A novel right-heart catheterization technique for in vivo measurement of vascular responses in lungs of intact mice

The present study employed a new right-heart catheterization technique to measure pulmonary arterial pressure, pulmonary arterial wedge pressure, and pulmonary vascular resistance in anesthetized intact-chest, spontaneously breathing mice. Under fluoroscopic guidance, a specially designed catheter was inserted via the right jugular vein and advanced to the main pulmonary artery. Cardiac output was determined by the thermodilution technique, and measured parameters were stable for periods of 相似文献   

Hemodynamic mechanisms of the pulmonary artery pressure and blood flow changes following vasoactive pressor drugs injection

The character and values of changes of the pulmonary and systemic hemodynamics following epinephrine, norepinephrine and angiotensin intravenous injection were studied in acute experiments on the anesthetized cats. After catecholamines injection pulmonary blood flow was always increased, meanwhile pulmonary artery pressure can be elevated (in the most observations) or decreased. In the cases of angiotensin administration the pulmonary blood flow could be augmented or decreased; pulmonary artery pressure had been increased or decreased independently from the character of changes of pulmonary flow. Thus, linear correlation between shifts of the pulmonary artery pressure and pulmonary blood flow had not been revealed. The changes of the pulmonary artery pressure were not correlated with the pulmonary vascular resistance ones; however they had strong relationship with the changes of the left atrial pressure. If the left atrial pressure was decreased the pulmonary artery pressure elevation was less, comparing with its values in experiments, where the left atrial pressure was increased; in the case of depressor shifts of pulmonary artery pressure, the left atrial pressure was also decreased. The character and values of the pulmonary blood flow changes were strongly correlated with the changes of the venous return; however they had no linear correlations with the right and left atrial pressures and pulmonary vascular resistance changes. Thus we concluded, that hemodynanics mechanisms of the pulmonary artery pressure and flow changes following vasoactive pressor drugs injection changes are different.     

Effects of pneumatic antishock garment inflation in normovolemic subjects

This study examines the effects of inflation of pneumatic antishock garments (PASG) in 10 normovolemic men (mean age 44 +/- 6 yr) undergoing diagnostic catheterization. Seven subjects had normal heart function and no evidence of coronary artery disease (CAD); three patients had CAD. High-fidelity multisensor catheters were employed to simultaneously record right and left heart pressures before PASG inflation and after inflation to 40, 70, and 100 mmHg. A thermal dilution catheter was used to obtain pulmonary capillary wedge pressure and cardiac output. Counterpressure increases greater than or equal to 40 mmHg were associated with significant changes in left and right heart pressures. Right and left ventricular end-diastolic pressures increased 100% (P less than 0.01); mean pulmonary arterial and aortic pressures increased 77 and 25%, respectively (P less than 0.01); systemic vascular resistance increased 22% (P less than 0.05) and pulmonary vascular resistance did not change in normal subjects at maximum PASG inflation. Heart rate, cardiac output, and aortic and pulmonary arterial pulse pressures did not change during inflation in either group. Right and left ventricular end-diastolic pressures and pulmonary capillary wedge pressure were greater (P less than 0.05) in the CAD group compared with the normal subjects during PASG inflation. The data suggest that the primary mechanism whereby PASG inflation induces changes in central hemodynamics in normovolemic subjects is through an acute increase in left ventricular afterload. PASG changes in afterload and pulmonary capillary wedge pressure imply that these devices should be used with caution in patients with compromised cardiac function.     

Circulatory effects of prolonged hypoxia before and during antihistamine.

Five chronically instrumented healthy dogs were exposed to a 5-day period of breathing 10% oxygen in a chamber. The response to hypoxia was found to be time dependent. During the first 24 h of hypoxia the circulatory response was characterized by increases in cardiac output, heart rate, pulmonary and systemic arterial blood pressures, and pulmonary vascular resistance. Systemic vascular resistance increased; left atrial pressure decreased. During the early part of hypoxia the animals became hypocapnic; the arterial blood pH rose significantly. During the rest of the hypoxic period cardiac output, heart rate, and arterial blood pH returned to the control values; pulmonary and systemic arterial pressures and pulmonary vascular resistance remained significantly elevated. Systemic vascular resistance rose; left atrial pressure remained below control. This response to hypoxia was not substantially modified when the experiment was repeated during the administration of the antihistamine promethazine, an H1-receptor blocking agent, in a dose which blocked the pulmonary vasoconstrictor response to small doses of exogenous histamine. The circulatory response to acute hypoxia in five anesthetized dogs was not modified by intravenous administration of metiamide, an H2-receptor blocking agent.     

