Hydrogen ion concentration is not the sole determinant of muscle metaboreceptor responses in humans.

We examined the effects of exercise conditioning on muscle sympathetic nerve activity (MSNA) during handgrip and posthandgrip circulatory arrest (PHG-CA). Two conditioning stimuli were studied: forearm dominance and bodybuilding. Static handgrip at 30% maximal voluntary contraction followed by PHG-CA led to a rise in MSNA smaller in dominant than in nondominant forearms (99% vs. 222%; P less than 0.02) and in body builders than in normal volunteers (28% vs. 244%; P less than 0.01). Separate 31P NMR experiments showed no effect of dominance on forearm pH but a pH in bodybuilders higher (6.88) than in normal volunteers (6.79; P less than 0.02) during PHG-CA. Our second goal was to determine if factors besides attenuated [H+] contribute to this conditioning effect. If differences in MSNA during exercise were noted at the same pH, then other mechanisms must contribute to the training effect. We measured MSNA during ischemic fatiguing handgrip. No dominance or bodybuilding effect on pH was noted. However, we noted increases in MSNA smaller in dominant than nondominant forearms (212% vs. 322%; P less than 0.02) and in bodybuilders than in normal volunteers (161% vs. 334%; P less than 0.01). In summary, MSNA responses were less during exercise of conditioned limbs. Factors aside from a lessening of muscle acidosis contribute to this effect.

Autonomic pathophysiology in heart failure patients. Sympathetic-cholinergic interrelations.

We conducted this study in an effort to characterize and understand vagal abnormalities in heart failure patients whose sympathetic activity is known. We measured sympathetic (peroneal nerve muscle sympathetic recordings and antecubital vein plasma norepinephrine levels) and vagal (R-R intervals and their standard deviations) activities in eight heart failure patients and eight age-matched healthy volunteers, before and after parasympathomimetic and parasympatholytic intravenous doses of atropine sulfate. At rest, sympathetic and parasympathetic outflows were related reciprocally: heart failure patients had high sympathetic and low parasympathetic outflows, and healthy subjects had low sympathetic and high parasympathetic outflows. Low dose atropine, which is known to increase the activity of central vagal-cardiac motoneurons, significantly increased R-R intervals in healthy subjects, but did not alter R-R intervals in heart failure patients. Thus, our data document reciprocal supranormal sympathetic and subnormal parasympathetic outflows in heart failure patients and suggest that these abnormalities result in part from abnormalities within the central nervous system.

Global right atrial mapping of human atrial flutter: the presence of posteromedial (sinus venosa region) functional block and double potentials : a study in biplane fluoroscopy and intracardiac echocardiography.

BACKGROUND: Previous studies of atrial flutter have found linear block at the crista terminalis; this was thought to predispose the patient to the arrhythmia. More recent observations, however, have demonstrated crista conduction. We sought to characterize the posterior boundary of atrial flutter. METHODS AND RESULTS: Patients with counterclockwise flutter (n=20), clockwise flutter (n=3), or both (n=5) were studied using two 20-pole catheters. Biplane fluoroscopy determined catheter positions. During counterclockwise flutter, craniocaudal activation occurred along the entire lateral and posterior right atrial walls. Septal activation proceeded caudocranially. In all patients, a line of block was seen in the posteromedial (sinus venosa) right atrium; this was manifested by the presence of double potentials where the upward and downward activations collided. Anatomic location was confirmed by intracardiac echocardiography in 9 patients. In patients with clockwise flutter, the line of block and double potentials were seen in the same location during counterclockwise flutter, but the activation sequence around the line of block was reversed. Pacing near the site of double potentials during sinus rhythm excluded a fixed line of block, and premature atrial complexes demonstrated functional block with manifest double potentials. In 2 patients, posterior ectopy organized to subsequently initiate isthmus-dependent atrial flutter. CONCLUSIONS: (1) A functional line of block is seen at the posteromedial (sinus venosa region) right atrium during counterclockwise and clockwise atrial flutter. (2) All lateral wall right atrial activation can be uniform during flutter, without linear block or double potentials in the region of the crista terminalis. (3) Activation at the site of posteromedial right atrial functional block can organize to subsequently initiate isthmus-dependent atrial flutter.

