Transient analysis of cardiopulmonary interactions. II. Systolic events

The etiology of the fall in left ventricular stroke volume (LVSV) and arterial pressure with a negative intrathoracic pressure (NITP) during inspiration is controversial. An increase in LV afterload produced by NITP has been proposed as one explanation but is difficult to evaluate if preload is also altered. To test the hypothesis that a systolic event alone, i.e., a change in LV afterload or contractility, can reduce LVSV during inspiration independent of changes in LV preload, a rapid transient NITP confined to systole was produced by electrocardiogram-triggered phrenic nerve stimulation in eight anesthetized dogs. Intrathoracic descending aortic diameters were measured by sonomicrometry to transduce qualitative changes in aortic transmural pressure. With the airway completely obstructed systolic NITP resulted in a decrease in LVSV (-8.1%, P less than 0.001) but an increase in the systolic anteroposterior (0.54 mm, P less than 0.01) and right-to-left (0.45 mm, P less than 0.01) aortic diameters compared with preceding beat. Similar significant changes were observed with the airway unobstructed. These observations are consistent with an increased afterload imposed on the LV reducing LVSV and egress of blood out of the thorax. Prolonging NITP to include both systole and diastole, a profound fall in LVSV is observed, consistent with the independent influences of systolic and diastolic events combining to diminish LVSV.(ABSTRACT TRUNCATED AT 250 WORDS)     

Superior vena caval blood flow velocities in adults: a Doppler echocardiographic study

Superior vena caval blood flow velocity was measured in 30 normal adults (age 20-65, mean 36 yr). The flow velocities were measured by pulsed Doppler echocardiography, using a Duplex system with the transducer at the right supraclavicular fossa, approximating a 0 degrees Doppler angle. Four distinct flow waveforms were found during each cardiac cycle: A, a small retrograde flow during right atrial contraction (peak flow velocity 12.4 +/- 2.2 cm/s); B, a small antegrade flow during right atrial relaxation (15.7 +/- 5.0 cm/s); S, a large antegrade flow during ventricular systole (35.2 +/- 7.3 cm/s); and D, a large antegrade flow during ventricular diastole (23.2 +/- 3.1 cm/s). The wave duration was inversely related to heart rate. The peak flow velocities of the S and D waves were inversely related to the patients' ages. This study provides recognition of the pattern and range of normality essential to extension of this noninvasive technique to the diagnosis of pathological conditions.     

Stroke volume and cardiac output decrease at termination of obstructive apneas.

Patients with obstructive sleep apnea (OSA) experience repetitive nocturnal oscillations of systemic arterial pressure that occur in association with changes in respiration and changes in sleep state. To investigate cardiac function during the cycle of obstruction (apnea) and resumption of ventilation (recovery), we continuously measured left ventricular stroke volume (LVSV) and mean arterial blood pressure (MAP) during non-rapid-eye-movement sleep in six males with severe OSA (apnea/hypopnea index > or = 30 events/h associated with oxygen saturation < 82%). LVSV was assessed continuously using an ambulatory ventricular function monitor (VEST; Capintec). The apnea-recovery cycle was divided into three phases: 1) early apnea (EA), 2) late apnea (LA), and 3) recovery (Rec). In all subjects recovery was associated with an abrupt decrease in LVSV [54.0 +/- 14.5 (SD) ml] compared with either EA (91.4 +/- 14.7 ml; P < 0.001) or LA (77.1 +/- 15.2 ml; P < 0.005). Although heart rate increased with recovery, the increase was not sufficient to compensate for the decrease in LVSV so that cardiac output (CO) fell (EA: 6,247 +/- 739 ml/min; LA: 5,741 +/- 1,094 ml/min; Rec: 4,601 +/- 1,249 ml/min; EA vs. Rec, P < 0.01; LA vs. Rec, P < 0.025). Recovery was also associated with a significant increase in MAP. We speculate that such abrupt decreases in LVSV and CO at apnea termination, occurring coincident with the nadir of oxygen saturation, may further compromise tissue oxygen delivery.     