The adrenergic mechanisms are involved in the pulmonary hemodynamics changes following experimental myocardial ischemia in rabbits

In acute experiments in anesthetized rabbits the changes of the pulmonary hemodynamics following myocardial ischemia in the region of the descendent left coronary artery were studied in control animals and after the blockade of alpha-adrenoreceptors by phentolamine or N-cholinoreceptors of autonomic ganglia by hexamethonium. Following myocardial ischemia in control animals the pulmonary artery pressure and flow decreased, the pulmonary vascular resistance was elevated not significantly, the cardiac output decreased more than pulmonary artery flow. Following myocardial ischemia after the blockade of alpha-adrenoreceptors the pulmonary artery flow and cardiac output decreased in the same level and the pulmonary vascular resistance was decreased. In these conditions the pulmonary artery pressure decreased more than in control animals, meanwhile the pulmonary artery flow was decreased in the same level as in the last case. Following myocardial ischemia after the blockade of N-cholinoreceptors the pulmonary hemodynamics changes were the same as they were following myocardial ischemia in the control rabbits, the cardiac output decreased more than pulmonary artery flow. The disbalance of the cardiac output and pulmonary artery flow changes in the case of myocardial ischemia was caused by the pulmonary vessel reactions following activations of the humoral adrenergic mechanisms.     

Pulmonary vascular remodeling in isolated mouse lungs: effects on pulsatile pressure-flow relationships

Chronic hypoxia causes pulmonary vasoconstriction and pulmonary hypertension, which lead to pulmonary vascular remodeling and right ventricular hypertrophy. To determine the effects of hypoxia-induced pulmonary vascular remodeling on pulmonary vascular impedance, which is the right ventricular afterload, we exposed C57BL6 mice to 0 (control), 10 and 15 days of hypobaric hypoxia (n=6, each) and measured pulmonary vascular resistance (PVR) and impedance ex vivo. Chronic hypoxia led to increased pulmonary artery pressures for flow rates between 1 and 5ml/min (P<0.01), and increased PVR, 0-Hz pulmonary vascular impedance and the index of wave reflection (P<0.05) as well as a more negative impedance phase angle for low frequencies (P<0.05). The increases in resistance and 0-Hz impedance correlated with increased muscularization of small arterioles measured with quantitative immunohistochemistry (P<0.01). The increases in wave reflection and decreases in phase angle are likely due to increased proximal artery stiffness. These results confirm that chronic hypoxia causes significant changes in steady and pulsatile pressure-flow relationships in mouse lungs and does so via structural remodeling. They also provide important baseline data for experiments with genetically engineered mice, with which molecular mechanisms of pulmonary vascular remodeling can be investigated.     

The pulmonary hemodynamic changes under experimental myocardial ischemia in rabbits following beta-adrenoreceptors blockade

In acute experiments in anesthetized rabbits, changes of the pulmonary hemodynamics following myocardial ischemia in the region of the descendent left coronary artery were studied as well as in control animals and after the blockade of beta-adrenoreceptors. The myocardial ischemia decreased the left ventricular myocardial contractility, cardiac output and arterial pressure, decreased the pulmonary artery pressure and flow. Following myocardial ischemia, the pulmonary artery pressure decreased less than pulmonary artery blood flow as the result of elevating of the left atrial pressure, meanwhile pulmonary vascular resistance was not changed. Following myocardial ischemia in animals after the blockade of the beta-adrenoreceptors, the pulmonary flow decreased the same as in control animals. However, the pulmonary artery pressure was decreased twofold more significantly than in control animals, and its diminishing was in the same degree as the pulmonary artery flow. Following myocardial ischemia after the blockade of the beta-adrenoreceptors, the pulmonary vascular resistance decreased whereas the left atrial pressure did not change significantly because the myocardial contractility decreased less than in control animals.     