Effects of quinidine on vascular resistance and sympathetic nerve activity in humans.

OBJECTIVES: The purpose of the present study was to test the hypothesis that intravenous quinidine, unlike procainamide, causes direct vasodilation and reflexly mediated increases in sympathetic nerve activity. BACKGROUND: Intravenous quinidine can cause significant hypotension. Animal experiments have suggested that quinidine blocks alpha-receptors and also relaxes vascular smooth muscle by a nonadrenergic mechanism. In a recent study we showed that intravenous procainamide causes peripheral vasodilation, hypotension and inhibition of sympathetic nerve activity in humans. Intraarterial procainamide, however, did not cause vasodilation. METHODS: Postganglionic muscle sympathetic nerve traffic was recorded from the peroneal nerve at the fibular head with tungsten microelectrodes, and forearm blood flow was measured with venous occlusion plethysmography. Central venous pressure was measured directly. The direct effects of quinidine on vascular resistance were determined with brachial artery quinidine infusions and measurement of ipsilateral forearm blood flow. RESULTS: In eight normal subjects intravenous quinidine (8 mg/kg body weight infused for 27 min) decreased mean arterial pressure from 87 +/- 3 (mean +/- SE) to 83 +/- 3 mm Hg, central venous pressure from 6.3 +/- 0.6 to 5.0 +/- 0.7 mm Hg and forearm vascular resistance from 32.2 +/- 5.5 to 25.3 +/- 4.7 U (all p < 0.05). Heart rate increased from 67 +/- 4 to 77 +/- 5 beats/min and muscle sympathetic nerve activity from 288 +/- 70 to 660 +/- 151 U/min (both p < 0.05). In five subjects intravenous nitroprusside that caused similar hemodynamic effects produced similar increases in sympathetic nerve activity. In eight subjects graded infusions of quinidine into the brachial artery (0.37, 0.74 and 1.48 mg/min) produced dose-dependent decreases in ipsilateral forearm vascular resistance and marked attenuation of forearm vasoconstriction caused by the cold pressor test. CONCLUSIONS: These data show that quinidine, unlike procainamide, causes vasodilation directly and, when given intravenously, is associated with baroreflex-mediated increases in sympathetic nerve activity.

Enhancement of sympathetic nerve activity by single premature ventricular beats in humans.

This is the first systematic study of the effects of ventricular premature beats on sympathetic nerve activity in humans. Microneurographic techniques were used to record efferent sympathetic activity from the peroneal nerve, and an intracardiac electrode catheter was used to introduce ventricular premature beats after every 6 to 10 sinus heartbeats. Studies were performed in eight patients, aged 22 to 74 years (mean 57), undergoing cardiac electrophysiologic studies. Three patients did not have apparent heart disease and five had coronary artery disease. During sinus rhythm, 19 to 93% (mean 42%) of heartbeats were followed by a pulse-synchronous burst of sympathetic activity. Provoked ventricular premature beats had obvious effects on this activity. Premature beats with coupling intervals less than 80% of sinus cycle length were consistently followed by a burst of sympathetic activity, and this activity was greater in amplitude, duration and area (all p less than 0.05) than were burst of such activity during sinus rhythm. The magnitude of this burst of activity increased as the coupling interval of the ventricular premature beat decreased (p less than 0.0001). In contrast, postextrasystolic beats were followed by nearly complete neural silence. These effects were seen in all patients regardless of baseline burst incidence and the presence or absence of heart disease. Total nerve activity per 10 heartbeats was 6,520 +/- 770 U during ventricular extrastimulation and 5,720 +/- 440 U during normal sinus rhythm (difference not significant). It is concluded that single ventricular premature beats provoke fluxes of muscle sympathetic nerve activity in humans, comprising surges of sympathetic activity larger than those occurring during sinus rhythm, followed by neural silence.

Utility of a single-stage isoproterenol tilt table test in adults: a randomized comparison with passive head-up tilt.