Hemodynamic effects of cardiac cycle-specific increases in intrathoracic pressure

Changes in intrathoracic pressure (ITP) can influence cardiac performance by affecting ventricular loading conditions. Because both systemic venous return and factors determining left ventricular (LV) ejection may vary over the cardiac cycle, phasic increases in ITP may differentially affect preload or afterload if delivered at specific points within the cardiac cycle. We studied the hemodynamic effects of cardiac cycle-specific increases in ITP (pulses) delivered by a high-frequency jet ventilator in an acute closed-chested canine model (n = 11), using electromagnetic flow probes to measure biventricular stroke volume. Measurements were taken during a control condition after the induction of acute ventricular failure (AVF) by propranolol hydrochloride and volume infusion. ITP was independently varied without changing lung volume by the inflation of thoracoabdominal binders. Although synchronous pulses had minimal hemodynamic effects in unbound controls, binding pulses timed to occur in early diastole resulted in decreases in LV filling pressure and left ventricular stroke volume (SVlv) (P less than 0.05). In the AVF condition, pulses increased LV performance, evidenced by increases in SVlv (P less than 0.01), despite decreases in LV filling pressure (P less than 0.05). This effect is maximized by binding and by timing the pulses to occur in systole. We conclude that cardiac cycle-specific increases in ITP can significantly affect cardiac performance. These effects appear to be related to the ability of such timed pulses to selectively affect LV preload and afterload.     

Hemodynamic effects of synchronous high-frequency jet ventilation during acute hypovolemia

We studied the effects of synchronous cardiac cycle-specific high-frequency jet ventilation (HFJV) in pentobarbital-anesthetized, splenectomized, closed-chest dogs to test the hypothesis that phasic inspiratory increases in intrathoracic pressure (ITP) selectively timed to specific periods of the cardiac cycle have different hemodynamic effects during both hypovolemia (acute hemorrhage, 20 ml/kg) and neurogenic vasomotor shock (hexamethonium, 10 mg/kg) than those observed during normovolemic control conditions. Ventricular stroke volumes (SV) were measured by electromagnetic flow probes. The influence of changes in venous return (VR) on the subsequent hemodynamic response to synchronous HFJV was analyzed using instantaneous VR curves (M. R. Pinsky, J. Appl. Physiol. 56:765-771, 1984). During hemorrhage the VR curve was shifted leftward with concomitant reductions in apneic SV (15.4 +/- 3.8 to 11.2 +/- 3.6 ml, mean +/- SD), (P less than 0.01) that were accentuated by HFJV (P less than 0.01), except when the phasic inspiratory increases in ITP during HFJV were timed to occur during late diastole (-4% apneic SV, NS). SV was greater with late diastolic pulses than with other timed synchronous ITP pulses during hypovolemia (P less than 0.01). During ganglionic blockade, arterial pressure decreased (139 +/- 14 to 76 +/- 18 Torr, P less than 0.001), but VR was preserved at control levels, and no significant cardiac cycle-specific HFJV effects occurred. We conclude that SV reductions associated with positive-pressure ventilation during acute hypovolemia are minimized by HFJV synchronized to late diastole but that this effect is preload dependent.     

Reduced stroke volume related to pleural pressure in obstructive sleep apnea

Left ventricular stroke volume (LVSV) falls during obstructed inspiration in animals and normal human subjects through mechanisms that may be closely related to pleural pressure. In this study we postulated that a similar reduction in LVSV should occur in patients with obstructive sleep apnea (OSA). Daytime polysomnograms were performed in 10 patients with OSA. A noninvasive electrical impedance method was used to determine LVSV. Pleural pressure was measured by esophageal balloon. In comparison with awake values, during OSA we found reductions in LVSV, cardiac output, and heart rate of 18, 27, and 11%, respectively (P less than 0.01). We observed that systolic pleural pressure did not have a significant effect on LVSV (P greater than 0.05). However, at pleural pressures lower than 10 cmH2O below resting expiratory level, there was a linear relationship between falls in LVSV and falls in middiastolic pleural pressure (P less than 0.0001). We concluded that reduced LVSV shown in patients with OSA was significantly related to diastolic pleural pressure level. Our findings suggested reduced preload as the most likely mechanism for decreased cardiac output in OSA.     

Effects of respiration on cardiac performance

The conventional explanation for the fall in left ventricular stroke volume (LVSV) with inspiration is that blood pools in the lungs, thereby decreasing pulmonary venous return. In anesthetized dogs, we have found an increase in left ventricular filling pressure (LVFP) with both constant and increasing lung volume during an inspiratory effort. Transmural aortic diastolic pressure rises as LVSV falls and LVFP rises consistent with the hypothesis that a fall in pleural pressure afterloads the left ventricle. Additionally the increase found in right ventricular filling pressure with inspiration may adversely affect LV performance by decreasing LV compliance and/or contractility. Our findings are incompatible with pooling of blood in the lungs being the primary determinant of the fall in LVSV with inspiration.     