Effects of dopamine, noradrenaline and isoproterenol on pulmonary circulation in anesthetized dogs

Experiments were performed on 19 anaesthetized open-chest dog instrumented with polyethylene catheters inserted: into the aorta, in pulmonary artery and in left atrium and with an electromagnetic flow-transducer placed around the ascending aorta in order to record : systemic arterial and pulmonary pressures, mean left auricular pressure and phasic aortic flow. Heart rate, stroke volume, total systemic and pulmonary resistance, cardiac work were moreover calculated. Each dog was given intravenously by slow infusione : Dopamine (micrograms 5--10--20/kg/min/ 5 min), Isoproterenol (microgram 0.125--0.25--0.5/kg/min/5 min) and Norepinephrine (microgram 0.25--0.5--1 /kg/min/5 min). Results obtained on systemic hemodynamics agree with those reported by many other investigators. On pulmonary circulation : Isoproterenol, at the tested doses, elicited vasodilator effects, Norepinephrine increased total pulmonary resistance but not pulmonary vascular resistance, while Dopamine did not modify or slightly reduced vascular pulmonary tone.     

Effect of hypoxia on pulmonary blood flow-segmental vascular resistance relationship in perfused cat lungs

To investigate the effect of alveolar hypoxia onthe pulmonary blood flow-segmental vascular resistance relationship, wedetermined the longitudinal distribution of vascular resistance whileincreasing blood flow during hyperoxia or hypoxia in perfused catlungs. We measured microvascular pressures by the micropipetteservo-null method, partitioned the pulmonary vessels into threesegments [i.e., arterial (from main pulmonary artery to 30- to50-µm arterioles), venous (from 30- to 50-µm venules to leftatrium), and microvascular (between arterioles and venules)segments] and calculated segmental vascular resistance. Duringhyperoxia, total resistance decreased with increased blood flow becauseof a reduction of microvascular resistance. In contrast, duringhypoxia, not only microvascular resistance but also arterial resistancedecreased with increase of blood flow while venous resistance remainedunchanged. The reduction of arterial resistance was presumably causedby arterial distension induced by an elevated arterial pressure duringhypoxia. We conclude that, during hypoxia, both microvessels andarteries >50 µm in diameter play a role in preventing furtherincreases in total pulmonary vascular resistance with increased bloodflow.

     

Bronchovascular responses to intravenous contrast media for helical CT pulmonary angiography

CT angiography is now commonly used for the diagnosis of pulmonary embolism, but the contrast media used for imaging produces various hemodynamic changes. In this study, we investigated the bronchovascular and hemodynamic responses to intravenous iopromide, a non-ionic contrast agent used for pulmonary CT angiograms, in anesthetized, mechanically ventilated sheep (n = 6). Bronchial blood flow and cardiac output were measured with ultrasonic flow probes. Systemic and pulmonary arterial pressures were continuously monitored. Injections of 0.9% NaCl (120 ml over 30 s) or iopromide (300 mg/ml, 120 ml over 30 s) were given in random order in a peripheral vein with an angiogram infuser and hemodynamic changes were determined. After these parameters returned to baseline, the left pulmonary artery (LPA) was occluded with a snare and the animals were allowed to stabilize. Injections of NaCl and iopromide were repeated in random order as before. There were no significant hemodynamic effects with infusion of NaCl. With intact pulmonary vasculature, NaCl and iopromide did not cause significant changes in arterial blood gases, however, cardiac output (QT, L/min), mean systemic and pulmonary arterial pressures (PSA and PPA, Torr) increased and bronchovascular resistance (BVR, Torr x min/ml), decreased. Following LPA ligation, pH and PO2 significantly decreased over baseline, whereas PCO2 increased. After LPA ligation, iopromide produced a greater decrease in BVR as compared with preligation intact pulmonary vasculature. In conclusion, iopromide caused rapid hemodynamic changes and decreased BVR, likely secondary to osmolar stress. Bronchovascular effects were more pronounced after pulmonary arterial occlusion.     

Central and peripheral circulatory effects and metabolic effects of different prostaglandins given I.V. to man

Cardiac output, heart rate, stroke volume, pressures in the brachial artery, right ventricle and pulmonary artery, forearm blood flow, and arterial concentration of FFA, lactate and glucose were measured in healthy male volunteers during i–v infusion of PGE₁, PGE₂, PGF_2α or 15-methyl PGF_2α in increasing doses. In accordance with previous findings PGE₁ and PGE₂ increased cardiac output by a vasodilating effect in the systemic and pulmonary vascular bed, probably in combination with an inotropic effect on the heart.15-methyl PGF_2α had essentially the same cardiovascular effects as PGF_2α. They induced a slight increase in cardiac output due to effects on heart rate, while systemic vascular resistance was unchanged. Forearm vascular resistance increased and pressures in the pulmonary circulation rose, indicating a vasoconstriction in these vascular beds.Glucose concentrations were not affected nor were lactate concentrations, except for a slight decrease of unclear significance in the group receiving 15-methyl PGF_2α. FFA increased slowly in the same manner as seen spontaneously in fasting individuals. These data do not indicate direct metabolic effects of the prostaglandins studied when given i–v.     

