Influence of respiratory motor neurone activity on human autonomic and haemodynamic rhythms.

Although humans hold great advantages over other species as subjects for biomedical research, they also bring major disadvantages. One is that among the many rhythmic physiological signals that can be recorded, there is no sure way to know which individual change precedes another, or which change represents cause and which represents effect. In an attempt to deal with the inherent complexity of research conducted in intact human subjects, we developed and used a structural equation model to analyse responses of healthy young men to pharmacological changes of arterial pressure and graded inspiratory resistance, before and after vagomimetic atropine. Our model yielded a good fit of the experimental data, with a system weighted R2 of 0.77, and suggested that our treatments exerted both direct and indirect influences on the variables we measured. Thus, infusions of nitroprusside and phenylephrine exerted all of their direct effects by lowering and raising arterial pressure; the changes of R-R intervals, respiratory sinus arrhythmia and arterial pressure fluctuations that these drugs provoked, were indirect consequences of arterial pressure changes. The only direct effect of increased inspiratory resistance was augmentation of arterial pressure fluctuations. These results may provide a new way to disentangle and understand responses of intact human subjects to experimental forcings. The principal new insight we derived from our modelling is that respiratory gating of vagal-cardiac motor neurone firing is nearly maximal at usual levels of arterial pressure and inspiratory motor neurone activity.

Interactions between CO2 chemoreflexes and arterial baroreflexes.

We studied interactions between CO2 chemoreflexes and arterial baroreflexes in 10 supine healthy young men and women. We measured vagal carotid baroreceptor-cardiac reflexes and steady-state fast Fourier transform R-R interval and photoplethysmographic arterial pressure power spectra at three arterial pressure levels (nitroprusside, saline, and phenylephrine infusions) and three end-tidal CO2 levels (3, 4, and 5%, fixed-frequency, large-tidal-volume breathing, CO2 plus O2). Our study supports three principal conclusions. First, although low levels of CO2 chemoreceptor stimulation reduce R-R intervals and R-R interval variability, statistical modeling suggests that this effect is indirect rather than direct and is mediated by reductions of arterial pressure. Second, reductions of R-R intervals during hypocapnia reflect simple shifting of vagally mediated carotid baroreflex responses on the R-R interval axis rather than changes of baroreflex gain, range, or operational point. Third, the influence of CO2 chemoreceptor stimulation on arterial pressure (and, derivatively, on R-R intervals and R-R interval variability) depends critically on baseline arterial pressure levels: chemoreceptor effects are smaller when pressure is low and larger when arterial pressure is high.

Contributions of tidal lung inflation to human R-R interval and arterial pressure fluctuations.

We studied the effects of mechanical lung inflation on respiratory frequency R-R interval and arterial pressure fluctuations in nine healthy young adults undergoing elective orthopedic surgery. We conducted this research to define the contribution of pulmonary and thoracic stretch receptor input to respiratory sinus arrhythmia. We compared fast Fourier transform spectral power during three modes of ventilation: (1) spontaneous, frequency-controlled (0.25 Hz) breathing, (2) intermittent positive pressure ventilation (0.25 Hz, with a tidal volume of 8 ml/kg) and (3) high frequency jet ventilation (5.0 Hz, 2.5 kg/cm2), after sedation and vecuronium paralysis. Mean R-R intervals, arterial pressures and arterial blood gas levels were comparable during all three breathing conditions. Respiratory frequency systolic pressure spectral power was comparable during spontaneous breathing and conventional mechanical ventilation, but was significantly reduced during high frequency jet ventilation (P < 0.05). Respiratory frequency R-R interval spectral power (used as an index of respiratory sinus arrhythmia) declined dramatically with sedation and muscle paralysis (P < 0.05), but was greater during conventional mechanical, than high frequency jet ventilation (P < 0.05). These results suggest that although phasic inputs from pulmonary and thoracic stretch receptors make a statistically significant contribution to respiratory sinus arrhythmia, that contribution is small.

Controlled breathing protocols probe human autonomic cardiovascular rhythms.