Myocardial tissue pressure and blood flow during coronary sinus pressure modulation in anesthetized dogs.

To determine whether coronary sinus outflow pressure (Pcs) or intramyocardial tissue pressure (IMP) is the effective back pressure in the different layers of the left ventricular (LV) myocardium, we increased Pcs in 14 open-chest dogs under maximal coronary artery vasodilation. Circumflex arterial (flowmeter), LV total, and subendocardial and subepicardial (15-microns radioactive spheres) pressure-flow relationships (PFR) and IMP (needle-tip pressure transducers) were recorded during graded constriction of the artery at two diastolic Pcs levels (7 +/- 3 vs. 23 +/- 4 mmHg). At high Pcs, LV, aortic and diastolic circumflex arterial pressure, heart rate, myocardial oxygen consumption, and lactate extraction were unchanged; IMP in the subendocardium did not change (130/19 mmHg), whereas IMP in the subepicardium increased by 17 mmHg during systole and 10 mmHg during diastole (P < or = 0.001), independently of circumflex arterial pressure. Increasing Pcs did not change the slope of the PFR; however, coronary pressure at zero flow increased in the subepicardium (P < or = 0.008), whereas in the subendocardium it remained unchanged at 24 +/- 3 mmHg. Thus Pcs can regulate IMP independently of circumflex arterial pressure and consequently influence myocardial perfusion, especially in the subepicardial tissue layer of the LV.     

Hemodynamic effects of periodic obstructive apneas in sedated pigs with congestive heart failure.

Because of similar physiological changes such as increased left ventricular (LV) afterload and sympathetic tone, an exaggerated depression in cardiac output (CO) could be expected in patients with coexisting obstructive sleep apnea and congestive heart failure (CHF). To determine cardiovascular effects and mechanisms of periodic obstructive apnea in the presence of CHF, 11 sedated and chronically instrumented pigs with CHF (rapid pacing) were tested with upper airway occlusion under room air breathing (RA), O(2) breathing (O2), and room air breathing after hexamethonium (Hex). All conditions led to large negative swings in intrathoracic pressure (-30 to -39 Torr) and hypercapnia (PCO(2) approximately 60 Torr), and RA and Hex also caused hypoxia (to approximately 42 Torr). Relative to baseline, RA increased mean arterial pressure (from 97.5 +/- 5.0 to 107.3 +/- 5.7 Torr, P < 0.01), systemic vascular resistance, LV end-diastolic pressure, and LV end-systolic length while it decreased CO (from 2.17 +/- 0.27 to 1.52 +/- 0.31 l/min, P < 0.01), stroke volume (SV; from 23.5 +/- 2.4 to 16.0 +/- 4.0 ml, P < 0.01), and LV end-diastolic length (LVEDL). O2 and Hex decreased mean arterial pressure [from 102.3 +/- 4.1 to 16.0 +/- 4.0 Torr (P < 0.01) with O2 and from 86.0 +/- 8.5 to 78.1 +/- 8.7 Torr (P < 0.05) with Hex] and blunted the reduction in CO [from 2.09 +/- 0.15 to 1.78 +/- 0.18 l/ml for O2 and from 2.91 +/- 0.43 to 2.50 +/- 0.35 l/ml for Hex (both P < 0.05)] and SV. However, the reduction in LVEDL and LV end-diastolic pressure was the same as with RA. There was no change in systemic vascular resistance and LVEDL during O2 and Hex relative to baseline. In the CHF pigs during apnea, there was an exaggerated reduction in CO and SV relative to our previously published data from normal sedated pigs under similar conditions. The primary difference between CHF (present study) and the normal animals is that, in addition to increased LV afterload, there was a decrease in LV preload in CHF contributing to SV depression not seen in normal animals. The decrease in LV preload during apneas in CHF may be related to effects of ventricular interdependence.     

Experimental cardiac tamponade: correlation of pressure, flow velocity, and echocardiographic changes

Seven episodes of experimental cardiac tamponade were induced in five anesthetized closed-chest dogs. Simultaneous pericardial and intracavitary pressures were synchronized with superior vena caval and transvalvular pulsed-Doppler flow tracings. The earliest indication of tamponade was the development of a negative transmural right atrial pressure that occurred during early ventricular diastole and was associated with echocardiographic evidence of right atrial collapse. This was also associated with reversal of diastolic flow in the superior vena cava and with diminished early diastolic flow velocity across the tricuspid as well as the mitral valve. During more advanced cardiac tamponade, the transmural right atrial pressure became negative during both early and late ventricular diastole as well as during isovolumic ventricular systole. This was associated with a disappearance of early diastolic ventricular filling and right ventricular diastolic collapse as observed on two-dimensional echocardiography. In hypotensive cardiac tamponade (cardiac output diminished by 70%), the decreased transmural right atrial pressure that developed during ventricular systole was accompanied by diminished antegrade flow in the superior vena cava. In advanced and hypotensive tamponade, ventricular filling occurred mainly during atrial contraction.     

