceptor effects on renal and adrenal nerve activity

Spontaneous efferent discharges were recorded from nerve filaments dissected from adrenal and renal nerve bundles in the rabbit. Raising of the systemic blood pressure or stimulation of the depressor nerve caused a decrease in discharge rate in these nerve filaments. Portal vein occlusion or elevation of mesenteric venous pressure caused a depression of activity in these nerves. It is suggested that adrenal and renal sympathetic nerve cells receive inputs from baroreceptors in the systemic arterial system and from mechanoreceptors in the portal and mesenteric veins that cause reflex inhibition of activity in these nerve cells.     

Concealed mechanical bradycardia: an indication for permanent pacemaker implantation

We report a 51-year-old man with severe ischemic cardiomyopathy and heart failure in whom incessant bigeminal ventricular ectopy failed to generate a detectable arterial pressure. This created a mechanical bradycardia despite an adequate electrical heart rate. Dual chamber pacing increased the effective heart rate and allowed discontinuation of an intraaortic balloon pump from which the patient could not otherwise be weaned.     

Interaction of cardiopulmonary and somatic reflexes in humans

Activation of cardiopulmonary receptors with vagal afferents results predominantly in reflex inhibition of efferent sympathetic activity, whereas activation of somatic receptors reflexly increases sympathetic activity to the heart and circulation. Previous studies in experimental animals indicate that there is an important interaction between these excitatory and inhibitory reflexes in the control of the renal circulation. The purpose of this study was to determine whether there is a similar interaction between somatic and cardiopulmonary reflexes in humans. The activity of the cardiopulmonary receptors was altered (reduced) with lower body negative pressure (-5 mm Hg), which causes a decrease in cardiac filling pressure and a small reflex increase in forearm vascular resistance without accompanying changes in arterial pressure. Activation of somatic receptors by isometric handgrip for 2 min at 10 and 20% of maximum voluntary contraction resulted in reflex vasoconstriction in the nonexercising arm. Lower body negative pressure at -5 mm Hg produced a threefold augmentation in the forearm vasoconstrictor response to isometric handgrip in the nonexercising arm. This increase in resistance was significantly greater (P < 0.05) than the algebraic sum of the increases in resistance resulting from lower body suction alone plus isometric handgrip alone. Furthermore, it occurred despite a greater rise in arterial pressure, which would be expected to decrease forearm vascular resistance through activation of arterial baroreceptors and through passive dilatation of forearm vessels. Thus, removal of the inhibitory influence of cardiopulmonary receptors by pooling blood in the lower extremities enhances the somatic reflex. These data suggest an interaction between cardiopulmonary and somatic reflexes in the control of forearm vascular resistance in man.     

Autonomic control of asystolic vasovagal syncope

A 30 year old woman with a lifelong history of severe, recurrent, vasovagal syncope became asystolic for 30 seconds after 37 minutes of 60 degrees head-up tilt. During early tilt, sympathetic activity, heart rate, left ventricular contractility, and cardiac output increased. Mean blood pressure was initially maintained. Presyncope was associated with maximal contractility and bradycardia despite sustained sympathetic activity. Subsequently, asystole occurred associated with complete withdrawal of muscle nerve sympathetic activity. In asystolic vasovagal reactions, presyncope may be triggered by increased left ventricular contractility and is associated with increased levels of parasympathetic and sympathetic activity. Asystole and peripheral vasodilatation may be caused by sudden and complete withdrawal of the increased sympathetic activity.     

Salt intake, blood pressure, and cardiovascular structure

Epidemiologic data revealed that a low sodium intake might have a favorable influence on blood pressure throughout an individual's lifetime. Sodium restriction was reported to lead to a modest fall in blood pressure in some studies, although a few groups of hypertensive patients experienced a rise in blood pressure. Left ventricular hypertrophy has been demonstrated to be related to cardiovascular morbidity and mortality independent of other risk factors. Dietary salt intake participates in the hypertrophic process independent of other determinants. Thus, 24-hour urinary sodium excretion has been reported to correlate with left ventricular mass independent of levels of arterial pressure. Three different mechanisms may link dietary salt intake to myocardial hypertrophy: the renin-angiotensin-aldosterone system, the sympathetic nervous system, and fluid volume homeostasis. Whether salt restriction reduces cardiovascular structural damage independent of arterial pressure has not been determined.     

A comparison of the effects of propofol and sevoflurane on the systemic toxicity of intravenous bupivacaine in rats

We compared the effects of propofol and sevoflurane on bupivacaine-induced central nervous system and cardiovascular toxicity in rats. Thirty-four male Sprague-Dawley rats were anesthetized with 70% N2O/30% O2 plus the 50% effective dose (ED50) of propofol (propofol group, n = 12); 70% N2O/30% O2 plus ED50 of sevoflurane (sevoflurane group, n = 11); or 70% N2O/30% O2 (control group, n = 11). Bupivacaine was infused at a constant rate of 2 mg x kg(-1) x min(-1) while electrocardiogram, electroencephalogram, and invasive arterial pressure were continuously monitored. The cumulative doses of bupivacaine that induced dysrhythmias, seizures, and 50% reduction of heart rate were larger in the propofol and sevoflurane groups than in the control group. The cumulative dose of bupivacaine that induced a 50% reduction in the mean arterial blood pressure was larger in the propofol group than in the sevoflurane and control groups. The margin of safety, assessed by the time between the onset of dysrhythmias and 50% reduction of mean arterial blood pressure, was wider in the propofol group than in the sevoflurane group. We conclude that propofol and sevoflurane attenuate bupivacaine-induced dysrhythmias and seizures and that propofol has a wider margin of safety than sevoflurane. IMPLICATIONS: In anesthetized patients, dysrhythmias may be the only warning sign of intravascular injection of bupivacaine. Because propofol has a wider margin of safety than sevoflurane, life-threatening cardiovascular depression may be prevented by stopping the injection of bupivacaine at the onset of dysrhythmias during propofol anesthesia.     