OBJECTIVES: This study was conducted to develop a time-efficient tilt table test. BACKGROUND: Current protocols of tilt table testing are quite time-consuming. This study was designed to assess the diagnostic value, tolerance and procedural time of a single-stage isoproterenol tilt table protocol. METHODS: A single-stage isoproterenol tilt table test was compared with the passive tilt table test. The study was prospectively designed in a randomized and crossover fashion. RESULTS: The study population consisted of 111 patients with a history of syncope (mean age 55 +/- 20 years). Of the total, 62 patients (56%; 95% confidence interval, 46% to 65%) had a positive vasovagal response during isoproterenol tilt table testing and 35 (32%; 23% to 41%) during passive tilt table testing (p = 0.002). The mean procedural times of the study population were 11.7 +/- 3.6 min and 36.9 +/- 13.3 min for isoproterenol and passive tilt table testing, respectively (p < 0.001). All patients tolerated single-stage isoproterenol testing. In the 23 control subjects (mean age 34 +/- 11 years), the apparent specificities were 91% (72% to 99%) and 83% (61% to 99%) for passive and single-stage tilt table testing, respectively. CONCLUSIONS: The single-stage isoproterenol tilt table test was more effective in inducing a positive vasovagal response in an adult population than the standard passive tilt table test, and it significantly reduced the procedural time. The increase in positive yield was associated with a moderate decrease in apparent specificity. These observations support the conclusion that single-stage tilt table testing could be a reasonable diagnostic option in patients undergoing syncope evaluation.

Distinct hemodynamic profiles in patients with vasovagal syncope: a heterogeneous population.

OBJECTIVE: The objective was to investigate mechanisms of vasovagal syncope by identifying laboratory techniques that characterize cardiovascular profiles in patients with vasovagal syncope. BACKGROUND: The triggering mechanisms of vasovagal syncope are complex. The patient population is likely heterogeneous. We hypothesized that distinct hemodynamic profiles are definable with provocative maneuvers. METHODS: Three groups of subjects were matched for age and gender: 16 patients with a history of syncope and an inducible vasovagal response during passive tilt table testing (70 degrees, 45 min, group I), 16 with a history of syncope, negative passive tilt table testing but positive isoproterenol tilt table testing (0.05 microg/kg per min, 70 degrees, 10 min, group II), and 16 control subjects. Beat-to-beat hemodynamic functions were determined noninvasively by photo-plethysmography and impedance cardiography. RESULTS: At baseline, hemodynamic functions were not different among the three groups (supine). In response to tilt before any symptoms developed, total peripheral resistance decreased 9% +/- 14% in group I from baseline supine to tilt position but increased 27% +/- 18% in group II and 28% +/- 17% in controls (p < 0.001). Responses to isoproterenol were not significantly different between group II and controls in supine position. In response to tilt during isoproterenol infusion before any symptoms developed, total peripheral resistance decreased 24% +/- 20% in group II and increased 20% +/- 48% in controls (p = 0.002). CONCLUSIONS: Group I patients may have impaired ability to increase vascular resistance during orthostatic stress. The inability to overcome isoproterenol-induced vasodilatation during tilt is important in triggering a vasovagal response in group II patients. These data suggest that the population with vasovagal response is heterogeneous. Distinct hemodynamic profiles in response to various provocative maneuvers are definable with noninvasive, continuous monitoring techniques.

Effects of fludrocortisone on sympathetic nerve activity in humans.

Fludrocortisone reduces plasma norepinephrine in healthy humans, but forearm vascular and pressor responses to norepinephrine are potentiated. The effects of fludrocortisone on sympathetic nerve activity in healthy humans are not known. To investigate these effects we evaluated muscle sympathetic nerve activity, heart rate, and arterial pressure in 11 healthy volunteers during three protocols: (1) before and on day 7 of fludrocortisone (0.4 mg/d) treatment with ad libitum diet (n = 6); (2) before and on day 7 of fludrocortisone (0.4 mg/d) or placebo with a 150 mmol/24 h (mEq/24 h) sodium diet (n = 7); and (3) before and on day 2 of fludrocortisone (0.4 mg/d) or placebo with a 150 mmol/24 h (mEq/24 h) sodium diet (n = 4). Placebo did not alter any parameter.(ABSTRACT TRUNCATED AT 250 WORDS)

Reflex control of sympathetic nerve activity in dopamine beta-hydroxylase deficiency.