Thromboxane inhibition reduces an early stage of chronic hypoxia-induced pulmonary hypertension in piglets.

The pulmonary vasoconstrictor, thromboxane, may contribute to the development of pulmonary hypertension. Our objective was to determine whether a combined thromboxane synthase inhibitor-receptor antagonist, terbogrel, prevents pulmonary hypertension and the development of aberrant pulmonary arterial responses in newborn piglets exposed to 3 days of hypoxia. Piglets were maintained in room air (control) or 11% O(2) (hypoxic) for 3 days. Some hypoxic piglets received terbogrel (10 mg/kg po bid). Pulmonary arterial pressure, pulmonary wedge pressure, and cardiac output were measured in anesthetized animals. A cannulated artery technique was used to measure responses to acetylcholine. Pulmonary vascular resistance for terbogrel-treated hypoxic piglets was almost one-half the value of untreated hypoxic piglets but remained greater than values for control piglets. Dilation to acetylcholine in preconstricted pulmonary arteries was greater for terbogrel-treated hypoxic than for untreated hypoxic piglets, but it was less for pulmonary arteries from both groups of hypoxic piglets than for control piglets. Terbogrel may ameliorate pulmonary artery dysfunction and attenuate the development of chronic hypoxia-induced pulmonary hypertension in newborns.     

Hemodynamic mechanisms of the pulmonary artery pressure and blood flow changes following vasoactive depressor drugs injection

The character and values of changes of the pulmonary hemodynamics and venous return following acetylcholine, histamine and isoproterenol intravenous injection were studied in acute experiments on the anesthetized cats. After depressor drugs injection the character and values of changes of pulmonary artery pressure and flow were different. In 67% cases the pulmonary artery pressure was decreased, and in 33%--it was elevated, meanwhile the pulmonary artery flow was decreased in 48% cases and it was increased in 52%, i.e., in the equal number of observations. Thus, following depressor drugs intravenous injection, hemodynamic mechanisms of the changes of pulmonary artery pressure and flow are different. The character and values of changes of the pulmonary artery pressure are correlated with the changes of pulmonary vascular resistance and are not dependent with the left atrial pressure shifts. The changes of the pulmonary artery blood flow are caused by the changes of the venous return and are not correlated with the changes of the right and left atrial pressure.     

Sildenafil is more selective pulmonary vasodilator than prostaglandin E1 in patients with pulmonary hypertension due to heart failure

In some patients, heart failure (HF) is associated with increased pulmonary vascular resistance (PVR). The magnitude and the reversibility of PVR elevation affect the HF management. Sildenafil has been recently recognized as potent PVR-lowering drug in HF. The aim of the study was to compare hemodynamic effects and pulmonary selectivity of sildenafil to prostaglandin E(1) (PGE(1)). Right-heart catheterization was performed in 13 euvolemic advanced HF patients with elevated PVR (6.3+/-2 Wood's units). Hemodynamic parameters were measured at the baseline, during i.v. infusion of PGE1 (alprostadil 200 ng · kg(-1) · min(-1)) and after 40 mg oral dose of sildenafil. Both drugs similarly reduced systemic vascular resistance (SVR), but sildenafil had higher effect on PVR (-28 % vs. -49 %, p = 0.05) and transpulmonary pressure gradient than PGE(1). The PVR/SVR ratio--an index of pulmonary selectivity, did not change after PGE(1) (p = 0.7) but it decreased by -32 % (p = 0.004) after sildenafil. Both drugs similarly reduced pulmonary artery mean and wedge pressures and increased cardiac index (+27 % and +28 %). Sildenafil led more often to transplant-acceptable PVR while causing smaller drop of mean systemic pressure than PGE(1). In conclusion, vasodilatatory effects of sildenafil in patients with heart failure are more pronounced in pulmonary than in systemic circulation.     

