Ischemia and activated neutrophils alter coronary microvascular but not epicardial coronary artery reactivity.

Activated neutrophils have been implicated in reperfusion injury and the no-reflow phenomenon of intramyocardial arterioles. This study tested the hypothesis that ischemia and activated neutrophils impair coronary endothelial and smooth muscle cell function of epicardial and intramyocardial coronary arteries. Alteration of smooth muscle and endothelial cell function in epicardial coronary arteries (3 mm diameter) and intramyocardial coronary arteries (0.3 mm diameter) was compared by means of a myograph after exposure to ischemia (epicardial, 160 minutes, intramyocardial, 30 minutes), activated neutrophils, and combined ischemia and activated neutrophils. Morphologic studies at the ultrastructural level were done by means of scanning electron microscopy. Epicardial coronary artery function was normal after ischemia, storage with activated neutrophils, and ischemia followed by storage with activated neutrophils. Intramyocardial artery function, however, was altered. Contraction to a 45 mmol/L concentration of potassium chloride after ischemia and storage with activated neutrophils was increased (p = 0.06). Smooth muscle relaxation was significantly decreased after ischemia, but storage with activated neutrophils did not further decrease smooth muscle relaxation. Endothelium-dependent relaxation to bradykinin was significantly decreased after combined ischemia and incubation with activated neutrophils (p < 0.05). Sensitivity to bradykinin was decreased after both ischemia alone (p < 0.05) and activated neutrophils alone (p < 0.05). Similar morphologic alterations were found in epicardial and intramyocardial arteries after ischemia. Activated neutrophils alone minimally damaged endothelial cells of nonischemic intramyocardial and epicardial arteries. Endothelial cells of both arteries exposed to ischemia alone showed evidence of ischemic damage, including endothelial cell blebbing, nuclear bulging, and appearance of large holes in the cell surface. Severe endothelial cell damage was found after combined ischemia and storage with neutrophils: total destruction of cells and exposure of the basal lamina. Endothelial damage, therefore, correlated with artery function in intramyocardial but not in epicardial arteries. These results indicate that ischemia is a prerequisite for severe neutrophil injury of intramyocardial artery endothelium-mediated relaxation. This may explain no-reflow phenomenon in arterioles concurrent with myocardial reperfusion injury.

Microvascular dysfunction after myocardial ischemia.

Endothelium-mediated relaxation and smooth muscle function in large coronary arteries are resistant to prolonged global ischemia. We used a small-vessel myograph to test the hypothesis that small intramyocardial artery endothelium and smooth muscle function have greater sensitivity to ischemic injury than large artery endothelium and smooth muscle. Normothermic global ischemia was induced in 15 porcine hearts. Intramyocardial arterial ring segments were assessed at 0, 30, 60, 90, and 120 minutes of ischemia in vitro with a small-vessel myograph. Potassium determined smooth muscle contraction, bradykinin endothelium-mediated relaxation, and sodium nitroprusside direct smooth muscle relaxation. Endothelium-mediated relaxation after 30 minutes of ischemia was similar to control (56% versus 66%) but was impaired at 60, 90, and 120 minutes of ischemia (32%, 11%, and 6%). Smooth muscle contraction was unchanged at 30 and 60 minutes compared with control (56 and 53 versus 63 mm Hg) but was significantly decreased at 90 and 120 minutes (33 and 13 mm Hg). Direct smooth muscle relaxation was significantly decreased at 120 minutes of ischemia compared with control (58% versus 95%). In a previous study, epicardial coronary artery endothelium-mediated smooth muscle vasodilation and direct smooth muscle vasodilation were preserved until 160 minutes of ischemia. After 160 minutes of ischemia, endothelium-mediated relaxation was lost and only direct smooth muscle vasodilation was preserved. In contrast to vasodilation, vasoconstriction was significantly reduced at 140 minutes of ischemia. These data indicate a greater and earlier adverse effect of ischemia on intramyocardial arterial endothelium-mediated relaxation than smooth muscle contraction or relaxation. These data support the hypothesis that there is an early functional endothelial cell injury associated with global ischemia. Relaxation that is endothelium-dependent in intramyocardial arteries is more sensitive to ischemic injury than in epicardial arteries. Unique to this study was the evaluation of small intramyocardial arteries (281 +/- 29 microns) that are the primary sites of coronary vascular resistance. Microvascular endothelial dysfunction after ischemia, therefore, may contribute to the "no-reflow phenomenon" seen during reperfusion injury.