Patients with autonomic failure secondary to dopamine beta-hydroxylase deficiency lack the enzyme activity necessary for the conversion of dopamine to norepinephrine in sympathetic nerve terminals and the adrenal medulla. These patients have virtually undetectable norepinephrine and epinephrine in plasma and cerebrospinal fluid. The presence of intact sympathetic nerve activity in these patients has been suggested by the enhanced release of dopamine (but not norepinephrine) in response to maneuvers that augment sympathetic outflow in normal subjects. In the present study, we recorded sympathetic nerve traffic by using microneurography in a patient with dopamine beta-hydroxylase deficiency and measured sympathetic neural responses to static exercise, the cold pressor test, and pharmacological alterations of blood pressure. At rest, sympathetic nerve activity was abundant and was modulated in a normal manner by handgrip (+278%), the cold pressor test (+169%), hypotension induced with isoproterenol (+102%), and hypertension induced with phenylephrine (-85%). These results provide the first electrophysiological evidence for intact regulation of sympathetic neural outflow in a patient with dopamine beta-hydroxylase deficiency and suggest that central norepinephrine and epinephrine pathways believed essential for the control of sympathetic neurotransmission in humans may be supplanted by alternative redundant mechanisms.

A test of the "epinephrine hypothesis" in humans.

-According to the "epinephrine hypothesis," circulating epinephrine taken up by sympathetic nerves is coreleased with norepinephrine during sympathetic stimulation and binding of coreleased epinephrine to presynaptic beta-adrenoceptors augments exocytotic release of norepinephrine, contributing to high blood pressure. This study examined whether infusion of a physiologically active amount of epinephrine affects subsequent vascular responses and the estimated rate of entry of norepinephrine into regional venous plasma (norepinephrine spillover). Each of 3 experiments included intravenous infusion of 3H-norepinephrine, measurements of forearm vascular resistance, and intra-arterial infusion of epinephrine (3 ng/min per deciliter forearm volume). In experiment 1, subjects underwent lower body negative pressure (LBNP-25 mm Hg) before and after intra-arterial epinephrine; in experiment 2, LBNP and intra-arterial yohimbine before and after intra-arterial epinephrine; and in experiment 3, intravenous nitroprusside before and after intra-arterial epinephrine. In all subjects, intra-arterial epinephrine produced ipsilateral pallor and decreased forearm vascular resistance. Ipsilateral venous epinephrine increased by 10-fold. Epinephrine did not affect forearm vasoconstrictor responses to LBNP or vasodilator responses to intra-arterial yohimbine or intravenous nitroprusside; did not affect venous norepinephrine levels or norepinephrine spillover during LBNP, yohimbine, LBNP during yohimbine, or nitroprusside; and did not increase venous epinephrine levels during any of these manipulations. Loading of forearm sympathetic terminals with epinephrine therefore does not augment subsequent neurogenic vasoconstriction or norepinephrine release in the human forearm in response to sympathetic stimulation. The findings are inconsistent with the epinephrine hypothesis.

Electrophysiologic characteristics of diverse accessory pathway locations of antidromic reciprocating tachycardia.

This study assessed antidromic reciprocating tachycardia (ART) in patients with paraseptal accessory pathways (APs). Previous clinical experience suggests that paraseptal APs are unable to serve as the anterograde limb during ART. Based on the reentry wavelength concept, we hypothesized that anatomic location of a paraseptal AP may not preclude occurrence of ART. If wavelength criteria were met due to prolonged conduction time retrogradely in the atrioventricular node or anterogradely in the AP, ART may be sustained. All patients who had ART in the electrophysiologic laboratory at our institution (1991 to 1998) were studied. Based on fluoroscopically guided electrophysiologic mapping and radiofrequency ablation, AP location was classified as paraseptal, posterior, or lateral. Conduction time and refractoriness measurements were made for all components of the ART circuit. Of 24 patients with ART, 5 (21%) had ART utilizing a paraseptal AP. Anterograde conduction time through the AP and retrograde atrioventricular nodal conduction time were significantly longer in patients with paraseptal versus lateral pathways. Isoproterenol was required for ART induction in 38% of patients with a posterior AP, 36% with lateral AP location, but not in patients with a paraseptal AP. There were no significant differences in tachycardia cycle length or refractoriness of anterograde and/or retrograde components of the macroreentry circuit between the 3 pathway locations. Thus, ART can occur in patients with a paraseptal AP. Slower anterograde pathway conduction, or retrograde atrioventricular nodal conduction renders the wavelength critical for completion of the antidromic re-entrant circuit.