The purpose of this study was to determine how breathing protocols requiring varying degrees of control affect cardiovascular dynamics. We measured inspiratory volume, end-tidal CO2, R-R interval, and arterial pressure spectral power in 10 volunteers who followed the following 5 breathing protocols: 1) uncontrolled breathing for 5 min; 2) stepwise frequency breathing (at 0.3, 0.25, 0.2, 0.15, 0.1, and 0.05 Hz for 2 min each); 3) stepwise frequency breathing as above, but with prescribed tidal volumes; 4) random-frequency breathing (approximately 0.5-0.05 Hz) for 6 min; and 5) fixed-frequency breathing (0.25 Hz) for 5 min. During stepwise breathing, R-R interval and arterial pressure spectral power increased as breathing frequency decreased. Control of inspired volume reduced R-R interval spectral power during 0.1 Hz breathing (P < 0.05). Stepwise and random-breathing protocols yielded comparable coherence and transfer functions between respiration and R-R intervals and systolic pressure and R-R intervals. Random- and fixed-frequency breathing reduced end-tidal CO2 modestly (P < 0.05). Our data suggest that stringent tidal volume control attenuates low-frequency R-R interval oscillations and that fixed- and random-rate breathing may decrease CO2 chemoreceptor stimulation. We conclude that autonomic rhythms measured during different breathing protocols have much in common but that a stepwise protocol without stringent control of inspired volume may allow for the most efficient assessment of short-term respiratory-mediated autonomic oscillations.

Vagal and sympathetic mechanisms in patients with orthostatic vasovagal syncope.

BACKGROUND: Autonomic and particularly sympathetic mechanisms play a central role in the pathophysiology of vasovagal syncope. We report direct measurements of muscle sympathetic nerve activity in patients with orthostatic vasovagal syncope. METHODS AND RESULTS: We studied 53 otherwise healthy patients with orthostatic syncope. We measured RR intervals and finger arterial pressures and in 15 patients, peroneal nerve muscle sympathetic activity before and during passive 60 degree head-up tilt, with low-dose intravenous isoproterenol if presyncope did not develop by 15 minutes. We measured baroreflex gain before tilt with regression of RR intervals or sympathetic bursts on systolic or diastolic pressures after sequential injections of nitroprusside and phenylephrine. Orthostatic vasovagal reactions occurred in 21 patients, including 7 microneurography patients. Presyncopal and nonsyncopal patients had similar baseline RR intervals, arterial pressure, and muscle sympathetic nerve activity. Vagal baroreflex responses were significantly impaired at arterial pressures below (but not above) baseline levels in presyncopal patients. Initial responses to tilt were comparable; however, during the final 200 seconds of tilt, presyncopal patients had lower RR intervals and diastolic pressures than nonsyncopal patients and gradual reduction of arterial pressure and sympathetic activity. Frank presyncope began abruptly with precipitous reduction of arterial pressure, disappearance of muscle sympathetic nerve activity, and RR interval lengthening. CONCLUSIONS: Patients with orthostatic vasovagal reactions have impaired vagal baroreflex responses to arterial pressure changes below resting levels but normal initial responses to upright tilt. Subtle vasovagal physiology begins before overt presyncope. The final trigger of human orthostatic vasovagal reactions appears to be the abrupt disappearance of muscle sympathetic nerve activity.

Valsalva's maneuver revisited: a quantitative method yielding insights into human autonomic control.

Seventeen healthy supine subjects performed graded Valsalva maneuvers. In four subjects, transesophageal echographic aortic cross-sectional areas decreased during and increased after straining. During the first seconds of straining, when aortic cross-sectional area was declining and peripheral arterial pressure was rising, peroneal sympathetic muscle neurons were nearly silent. Then, as aortic cross-sectional area and peripheral pressure both declined, sympathetic muscle nerve activity increased, in proportion to the intensity of straining. Poststraining arterial pressure elevations were proportional to preceding increases of sympathetic activity. Sympathetic inhibition after straining persisted much longer than arterial and right atrial pressure elevations. Similarly, R-R intervals changed in parallel with peripheral arterial pressure, until approximately 45 s after the onset of straining, when R-R intervals were greater and arterial pressures were smaller than prestraining levels. Our conclusions are as follows: opposing changes of carotid and aortic baroreceptor inputs reduce sympathetic muscle and increase vagal cardiac motor neuronal firing; parallel changes of barorsensory inputs provoke reciprocal changes of sympathetic and direct changes of vagal firing; and pressure transients lasting only seconds reset arterial pressure-sympathetic and -vagal response relations.

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.

Spaceflight alters autonomic regulation of arterial pressure in humans.