Measurement of bronchial arterial blood flow and bronchovascular resistance in sheep

We studied the bronchial arterial blood flow (Qbr) and bronchial vascular resistance (BVR) in sheep prepared with carotid-bronchial artery shunt. Nine adult sheep were anesthetized, and through a left thoracotomy a heparinized Teflon-tipped Silastic catheter was introduced into the bronchial artery. The other end of the catheter was brought out through the chest wall and through a neck incision was introduced into the carotid artery. A reservoir filled with warm heparinized blood was connected to this shunt. The height of blood column in the reservoir was kept constant at 150 cm by adding more blood. Qbr was measured, after interrupting the carotid-bronchial artery flow, by the changes in the reservoir volume. The bronchial arterial back pressure (Pbr) was measured through the shunt when both carotid-bronchial artery and reservoir Qbr had been temporarily interrupted. The mean Qbr was 34.1 +/- 2.9 (SE) ml/min, Pbr = 17.5 +/- 3.3 cmH2O, BVR = 3.9 +/- 0.5 cmH2O X ml-1 X min, mean pulmonary arterial pressure = 21.5 +/- 3.6 cmH2O, and pulmonary capillary wedge pressure (Ppcw) = 14.3 +/- 3.7 cmH2O. We further studied the effect of increased left atrial pressure on these parameters by inflating a balloon in the left atrium. The left atrial balloon inflation increased Ppcw to 25.3 +/- 3.1 cmH2O, Qbr decreased to 21.8 +/- 2.4 ml/min (P less than 0.05), and BVR increased to 5.5 +/- 1.0 cmH2O.ml-1.min (P less than 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)     

Hemodynamic effects of postpulmonary administration of prostaglandin D2 in fetal animals

Dose-response relationships in pulmonary vascular resistance (PVR), mean systemic arterial pressure (SAP), and heart rate (HR) to left atrial administration of prostaglandin D2 (PGD2) were determined in five fetal lambs. Fetuses were delivered by cesarean section from chloralose anesthetized ewes with the umbilical circulation maintained intact. Fetuses were prevented from breathing thus maintaining pulmonary vascular tone in the elevated fetal state. Blood was withdrawn from the inferior vena cava and pumped at constant flow into the lower left lobe of the fetal lung. Postpulmonary infusions of PGD2 brought about dose-dependent decreases in pulmonary vascular resistance. Heart rate tended to increase in fetal lambs. Mean systemic arterial pressure increased in the fetal lambs at all doses tested except for the largest dose (44.14 micrograms/kg X min), which produced slight hypotension. These data demonstrate that exposure to the systemic circulation prior to entering the pulmonary vasculature does not alter the preferential dilator action of PGD2 on fetal pulmonary vessels nor does it produce significant systemic hypotension.     

Microvascular pressure profile in intact in situ lung.

We measured the microvascular pressure profile in lungs physiologically expanded in the pleural space at functional residual capacity. In 29 anesthetized rabbits a caudal intercostal space was cleared of its external and internal muscles. A small area of endothoracic fascia was surgically thinned, exposing the parietal pleura through which pulmonary vessels were clearly detectable under stereomicroscopic view. Pulmonary microvascular pressure was measured with glass micropipettes connected to a servo-null system. During the pressure measurements the animal was kept apneic and 50% humidified oxygen was delivered in the trachea. Pulmonary arterial and left atrial pressures were 22.3 +/- 1.5 and 1.6 +/- 1.5 (SD) cmH2O, respectively. The segmental pulmonary vascular pressure drop expressed as a percentage of the pulmonary arterial to left atrial pressure was approximately 33% from pulmonary artery to approximately 130-microns-diam arterioles, 4.5% from approximately 130- to approximately 60-microns-diam arterioles, approximately 46% from approximately 60-microns-diam arterioles to approximately 30-microns-diam venules, approximately 9.5% from 30- to 150-microns-diam venules, and approximately 7% for the remaining venous segment. Pulmonary capillary pressure was estimated at approximately 9 cmH2O.     