Effects of dynamic cardiomyoplasty on left ventricular performance and myocardial mechanics in dilated cardiomyopathy.

We tested the hypothesis that dynamic cardiomyoplasty produces beneficial changes in the functional mechanics of the dilated, failing left ventricle. Chronic dilated cardiomyopathy was induced in seven mongrel dogs by rapid ventricular pacing (260 beats/min) for 3 to 4 weeks. After completion of the induction period, dynamic cardiomyoplasty was performed with the left latissimus dorsi muscle, paced synchronously with the R waves of the electrocardiogram (Medtronic SP1005). Instruments included an aortic flow probe, a left ventricular Millar pressure catheter, and piezoelectric sonomicrometric crystals on the left ventricle for measurements of wall thickness and minor and major axis dimensions. Data were obtained with the stimulator off and on. Statistical comparisons were made with Student's t test for paired data. Dynamic cardiomyoplasty increased the cardiac output of the failing heart (966 +/- 124 versus 1166 +/- 112 ml/min; p less than 0.01). Systolic shortening of both minor and major axis dimensions increased (3.1 +/- 0.3 versus 4.7 +/- 0.3 mm, p less than 0.01, and 4.6 +/- 0.3 versus 7.3 +/- 0.9 mm, p less than 0.05, respectively). Left ventricular end-diastolic pressure decreased by 16% (18 +/- 1 versus 15 +/- 1 mm Hg, p less than 0.01). Although skeletal muscle contraction increased the pressure development in the left ventricular chamber, mean systolic wall stress was diminished by concomitant changes in left ventricular dimensions (116,144 +/- 11,530 versus 101,268 +/- 7464 dynes/cm2, p less than 0.05). At end-systole, wall thickness increased (11.8 +/- 1.1 versus 12.7 +/- 1.1 mm, p less than 0.01), minor axis dimension decreased (51.3 +/- 1.4 versus 49.2 +/- 1.8 mm, p less than 0.01), and major axis dimension also decreased (85.6 +/- 3.3 versus 79.0 +/- 2.3 mm, p less than 0.05). Our detailed evaluation of left ventricular chamber mechanics suggests that dynamic cardiomyoplasty may have a role in ameliorating the functional and mechanical derangements associated with progression of dilated cardiomyopathy both by augmenting cardiac performance and by diminishing determinants of myocardial oxygen consumption. (All values are expressed as mean +/- standard error of the mean.)

Reactivity of gastroepiploic and internal mammary arteries. Relevance to coronary artery bypass grafting.

The gastroepiploic artery is an alternate conduit for coronary artery bypass grafting. To test the hypothesis that its vasoreactive properties are different from those of the internal mammary artery, we obtained gastroepiploic artery segments from human gastrectomy specimens. Trimmed internal mammary artery segments were obtained during coronary artery bypass. Ring segments were mounted on a strain gauge and stretched to optimum resting length (90% of the internal circumference at 100 mm Hg). Potassium chloride, serotonin, and norepinephrine were chosen to simulate physiologic vasospasm induced by depolarization, platelet aggregation, or adrenergic stimulation, respectively. Contractions to potassium and a concentration-response curve to serotonin or norepinephrine were obtained. Sodium nitroprusside was used to assess relaxation. Gastroepiploic artery segments had stronger contractions to the depolarizing agent (potassium chloride), adrenergic stimulation (norepinephrine), and product of platelet aggregation (serotonin). The gastroepiploic and internal mammary arteries showed equal sensitivity, measured by concentration causing half-maximal contraction to norepinephrine and serotonin. There was no difference in relaxation to sodium nitroprusside. These data suggest that prevention of platelet-, adrenergic-, or potassium-induced contraction may be more important when the gastroepiploic artery is used as an alternate conduit for coronary artery bypass, reinforcing consideration of nitrovasodilators and platelet inhibitors in the perioperative interval.

Limiting edema in neonatal cardiopulmonary bypass with narrow-range molecular weight hydroxyethyl starch.