Spaceflight is associated with decreased orthostatic tolerance after landing. Short-duration spaceflight (4-5 days) impairs one neural mechanism: the carotid baroreceptor-cardiac reflex. To understand the effects of longer-duration spaceflight on baroreflex function, we measured R-R interval power spectra, antecubital vein plasma catecholamine levels, carotid baroreceptor-cardiac reflex responses, responses to Valsalva maneuvers, and orthostatic tolerance in 16 astronauts before and after shuttle missions lasting 8-14 days. We found the following changes between preflight and landing day: 1) orthostatic tolerance decreased; 2) R-R interval spectral power in the 0.05 to 0.15-Hz band increased; 3) plasma norepinephrine and epinephrine levels increased; 4) the slope, range, and operational point of the carotid baroreceptor cardiac reflex response decreased; and 5) blood pressure and heart rate responses to Valsalva maneuvers were altered. Autonomic changes persisted for several days after landing. These results provide further evidence of functionally relevant reductions in parasympathetic and increases in sympathetic influences on arterial pressure control after spaceflight.

Human autonomic rhythms: vagal cardiac mechanisms in tetraplegic subjects.

1. We studied eight young men (age range: 20-37 years) with chronic, clinically complete high cervical spinal cord injuries and ten age-matched healthy men to determine how interruption of connections between the central nervous system and spinal sympathetic motoneurones affects autonomic cardiovascular control. 2. Baseline diastolic pressures and R-R intervals (heart periods) were similar in the two groups. Slopes of R-R interval responses to brief neck pressure changes were significantly lower in tetraplegic than in healthy subjects, but slopes of R-R interval responses to steady-state arterial pressure reductions and increases were comparable. Plasma noradrenaline levels did not change significantly during steady-state arterial pressure reductions in tetraplegic patients, but rose sharply in healthy subjects. The range of arterial pressure and R-R interval responses to vasoactive drugs (nitroprusside and phenylephrine) was significantly greater in tetraplegic than healthy subjects. 3. Resting R-R interval spectral power at respiratory and low frequencies was similar in the two groups. During infusions of vasoactive drugs, low-frequency R-R interval spectral power was directly proportional to arterial pressure in tetraplegic patients, but was unrelated to arterial pressure in healthy subjects. Vagolytic doses of atropine nearly abolished both low- and respiratory-frequency R-R interval spectral power in both groups. 4. Our conclusions are as follows. First, since tetraplegic patients have significant levels of low-frequency arterial pressure and R-R interval spectral power, human Mayer arterial pressure waves may result from mechanisms that do not involve stimulation of spinal sympathetic motoneurones by brainstem neurones. Second, since in tetraplegic patients, low-frequency R-R interval spectral power is proportional to arterial pressure, it is likely to be mediated by a baroreflex mechanism. Third, since low-frequency R-R interval rhythms were nearly abolished by atropine in both tetraplegic and healthy subjects, these rhythms reflect in an important way rhythmic firing of vagal cardiac motoneurones.

Important influence of respiration on human R-R interval power spectra is largely ignored.

Frequency-domain analyses of R-R intervals are used widely to estimate levels of autonomic neural traffic to the human heart. Because respiration modulates autonomic activity, we determined for nine healthy subjects the influence of breathing frequency and tidal volume on R-R interval power spectra (fast-Fourier transform method). We also surveyed published literature to determine current practices in this burgeoning field of scientific inquiry. Supine subjects breathed at rates of 6, 7.5, 10, 15, 17.1, 20, and 24 breaths/min and with nominal tidal volumes of 1,000 and 1,500 ml. R-R interval power at respiratory and low (0.06-0.14 Hz) frequencies declined significantly as breathing frequency increased. R-R interval power at respiratory frequencies was significantly greater at a tidal volume of 1,500 than 1,000 ml. Neither breathing frequency nor tidal volume influenced average R-R intervals significantly. Our review of studies reporting human R-R interval power spectra showed that 51% of the studies controlled respiratory rate, 11% controlled tidal volume, and 11% controlled both respiratory rate and tidal volume. The major implications of our analyses are that breathing parameters strongly influence low-frequency as well as respiratory frequency R-R interval power spectra and that this influence is largely ignored in published research.

Influence of cigarette smoking on human autonomic function.