Use of a transurethral microwave thermotherapeutic device with permanent pacemakers and implantable defibrillators.

OBJECTIVE: To determine whether a device (Urologix Targis system) used for transurethral microwave treatment interferes with sensing, pacing, and arrhythmia detection by permanent pacemakers and implantable cardioverter-defibrillators (ICDs). METHODS: We tested 13 pacemakers in both bipolar and unipolar sensing configurations and 8 ICDs in vitro. Pacemakers and ICDs were programmed to their most sensitive settings. Energy outputs of the microwave device were typical of those used clinically. The probe of the microwave device was anchored 1.2 cm from the pacemaker or ICD being tested. RESULTS: No sensing, pacing, or arrhythmic interactions were noted with any ICD or any pacemaker programmed to the bipolar configuration. One pacemaker (Guidant Vigor 1230) showed intermittent tracking when programmed to the unipolar configuration. CONCLUSIONS: Most patients with permanent pacemakers or ICDs can safely undergo transurethral microwave therapy using the device tested. Pacemakers and ICDs should be programmed to the bipolar configuration (if available) during therapy. The pacemaker or ICD should be interrogated before and after therapy to determine whether programming changes occurred as a result of treatment. However, our findings suggest that this is unlikely.

Sympathetic nerve activity in arm and leg muscles during lower body negative pressure in humans.

Nonhypotensive lower body negative pressure (LBNP) is reported to decrease forearm but not calf blood flow as measured by strain-gauge plethysmography. This suggests that unloading of cardiopulmonary receptors increases sympathetic outflow to arm but not to leg. To test this hypothesis we measured muscle sympathetic nerve activity (MSA) in the arm (radial nerve) and leg (peroneal nerve) simultaneously during LBNP. In eight healthy subjects, we measured heart rate, blood pressure, and radial and peroneal MSA during LBNP at 10 and 20 mmHg. There was no difference between radial and peroneal MSA at rest, and there were successive parallel increases of MSA in both nerves during LBNP at 10 and 20 mmHg. These data indicate that there are nearly identical increases of sympathetic outflow to the arm and leg during mild to moderate degrees of orthostatic stress.

Muscle sympathetic nerve responses to static leg exercise.

Previous studies of muscle sympathetic nerve activity (MSNA) during static exercise have employed predominantly the arms. These studies have revealed striking increases in arm and leg MSNA during static handgrip (SHG) and postexercise circulatory arrest (PECA). The purpose of this study was to examine MSNA during static leg exercise (SLE) at intensities and duration commonly used during SHG followed by PECA. During 2 min of SLE (static knee extension) at 10% of maximal voluntary contraction (MVC; n = 18) in the sitting position, mean arterial pressure and heart rate increased significantly. Surprisingly, MSNA in the contralateral leg did not increase above control levels during SLE but rather decreased (23 +/- 5%; P < 0.05) during the 1st min of SLE at 10% MVC. We compared MSNA responses to SHG and SLE (n = 8) at 30% MVC. SHG and SLE elicited comparable increases (P < 0.05) in arterial pressure and heart rate, but SHG elicited significant increases in MSNA, whereas SLE did not. During PECA after SHG and SLE, mean arterial pressure remained significantly above control. However, MSNA was unchanged during PECA after SLE but was significantly greater than control during PECA after SHG. Because previous studies have indicated differences in MSNA responses to the arm and leg, we measured arm and leg MSNA simultaneously in six subjects during SLE at 20% MVC and PECA. During SLE and PECA, MSNA in the contralateral arm and leg did not differ significantly from each other.(ABSTRACT TRUNCATED AT 250 WORDS)

A signal-averaging technique for the analysis of human muscle sympathetic nerve activity.