The marked edema observed in neonatal cardiopulmonary bypass is thought to result from pathologic increases in capillary permeability. Pentafraction is a subfraction of hydroxyethyl starch that is thought to be of appropriate size and shape to be retained by leaking capillaries and seal endothelial gaps in capillary basement membranes. To test the hypothesis that pentafraction would reduce edema in neonatal cardiopulmonary bypass, we established a model of edema formation in neonatal bypass in which neonatal piglets underwent 2 hours of normothermic cardiopulmonary bypass with crystalloid prime and no myocardial ischemia. Before initiation of bypass, experimental animals (n = 11) received intravenous pentafraction, 3 gm/kg. Control animals (n = 10) received an equivalent volume of saline. Hemodynamic parameters, animal weight, fluid redistribution, and percent tissue water of individual organs were assessed during and after bypass. Pentafraction treatment resulted in significant differences in (1) lowered percent body weight gain from baseline (11% versus 48%), (2) lowered volume requirement to maintain venous reservoir during cardiopulmonary bypass (148 ml/kg versus 581 ml/kg), (3) less fluid loss from the peritoneum (11 ml/kg versus 115 ml/kg), and (4) lowered percent tissue water of kidney, pancreas, stomach, jejunum, colon, and skeletal muscle (p less than 0.05 by unpaired t test). Pentafraction had no effect on hemodynamic parameters during bypass nor in percent tissue water of heart, lung, liver, spleen, skin, or brain. In summary, pentafraction lessened weight gain and fluid requirements during cardiopulmonary bypass, favorably influencing the percent tissue water of certain organs. If pentafraction functions as proposed, it may have wide applicability not only in cardiopulmonary bypass (or extracorporeal membrane oxygenation) but also in other clinical scenarios with altered capillary permeability.

Reactivity to alpha agonists is heightened in immature porcine pulmonary arteries.

BACKGROUND: Pulmonary hypertension after cardiopulmonary bypass is a common problem in pediatric cardiac operations. This study tested the hypothesis that there is a difference between adult and immature pulmonary artery constrictor and dilator responses. METHODS: Reactivity of pulmonary artery ring segments from 22 mature (15 to 19 weeks) and 15 immature pigs (4 to 5 weeks) was tested in a vessel myograph. Potassium as a receptor-independent vasoconstrictor and phenylephrine as an alpha-receptor-mediated vasoconstrictor were used to assess smooth-muscle vasoconstriction. To assess endothelial cell function (nitric oxide production and secretion), we used increasing concentrations of bradykinin or acetylcholine. Sodium nitroprusside was used to produce maximum smooth-muscle relaxation at the end of each experiment. RESULTS: The data demonstrated maturation-independent endothelium and smooth-muscle-mediated vasodilation. Pulmonary artery ring segments from immature pigs had significantly less KCl constriction compared with mature pigs (p < 0.05). In contrast, pulmonary ring segments from immature pigs demonstrated enhanced alpha-receptor-mediated constriction compared with mature pigs. CONCLUSIONS: These data may explain perioperative pulmonary vasoconstriction in pediatric patients.

The influence of age and sex on human internal mammary artery size and reactivity.

Internal mammary arteries (IMAs) from women and the elderly have been postulated to be smaller and more reactive than IMAs from men and younger patients and, therefore, not as reliable for coronary artery bypass grafting in the short term. This study tests the physiologic basis for that hypothesis. Trimmed IMA segments were obtained from patients aged 50 to 76 years at coronary artery bypass grafting. Eighteen ring segments from 12 women and 35 ring segments from 17 men were mounted on a strain-gauge apparatus, and internal diameter at a transmural pressure of 100 mm Hg was determined from length-tension curves. Contractions to potassium chloride and a dose-response curve to norepinephrine or serotonin were obtained to simulate physiologic vasospasm. Sodium nitroprusside determined arterial relaxation. Linear regression was used to determine correlation of these parameters with age. Internal mammary arteries from women and men were of equal size. They had equal strength of contraction to potassium chloride and norepinephrine, but female IMAs had greater strength of contraction to serotonin. Female IMAs had weaker contraction to norepinephrine as a percent of maximum contraction to potassium chloride than IMAs from men. Internal mammary arteries from women had equal relaxation to sodium nitroprusside compared with IMAs from men. There was no correlation between age and arterial reactivity to vasoconstrictors, relaxation to sodium nitroprusside, or size. These data suggest that IMAs from women and the elderly are not more susceptible to reduction in flow due to smaller size. Postoperatively, it may be important that women be kept on platelet inhibitors because of their greater absolute contraction to serotonin and men on nitrovasodilators because of their greater relative contraction to norepinephrine.