BACKGROUND: Although cigarette smoking is known to lead to widespread augmentation of sympathetic nervous system activity, little is known about the effects of smoking on directly measured human sympathetic activity and its reflex control. METHODS AND RESULTS: We studied the acute effects of smoking two research-grade cigarettes on muscle sympathetic nerve activity and on arterial baroreflex-mediated changes of sympathetic and vagal neural cardiovascular outflows in eight healthy habitual smokers. Measurements were made during frequency-controlled breathing, graded Valsalva maneuvers, and carotid baroreceptor stimulation with ramped sequences of neck pressure and suction. Smoking provoked the following changes: Arterial pressure increased significantly, and RR intervals, RR interval spectral power at the respiratory frequency, and muscle sympathetic nerve activity decreased. Plasma nicotine levels increased significantly, but plasma epinephrine, norepinephrine, and neuropeptide Y levels did not change. Peak sympathetic nerve activity during and systolic pressure overshoots after Valsalva straining increased significantly in proportion to increases of plasma nicotine levels. The average carotid baroreceptor-cardiac reflex relation shifted rightward and downward on arterial pressure and RR interval axes; average gain, operational point, and response range did not change. CONCLUSIONS: In habitual smokers, smoking acutely reduces baseline levels of vagal-cardiac nerve activity and completely resets vagally mediated arterial baroreceptor-cardiac reflex responses. Smoking also reduces muscle sympathetic nerve activity but augments increases of sympathetic activity triggered by brief arterial pressure reductions. This pattern of autonomic changes is likely to influence smokers' responses to acute arterial pressure reductions importantly.

Influence of lidocaine on human muscle sympathetic nerve activity during programmed electrical stimulation and ventricular tachycardia.

Lidocaine directly affects conduction and refractoriness of ventricular myocardium, and may also indirectly affect these electrophysiologic properties by inhibition of cardiac sympathetic nerve traffic. Both effects may play important roles in preventing ventricular arrhythmias in humans. To determine if lidocaine has a direct effect on sympathetic nerve activity, the effects of a 100 mg lidocaine bolus followed by a 2 mg/min infusion of lidocaine on muscle sympathetic nerve activity was assessed in seven patients during programmed ventricular stimulation with single extrastimuli (premature ventricular contractions [PVCs]) in sinus rhythm, and in seven patients during induced hemodynamically stable monomorphic ventricular tachycardia. During single extrastimuli, the mean (+/- SEM) area of PVC-associated bursts of sympathetic nerve activity was unaffected by lidocaine (1101 +/- 16 units pre-lidocaine versus 1075 +/- 19 units following lidocaine; p = 0.30). Likewise, the transient decrease in blood pressure with induced PVCs was similar before and after lidocaine infusion (p = 0.46). In seven patients with induced monomorphic ventricular tachycardia, tachycardia cycle length did not change after the lidocaine bolus (393 +/- 18 versus 399 +/- 17 msec; p = 0.34) but increased during lidocaine maintenance infusion (428 +/- 17 msec; p = 0.01). After induction of ventricular tachycardia, systolic pressure decreased from 150 +/- 6 to 117 +/- 9 mm Hg at 1 minute of tachycardia, to 109 +/- 6 mm Hg during the lidocaine bolus, and rebounded to 126 +/- 8 mm Hg during the lidocaine maintenance infusion (p = 0.04, bolus versus infusion).(ABSTRACT TRUNCATED AT 250 WORDS)

Sympathetic neural responses to induced ventricular tachycardia.

Although sympathetic mechanisms play a major role in buffering abrupt arterial pressure reductions, including those that occur during tachyarrhythmias, human sympathetic nervous system responses to ventricular tachycardia have not been measured. Muscle sympathetic nerve activity was recorded directly from the peroneal nerve in 16 patients during diagnostic induction of 19 episodes of sustained monomorphic ventricular tachycardia (average rate 189 beats/min, range 130 to 250). Average systolic and diastolic pressures decreased from 149/78 to 61/49 mm Hg by 10 s and increased toward baseline levels to 88/64 mm Hg by 1 min of ventricular tachycardia. Average sympathetic nerve activity increased by 92% at 10 s in direct proportion to arterial pressure reductions and in inverse proportion to ventricular rate and remained 83% above baseline levels at 1 min. The late recovery of arterial pressure during ventricular tachycardia was related significantly to the magnitude of early sympathetic responses. Sympathetic activity tended to lose its discrete bursting pattern during ventricular tachycardia, and power spectral analysis showed that the large sympathetic peaks at the heart rate frequency present during sinus rhythm are absent during ventricular tachycardia. This study is the first to delineate human sympathetic nervous system responses to ventricular tachycardia. The results suggest that in the patients studied, large early sympathetic surges differed from those that occur during sinus rhythm and contributed to hemodynamic stability during ventricular tachycardia.