We present a signal-averaging technique for analysis of human muscle sympathetic nerve activity (SNA). Nerve traffic was averaged by coupling signal acquisition to electrocardiographic R waves. The amplitude of the averaged waveform was multiplied by the number of R waves sampled to provide a measure of SNA in arbitrary units. This was compared with SNA measured by manual digitization of hard-copy records. In nine volunteers, SNA was increased or decreased with stepwise infusions of nitroprusside or phenylephrine: there were 10 5-min periods of data in each subject. Across all subjects, the correlation between manual and signal-averaged measures of SNA was excellent during both nitroprusside (r = 0.98) and phenylephrine infusions (r = 0.91) and the slopes of the regression lines were near unity. In three periods of data collection, electrical artifacts were added randomly at frequencies of 0.5 and 0.07 Hz during playback of the signal into the computer. Signal-averaged estimates of SNA were unaffected by artifacts. This technique provides reliable observer-independent measures of SNA.

Comparison of muscle sympathetic responses to hemorrhage and lower body negative pressure in humans.

We compared changes in muscle sympathetic nerve activity (SNA) during graded lower body negative pressure (LBNP) and 450 ml of hemorrhage in nine healthy volunteers. During LBNP, central venous pressure (CVP) decreased from 6.1 +/- 0.4 to 4.5 +/- 0.5 (LBNP -5 mmHg), 3.4 +/- 0.6 (LBNP -10 mmHg), and 2.3 +/- 0.6 mmHg (LBNP -15 mmHg), and there were progressive increases in SNA at each level of LBNP. The slope relating percent change in SNA to change in CVP during LBNP (mean +/- SE) was 27 +/- 11%/mmHg. Hemorrhage of 450 ml at a mean rate of 71 +/- 5 ml/min decreased CVP from 6.1 +/- 0.5 to 3.7 +/- 0.5 mmHg and increased SNA by 47 +/- 11%. The increase in SNA during hemorrhage was not significantly different from the increase in SNA predicted by the slope relating percent change in SNA to change in CVP during LBNP. These data show that nonhypotensive hemorrhage causes sympathoexcitation and that sympathetic responses to LBNP and nonhypotensive hemorrhage are similar in humans.

Modulation of human sympathetic periodicity by mild, brief hypoxia and hypercapnia.

We determined the influence of brief mild normocapnic hyperoxia, hypoxia, and hyperoxic hypercapnia on human muscle sympathetic nerve activity and R-R intervals, as quantified by both time- and frequency-domain analyses. We obtained measurements in nine healthy young adult men and women during uncontrolled and frequency (but not tidal volume) controlled breathing. Responses were evaluated with forward selection and backward elimination statistical models, with muscle sympathetic nerve activity as the dependent variable, and power spectral techniques. Hyperoxia and hypoxia did not alter arterial pressure; hypercapnia increased diastolic pressure modestly. Average R-R intervals tended to increase during hyperoxia, and decrease during hypoxia and hypercapnia. During uncontrolled breathing, changes of inspiratory gases exerted only minor effects on muscle sympathetic nerve activity; during controlled breathing, both hypoxia and hypercapnia tended to increase muscle sympathetic nerve activity. Statistical modeling suggested that chemoreceptor stimulation increased muscle sympathetic neural outflows, but that increases of sympathetic traffic were opposed by secondary increases of ventilation. Inspiratory gases modulated the frequency distribution of muscle sympathetic nerve activity strikingly: hypoxia increased sympathetic power at respiratory frequencies and hypercapnia increased sympathetic power at both respiratory and (primarily in one subject) cardiac frequencies. Our data suggest that mild brief hypoxia and hypercapnia increase human muscle sympathetic nerve activity, but that this tendency is opposed by chemoreflex-induced increases of ventilation. Our results suggest also that chemoreceptor activity exerts important influences on the frequency content, as well as the quantity of sympathetic neural outflow.