Effects of triiodothyronine supplementation after myocardial ischemia.

Cardiopulmonary bypass causes a "euthyroid-sick" state characterized by low levels of circulating triiodothyronine. Triiodothyronine supplementation in this setting has been postulated to improve postischemic left ventricular function by increasing the availability of myocardial high-energy phosphates. These postulates have not been substantiated, however, using load-independent parameters of left ventricular function and analysis of high-energy phosphate metabolism. To test these hypotheses, 14 healthy pigs (30 to 40 kg) were placed on cardiopulmonary bypass and instrumented with left ventricular minor-axis ultrasonic crystals and micromanometer-tipped pressure catheters. Hearts were subjected to 30 minutes of global, normothermic ischemia. Triiodothyronine (0.1 mg/kg; n = 7) or placebo (n = 7) was administered in a random, investigator-blinded fashion at the removal of the aortic cross-clamp and after 60 minutes of reperfusion. Hemodynamic, metabolic, and ultrastructural data were obtained before ischemia and after 30, 60, 90, and 120 minutes of reperfusion. By 90 minutes of reperfusion left ventricular contractility had returned to preischemic levels in hearts supplemented with triiodothyronine, despite postischemic myocardial adenosine triphosphate levels of 50% to 60% of baseline in both groups. Ultrastructurally, the sarcoplasmic reticulum and mitochondria were significantly better preserved in the group treated with triiodothyronine. This study suggests that triiodothyronine supplementation significantly enhances postischemic left ventricular functional recovery and that this recovery is due to mechanisms other than enhanced availability of myocardial high-energy phosphates.

Orotic acid improves left ventricular recovery four days after heterotopic transplantation.

Orotic acid accelerates compensatory myocardial hypertrophy after regional ischemia and improves left ventricular function acutely after global ischemia. In this study, the effect of orotic acid on left ventricular function was investigated 4 days after global ischemia (75 minutes, 21 degrees C) using heterotopically transplanted rabbit hearts (n = 18). Experimental animals received daily 100-mg/kg doses of intraperitoneally administered orotic acid, starting 1 day before transplantation, and showed a threefold increase in the serum level of orotic acid by 4 days. After 1 hour of reperfusion, the developed pressure was equally depressed in both the control and experimental groups; however, 4 days later, the developed pressure in control animals was decreased by 3 +/- 3 mm Hg (versus the developed pressure measured at 1 hour) while the developed pressure in experimental animals was significantly increased by 25 +/- 8 mm Hg. Heterotopically transplanted hearts manifested diminished systolic function (stemming from ischemia and unloading) as well as decreased expression of adult myosin. Because orotic acid has been observed to produce an increase in protein synthesis in other models, we investigated whether this improvement in systolic function resulted from an orotic acid-mediated augmentation (or preservation) or normal adult myosin expression. Both orotic acid-treated and untreated hearts manifested decreased expression of the beta-myosin heavy chain protein and steady-state messenger RNA levels. Because function improved with decreased beta-myosin heavy chain expression, an alternate mechanism underlying orotic acid-mediated improvement in function is implicated. Nevertheless, orotic acid may be a therapeutic agent facilitating long-term recovery from global ischemia.

Coronary artery endothelial cell and smooth muscle dysfunction after global myocardial ischemia.

We hypothesized that coronary artery endothelial cell function and smooth muscle function are modified by global myocardial ischemia and used bradykinin-induced secretion of endothelium-derived relaxing factor as a marker of endothelial cell function. Bradykinin and sodium nitroprusside together determined maximum smooth muscle relaxation. Potassium chloride-induced contraction determined smooth muscle contractility. Endothelium-mediated smooth muscle relaxation expressed as a ratio of total coronary smooth muscle relaxation before and after ischemia quantified endothelial cell function. The effect of global normothermic ischemia on in situ coronary arteries from 7 swine hearts was studied. Coronary arterial rings taken from 0 to 220 minutes of ischemia at 20-minute intervals were studied in vitro. The data revealed unexpected tolerance of endothelium-mediated relaxation to ischemia. Endothelium-derived relaxing factor function was maintained to 160 minutes and smooth muscle function, to 120 minutes of ischemia. Coronary artery dysfunction seen in other studies after less ischemia may be the result of injury introduced during reperfusion, may be the consequence of myocardial injury, or may be due to events operative at the level of small arterioles.