Reference cardiopulmonary values in normal dogs

The purpose of this project was to collate canine cardiopulmonary measurements from published and unpublished studies in our laboratory in 97 instrumented, unsedated, normovolemic dogs. Body weight; arterial and mixed-venous pH and blood gases; mean arterial, pulmonary arterial, pulmonary artery occlusion, and central venous blood pressures; cardiac output; heart rate; hemoglobin; and core temperature were measured. Body surface area; bicarbonate concentration; base deficit; cardiac index; stroke volume index, systemic and pulmonary vascular resistance indices; left and right cardiac work indices; alveolar partial pressure of oxygen (pO2) ; alveolar-arterial pO2 gradient (A-apO2); arterial, mixed-venous, and pulmonary capillary oxygen content; oxygen delivery; oxygen consumption; oxygen extraction; venous admixture; arterial and mixed-venous blood CO2 contents; and CO2 production were calculated. In the 97 normal, resting dogs, mean arterial and mixed-venous pH were 7.38 and 7.36, respectively; partial pressure of carbon dioxide (pCO2), 40.2 and 44.1 mm Hg, respectively; base-deficit, -2.1 and -1.9 mEq/liter, respectively; pO2, 99.5 and 49.3 mm Hg, respectively; oxygen content, 17.8 and 14.2 ml/dl, respectively; A-a pO2 was 6.3 mm Hg; and venous admixture was 3.6%. The mean arterial blood pressure (ABPm), mean pulmonary arterial blood pressure (PAPm), pulmonary artery occlusion pressure (PAOP) were 103, 14, and 5.5 mm Hg, respectively; heart rate was 87 beats/min; cardiac index (CI) was 4.42 liters/min/m2; systemic and pulmonary vascular resistances were 1931 and 194 dynes.sec.cm-5, respectively; oxygen delivery, consumption and extraction were 790 and 164 ml/min/m2 and 20.5%, respectively. This study represents a collation of cardiopulmonary values obtained from a large number of dogs (97) from a single laboratory using the same measurement techniques.     

Comparative responses to endothelin-2 and sarafotoxin 6b in the pulmonary vascular bed of the cat

Pulmonary vascular responses to endothelin-2 and sarafotoxin 6b were investigated in the feline pulmonary vascular bed under natural flow and constant flow conditions. Injections of endothelin-2 and sarafotoxin 6b in a dose of 0.3 nmol/kg iv increased pulmonary arterial and left atrial pressures and cardiac output, and caused a biphasic change in calculated pulmonary vascular resistance. Endothelin-2 caused a biphasic change in systemic arterial pressure, while sarafotoxin 6b only decreased arterial pressure. Under constant flow conditions in the intact-chest cat, injections of endothelin-2 and sarafotoxin 6b in doses of 0.1-1 nmol into the perfused lobar artery increased lobar arterial pressure in a dose-related manner but were less potent than the thromboxane A2 mimic, U46619. An ET analog with only the Cys1-Cys15 disulfide bond and an amidated carboxy terminus had no significant activity in the pulmonary vascular bed. The present data show that endothelin-2 and sarafotoxin 6b have significant vasoconstrictor activity in the pulmonary vascular bed of the cat.     

Pulmonary vasodilation by acetazolamide during hypoxia is unrelated to carbonic anhydrase inhibition

Acute hypoxic pulmonary vasoconstriction can be inhibited by high doses of the carbonic anhydrase inhibitor acetazolamide. This study aimed to determine whether acetazolamide is effective at dosing relevant to human use at high altitude and to investigate whether its efficacy against hypoxic pulmonary vasoconstriction is dependent on carbonic anhydrase inhibition by testing other potent heterocyclic sulfonamide carbonic anhydrase inhibitors. Six conscious dogs were studied in five protocols: 1) controls, 2) low-dose intravenous acetazolamide (2 mg.kg(-1).h(-1)), 3) oral acetazolamide (5 mg/kg), 4) benzolamide, a membrane-impermeant inhibitor, and 5) ethoxzolamide, a membrane-permeant inhibitor. In all protocols, unanesthetized dogs breathed spontaneously during the first hour (normoxia) and then breathed 9-10% O(2) for the next 2 h. Arterial oxygen tension ranged between 35 and 39 mmHg during hypoxia in all protocols. In controls, mean pulmonary artery pressure increased by 8 mmHg and pulmonary vascular resistance by 200 dyn.s.cm(-5) (P <0.05). With intravenous acetazolamide, mean pulmonary artery pressure and pulmonary vascular resistance remained unchanged during hypoxia. With oral acetazolamide, mean pulmonary artery pressure increased by 5 mmHg (P < 0.05), but pulmonary vascular resistance did not change during hypoxia. With benzolamide and ethoxzolamide, mean pulmonary artery pressure increased by 6-7 mmHg and pulmonary vascular resistance by 150-200 dyn.s.cm(-5) during hypoxia (P < 0.05). Low-dose acetazolamide is effective against acute hypoxic pulmonary vasoconstriction in vivo. The lack of effect with two other potent carbonic anhydrase inhibitors suggests that carbonic anhydrase is not involved in the mediation of hypoxic pulmonary vasoconstriction and that acetazolamide acts on a different receptor or channel.