Contribution of tonic chemoreflex activation to sympathetic activity and blood pressure in patients with obstructive sleep apnea

BACKGROUND: Muscle sympathetic nerve activity (MSNA) is increased in patients with obstructive sleep apnea (OSA). We tested the hypothesis that tonic activation of excitatory chemoreceptor afferents contributes to the elevated sympathetic activity in OSA. METHODS AND RESULTS: Using a double-blind, randomized, vehicle-controlled design, we examined the effects of chemoreflex deactivation (by comparing effects of breathing 100% oxygen for 15 minutes with effects of breathing room air for 15 minutes) on MSNA, heart rate, blood pressure, and minute ventilation in 14 untreated patients with OSA and in 12 normal subjects matched for age and body mass index. All control subjects underwent overnight polysomnography to exclude the existence of occult OSA. Baseline MSNA was markedly elevated in the patients with OSA compared with the control subjects (44+/-4 versus 30+/-3 bursts per minute; P=.01). In both control subjects and patients with OSA, heart rate decreased during administration of 100% oxygen but did not change during administration of room air. By contrast, both MSNA (P=.008) and mean arterial pressure (P=.02) were significantly reduced during chemoreflex deactivation by 100% oxygen only in patients with OSA but not in control subjects. CONCLUSIONS: Tonic activation of excitatory chemoreflex afferents may contribute to increased efferent sympathetic activity to muscle circulation in patients with OSA.     

A note on serological interpretations

The patterns of regional changes of sympathetic efferent activity evoked by thermal stimulation of the spinal cord and by arterial and primary tissue hypoxia were investigated in decerebrated, anesthetized and immobilized rabbits. Decerebration was performed either at the mid- or infracollicular level. The responses of the decerebrated rabbits evoked by spinal thermal stimulation were the same as those of intact rabbits, i.e., splanchnic and cardiac sympathetic activity increased and cutaneous sympathetic activity decreased during warming, while the reverse response was elicited by cooling. It is concluded that the typical thermoregulatory response pattern of the sympathetic nervous system can be produced also after the loss of hypothalamic integration, i.e., by integrative mechanisms in the lower brain stem and the spinal cord. In contrast, the responses of decerebrated rabbits to arterial and primary tissue hypoxia differed from those of intact rabbits in that they consisted in an overall activation in all investigated sympathetic branches. It is confirmed by this result that suprabulbar integration is essential for the generation of the inhibitory components in the differential sympathetic responses to hypoxia, which typically consist in cutaneous and cardiac sympathetic inhibition with splanchnic activation during arterial hypoxia and in cutaneous sympathetic inhibition with cardiac and splanchnic sympathetic activation during primary tissue hypoxia.     

Postural changes in plasma renin activity and responses to vasoactive drugs in a case of Shy-Drager syndrome

A male aged 47 years with gross autonomic insufficiency as part of the Shy-Drager syndrome is described. He did not sweat normally when warmed, and his circulatory responses to mental arithmetic, the Valsalva manoeuvre, and head-up tilt were abnormal indicating severe sympathetic failure. During head-up tilt there was a rise in plasma renin activity and plasma aldosterone. It is argued that plasma renin activity is not dependent on sympathetic nervous activity and may be mediated by renal baroreceptors. These rises may help sustain the blood pressure in such patients during repeated head-up tilts. Infusions of L-noradrenaline and angiotension produced greater hypertension, and injections of isoprenaline greater hypotension than in controls. Although it is difficult to exclude the possibility that one factor in this may be hypersensitivity of receptors in blood vessel walls, the principal factor is likely to be the absence of those baroreflexes of which the efferent pathways are in the sympathetic nervous system.     

Spontaneous thermoregulatory oscillations in cutaneous efferent sympathetic activity

Patterns of changes in cutaneous efferent sympathetic activity which have previously been shown to occur during experimental manipulation of the temperature of various thermosensitive body sites, have now been shown to accompany spontaneous thermoregulatory activity. That is, under thermoneural conditions, concurrent spontaneous oscillations in skin blood flow and efferent sympathetic activity were observed.     

Reflex relationships between the cervical esophagus and the respiratory system in cats

The present study focused on reflex relationships between the esophagus and the respiratory system in cats, namely the changes in airway tone and pulmonary circulation elicited by mechanical or acid (pH 2) stimulation of esophageal afferents. One-minute of sustained distension of the cervical esophagus increased tracheal pressure (PTr), decreased pulmonary artery pressure (PPA) and to a higher extent pulmonary blood flow (QPA) and lowered arterial blood pressure (Pa). This was associated with significant variations in arterial blood gases (increased PaO2 and decreased PaCO2). Acid stimulation of the cervical esophagus caused a marked increase in PTr and a modest fall in QPA. In both circumstances, cervical bivagotomy abolished PTr changes, whereas the changes in pulmonary hemodynamics but not in Pa were then accentuated. Further cervical sympathectomy suppressed the vascular response. These observations show the existence of reflex influences of esophageal afferents on the control of airway tone and pulmonary vascular resistance. The vagus nerve is the efferent arm of the bronchomotor reflex whereas modulation of the sympathetic control of pulmonary circulation seems to be responsible for the changes in pulmonary hemodynamics.