Effects of enhanced ventricular filling on cardiac pump performance in exercising dogs

The extent to which the normal increase in stroke volume during exercise can be augmented by increasing preload by dextran infusion was studied in seven dogs. Each dog ran 3 min on a level treadmill at mild (3-4 mph), moderate (6-8 mph), and severe (9-13 mph) loads during the control study and immediately after 10% dextran 14 ml/kg iv. During severe exercise dextran-augmented stroke volume (+5.4 ml or 19% vs. exercise without dextran, P less than 0.01) and left ventricular end-diastolic diameter and pressure did not change heart rate, aortic pressure, or maximum derivative of left ventricular pressure but decreased systemic vascular resistance by 16%. Similar increases in stroke volume and preload after dextran occurred during mild and moderate exercise when arterial pressure and heart rate were unchanged or increased and systemic vascular resistance was decreased. Thus altering preload above those levels normally encountered during exercise is a potential mechanism to increase stroke volume and cardiac output.     

Site of airway obstruction in pulmonary disease: direct measurement of intrabronchial pressure.

To partition the central and peripheral airway resistance in awake humans, a catheter-tipped micromanometer sensing lateral pressure of the airway was wedged into the right lower lobe of a 3-mm-ID bronchus in 5 normal subjects, 7 patients with chronic bronchitis, 8 patients with emphysema, and 20 patients with bronchial asthma. We simultaneously measured mouth flow, transpulmonary pressure, and intra-airway lateral pressure during quiet tidal breathing. Total pulmonary resistance (RL) was calculated from transpulmonary pressure and mouth flow and central airway resistance (Rc) from intra-airway lateral pressure and mouth flow. Peripheral airway resistance (Rp) was obtained by the subtraction of Rc from RL. The technique permitted identification of the site of airway resistance changes. In normal subjects, RL was 3.2 +/- 0.2 (SE) cmH2O.l-1.s and the ratio of Rp to RL was 0.24 during inspiration. Patients with bronchial asthma without airflow obstruction showed values of Rc and Rp similar to those of normal subjects. Although Rc showed a tendency to increase, only Rp significantly increased in those patients with bronchial asthma with airflow obstruction and patients with chronic bronchitis and emphysema. The ratio of Rp to RL significantly increased in three groups of patients with airflow obstruction (P less than 0.01). These observations suggest that peripheral airways are the predominant site of airflow obstruction, irrespective of the different pathogenesis of chronic airflow obstruction.     

Echocardiographic variables in healthy guineapigs anaesthetized with ketamine-xylazine

Echocardiographic parameters were recorded, measured and statistically analysed on a population of 12 male Hartley albino guineapigs under ketamine-xylazine anaesthesia. Additionally, the effect of body weight on these parameters and the correlation between the parameters were assessed. The mean values of left ventricular internal diameter in end diastole (LVIDD), left ventricular internal diameter in end systole (LVIDS), interventricular septum thickness in diastole (IVSD), interventricular septum thickness in systole (IVSS), left ventricular posterior wall thickness in diastole (LVPWD), left ventricular posterior wall thickness in systole (LVPWS), left atrial diameter (LA), aortic diameter (AO), left ventricular fractional shortening (FS) and left ventricular ejection fraction (EF) were measured or calculated as 6.85+/-0.36, 4.35+/-0.17, 1.75+/-0.31, 2.26+/-0.35, 2.28+/-0.40, 2.80+/-0.58, 4.95+/-0.34, 4.65+/-0.25 mm, 35.62+/-2.62 and 70.87+/-3.01%, respectively. A significant (P<0.01) positive correlation to body weight was found with LVIDD, LVPWD, IVSD, aortic root diameter and LA. Significant correlation was also found between a number of echocardiographic parameters.     