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.

Benzyl alcohol interference from heparin lock flush solutions in a high pressure liquid chromatographic procedure for mezlocillin.

During the course of a pharmacokinetic study of the antibiotic mezlocillin, we observed an interfering peak in the high pressure liquid chromatographic analytical procedure that was identified as benzyl alcohol. The benzyl alcohol interferent was traced to a preservative in heparin and saline solutions used to flush heparin locks and indicated that the heparin lock purge volume was inadequate to clean the flushing solution. The present study uses this as a model to study the amount of dilution and contamination interference observed in a controlled study where the purge volume was varied for two "real situation" concentrations of benzyl alcohol in the flush solution. It was found that only 0.5 ml of purge must be drawn to avoid significant contamination interference if benzyl alcohol-free saline is used for dilutions. Contamination interference from benzyl alcohol can also be avoided by spectroscopic or chromatographic resolution if the interference is identified and the particular analyte in question can be resolved. The results of this study provide valuable information for any study in which heparin locks are used and especially in procedures where benzyl alcohol may interfere with the method of analysis. If saline containing benzyl alcohol is used for the dilution of heparin solutions, 1.0 ml of purge must be drawn.

Automated solid-phase extraction and high-performance liquid chromatographic determination of ranitidine from urine, plasma and peritoneal dialysate.

Ranitidine is an H2-receptor antagonist primarily used to treat peptic ulcer. The present automated solid-phase extraction technique involves sorbent conditioning of a cyano (CN) cartridge with 0.5 ml of methanol and 1.0 ml of extraction buffer (0.005 M phosphate, pH 9). Plasma samples were applied by passing 1.0 ml of plasma through the cartridge and subsequently washing with 2 ml of the extraction buffer. Appropriate larger volumes of dialysate were used to concentrate ranitidine onto the cartridge so that the amount eluted was increased to within detectable limits. Urine samples were deluted with distilled water to decrease the ranitidine concentration to within the range of the standard curve. The high-performance liquid chromatographic method (mobile phase 88-89% of 0.02 M phosphate buffer pH 3 and 11-12% of methanol; Spherisorb phenyl cartridge column, 10 cm X 0.46 cm I.D., 5 micron particle diameter, flow-rate 1.1 ml/min; detection at 228 nm) is sensitive to 2 ng/ml in 1 ml of sample. The internal standard of choice was determined to be n-propionylprocainamide as compared to cimetidine and lidocaine. The method was cost-efficient, rapid and simple due to the automated sample processing. The coefficient of variation on replicate assays was less than 10% over all concentrations studied. Recoveries were between 97 and 110%, and the method was linear over the range 1.90-687.20 with a mean correlation coefficient of 0.999.

Comparative pharmacokinetics of azlocillin and piperacillin in normal adults.

The single-dose pharmacokinetics of azlocillin and piperacillin were compared by using a randomized, crossover design. The concentrations of azlocillin in serum were consistently higher than those of piperacillin throughout an 8-h study. The area under the time-concentration curve of azlocillin was significantly greater than that of piperacillin, and the total body clearance of azlocillin was significantly lower than that of piperacillin.

Evaluation of fluorescence polarization immunoassay for quantitation of serum salicylates.

A fluorescence polarization immunoassay (FPIA) for serum salicylates that has been developed for use with the Abbott TDx analyzer is evaluated with regard to precision, accuracy, and stability of the standard curve. The FPIA method is also compared with a well-established high performance liquid chromatography (HPLC) technique in a clinical laboratory environment. The FPIA demonstrates excellent precision, and the standard curve is sufficiently stable to perform reproducible measurements over a 29-day period without recalibration. Superior accuracy of the FPIA method is indicated for salicylate concentrations between 50 and 800 micrograms/ml by recovery studies and by favorable comparison with the reference method. The performance of the FPIA for salicylate concentrations between 0 and 50 micrograms/ml is somewhat less favorable and should be used with caution in this range. The present method is more appropriate than HPLC for the management of patients receiving chronic high doses of salicylates or in cases of acute salicylate overdose and is also more rapid.