Toward consistent definitions for preload and afterload

Significant differences exist among textbook definitions for the terms preload and afterload, leading to confusion and frustration among students and faculty alike. Many faculty also chose to use in their teaching simple terms such as "end-diastolic volume" or "aortic pressure" as common-usage approximations of preload and afterload, respectively, but these are only partial representations of these important concepts. Straightforward definitions both of preload and afterload that are concise yet still comprehensive can be developed using the Law of LaPlace to describe the relationships among chamber pressure, chamber radius, and wall thickness. Within this context, the term "preload" can be defined as all of the factors that contribute to passive ventricular wall stress (or tension) at the end of diastole, and the term "afterload" can be defined as all of the factors that contribute to total myocardial wall stress (or tension) during systolic ejection. The inclusion of "wall stress" in both definitions helps the student appreciate both the complexities of cardiac pathophysiology and the rationale for therapeutic intervention.     

Influence of timing and magnitude of arterial wave reflection on left ventricular relaxation

The influence of timing and magnitude of arterial wave reflection (WR) on afterload-dependent relaxation was evaluated in patients with a variety of heart diseases (group 1, age < 30 yr; group 2, age > 40 yr) and in dogs. While both femoral arteries were compressed (FC), WR returned just after the dicrotic notch (early diastole) in group 1 but before the dicrotic notch (late systole) in group 2. The time constant of the left ventricular pressure decay (tau) was shortened during FC in group 1, whereas it was prolonged in group 2. In dogs, a constriction of the thoracic aorta induced a late systolic augmentation of WR with a prolongation of tau (cf. group 2), whereas constriction of the lower abdominal aorta induced an early diastolic augmentation of WR with a shortening of tau (cf. group 1). With aortic constriction, coronary flow increased, and there was a close correlation between the peak change in backward aortic pressure and that in coronary flow regardless of the timing of WR. Thus the time at which WR returns during the cardiac cycle may have an important effect on left ventricular relaxation and coronary flow.     

Effect of synchronous increase in intrathoracic pressure on cardiac performance during acute endotoxemia

In the anesthetized closed-chest canine model of Gram-negative endotoxemia (n = 10), we tested the hypothesis that the effect of cardiac cycle-specific intrathoracic pressure pulses delivered by a heart rate-(HR) synchronized high-frequency jet ventilator (sync HFJV) on systolic ventricular performance is dependent on the level of preload. To control for HFJV frequency, hemodynamic responses were also measured at fixed frequency within 15% of HR (async HFJV). Biventricular stroke volumes (SV) were measured by electromagnetic flow probes. Measurements were made before (baseline) and 30 min after infusion of 1 mg/kg Escherichia coli endotoxin (serotype 055:B5) and then after 2 mg/kg propranolol at both low (less than 10 mmHg) left ventricular filling pressure (LVFP) and high (greater than 10 mmHg) LVFP. Ventricular function curves, aortic pressure-flow (P-Q) relationships, and venous return (VR) curves were analyzed. We found that endotoxin did not alter VR curves but shifted the aortic P-Q curves to the left with pressure on the x-axis (P less than 0.05). Volume loading increased SV (P less than 0.01) because of a rightward shift of the VR curve. No specific differences occurred with either sync or async HFJV during endotoxin, presumably because of preserved VR and shifted aortic P-Q. The lack of cardiac cycle-specific effects of ITP appears to be due to the selective endotoxin-induced changes in peripheral vasomotor tone that counterbalance any depressed myocardial contractility.     

Determinants of gas flow through a bronchopleural fistula

To assess the determinants of bronchopleural fistula (BPF) flow, we used a surgically created BPF to study 15 anesthetized intubated mechanically ventilated New Zealand White rabbits. Mean airway pressure and intrathoracic pressure were evaluated independently. Mean airway pressure was varied (8, 10, or 12 cmH2O) by independent manipulations of either peak inspiratory pressure, positive end-expiratory pressure, or inspiratory time. Intrathoracic pressure was varied from 0 to -40 cmH2O. BPF flow varied directly with mean airway pressure (P less than 0.001). However, at constant mean airway pressure, BPF flow was not influenced independently by changes in peak inspiratory pressure, positive end-expiratory pressure, or inspiratory time. Resistance of the BPF increased as intrathoracic pressure became more negative. Despite increased resistance, BPF flow also increased. BPF resistance was constant over the range of mean airway (P less than 0.01) pressures investigated. Our data document the influence of mean airway pressure and intrathoracic pressure on BPF flow and suggest that manipulations which reduce transpulmonary pressure will decrease BPF flow.     

Development of systemic arterial mechanical properties from infancy to adulthood interpreted by four-element windkessel models.

Aortic impedance data of infants, children and adults (age range 0.8-54 yr), previously reported by others, were interpreted by means of three alternative four-element windkessel models: W4P, W4S, and IVW. The W4P and W4S are derived from the three-element windkessel (W3) by connecting an inertance (L) in parallel or in series, respectively, with the aortic characteristic resistance (Rc). In the IVW, L is connected in series with a viscoelastic windkessel (VW). The W4S and IVW (same input impedance) fit the data best. The W4S, however, suffers from the assumption that Rc is part of total peripheral resistance (Rp). The IVW model offers a new paradigm for interpretation of resistive properties in terms of viscous (Rd) properties of vessel wall motion, distinguished from Rp. Results indicated that rapid reduction of Rd/Rp during early development is functional to modulation of decay time constant (taud) of pressure in diastole, such that normalization over heart period (taud/T) is independent of body size. Estimates of total arterial compliance (C) vs. age were fitted by a bell-shaped curve with a maximum at 33 yr. With body weight (BW) factored out by normalization, the C/BW data scattered about a bell-shaped curve centered at 66 mmHg. Inertance was significantly higher in pediatric patients than in adults, in accordance with a lower cross-sectional area of the vasculature, commensurate to a lower aortic flow. Changes of arterial properties appear functional to control the ratio of pulsatile power to active power and keep arterial efficiency as high as 97% in infants and children.     

Airway obstruction during exercise and isocapnic hyperventilation in asthmatic subjects.

We compared pulmonary mechanics measured during long-term exercise (LTX = 20 min) with long-term isocapnic hyperventilation (LTIH = 20 min) in the same asthmatic individuals (n = 6). Peak expiratory flow (PEF) and forced expiratory volume in 1 s (FEV(1)) decreased during LTX (-19.7 and -22.0%, respectively) and during LTIH (-6.66 and 10. 9%, respectively). In contrast, inspiratory pulmonary resistance (RL(I)) was elevated during LTX (57.6%) but not during LTIH (9.62%). As expected, airway function deteriorated post-LTX and post-LTIH (FEV(1) = -30.2 and -21.2%; RL(I) = 111.8 and 86.5%, respectively). We conclude that the degree of airway obstruction observed during LTX is of a greater magnitude than that observed during LTIH. Both modes of hyperpnea induced similar levels of airway obstruction in the posthyperpnea period. However, the greater airway obstruction during LTX suggests that a different process may be responsible for the changes in airway function during and after the two modes of hyperpnea. This finding raises questions about the equivalency of LTIH and LTX in the study of airway function during exercise-induced asthma.     

Peptide mediator effects on bronchial blood velocity and lung resistance in conscious sheep.

Peptide mediators or neuropeptides released from sensory nerves may induce inflammatory effects in airways, but their effects on airway blood velocity and lung resistance have not been previously studied simultaneously in awake animals. Nine adult sheep were chronically prepared for continuous measurement of blood flow velocity to the distal trachea and bronchi by surgical implantation of a 20-MHz pulsed Doppler flow probe on the common bronchial branch of the bronchoesophageal artery. Awake restrained animals were intubated and connected to a pneumotachograph to measure resistance to airflow across the lung (RL). Doubling doses of bradykinin (BK, 0.02-1.51 nmol/kg), calcitonin gene-related peptide (CGRP, 0.004-0.26 nmol/kg), or substance P (SP, 0.02-1.19 nmol/kg) were injected as a bolus into the right atrium while mean arterial pressure (MAP), bronchial blood velocity (Vbr), and RL were measured. BK at 0.76 nmol/kg caused a transient dose-related increase in Vbr from a baseline of 19.3 +/- 2.5 to 41.4 +/- 4.1 (SE) cm/s (P less than 0.05) despite a decrease in MAP from 118 +/- 6 to 80 +/- 6 mmHg. CGRP at 0.26 nmol/kg caused a transient dose-related increase in Vbr from 16.8 +/- 2.7 to 25.3 +/- 4.7 cm/s (P less than 0.05) despite a decrease in MAP from 113 +/- 5 to 87 +/- 8 mmHg. Neither BK nor CGRP affected RL. SP at 1.19 nmol/kg transiently increased Vbr from 18.3 +/- 2.3 to 45.1 +/- 8.3 cm/s (P less than 0.05), MAP from 138 +/- 9 to 162 +/- 15 mmHg, and RL from 4.5 +/- 1.0 to 106.6 +/- 62.1 cmH2O.l-1.s.(ABSTRACT TRUNCATED AT 250 WORDS)