Efficacy of a hydroxyl radical scavenger (VF 233) in preventing reperfusion injury in the isolated rabbit heart.

We tested the hypothesis that 3,4,5,-trihydroxybenzamidoxime (VF 233), a demonstrated hydroxyl radical scavenger and an effective Fe3+ chelator, attenuates reperfusion injury and improves isovolumic left ventricular function. Eighteen isolated, perfused rabbit hearts with intracavitary balloons were subjected to normothermic, global ischemia until the initiation of ischemic contracture. Effects on the adenine nucleotide pool metabolites were determined by high-pressure liquid chromatography from right ventricular biopsy specimens before ischemia and at 15-minute intervals throughout reperfusion. In the experimental group (n = 9), a 5-mL bolus of 1 mol/L VF 233 was given immediately before reperfusion and followed by a continuous infusion (0.125 mumol/min). The control group (n = 9) received the vehicle solution at identical times. Rabbits treated with VF 233 had significant improvement in left ventricular function (expressed as percent return of left ventricular peak developed pressure) within 15 minutes of reperfusion (55.0 +/- 3.0 versus 66.2 +/- 4.1; p less than 0.05 by analysis of variance) after global ischemia and remained significantly improved throughout the reperfusion period. Myocardial adenine nucleotide pool intermediates were not significantly different between groups. These results demonstrate that administration of VF 233 significantly improves ventricular function but does not affect adenine nucleotide metabolism after ischemia and reperfusion.

Ultra-low dose aprotinin decreases transfusion requirements and is cost effective in coronary operations.

BACKGROUND: The recommended dose of aprotinin has been shown to reduce blood loss and need for blood transfusions, but the cost precludes its routine use. This study was designed to determine whether a less expensive, ultra-low dose of aprotinin is effective when used in coronary artery bypass grafting with left internal mammary artery. METHODS: Patients (n = 202) were randomized to receive either placebo or aprotinin, 0.5 million KIU before incision and 0.5 million KIU during initiation of cardiopulmonary bypass. Differences in quantity of blood transfused were analyzed. Further groups were analyzed to account for the effect of aspirin. Multivariable analysis was performed to determine risk factors for transfusion. Direct costs of blood products and aprotinin were tabulated for each group. RESULTS: There was an important reduction in the proportion of patients transfused, and number of blood units transfused when aprotinin was given before coronary artery bypass grafting. These differences were even more important in patients on aspirin preoperatively. Independent predictors for increased number of transfusions were aspirin continued before operation, smaller body surface area, and the use of placebo instead of ultra-low dose aprotinin. There was no difference in morbidity between treatment groups. There was a reduction in direct costs associated with the use of aprotinin. CONCLUSIONS: These data support the routine use of aprotinin 1 million KIU in coronary artery bypass grafting with left internal mammary artery to reduce cost and transfusion requirements.

Inotropic stimulation and oxygen consumption in a canine model of dilated cardiomyopathy.

Inotropic support for the dilated, failing ventricle results in complex hemodynamic changes affecting preload, afterload, contractility, and heart rate, each of which affects myocardial oxygen consumption. Appreciation of a hierarchy of hemodynamic determinants of myocardial oxygen consumption may be helpful to the clinician trying to balance oxygen demands and hemodynamic performance. We tested the hypothesis that epinephrine alters the hierarchy of hemodynamic determinants of myocardial oxygen consumption in a canine model of dilated cardiomyopathy created by rapid ventricular pacing. Dogs (n = 10) were instrumented to record left ventricular pressure and dimension, and a modified right heart bypass preparation was used to control left ventricular workload. Coronary sinus effluent was quantitatively collected and analyzed for oxygen content and used to calculate myocardial oxygen consumption. Epinephrine administration significantly increased myocardial oxygen consumption in the empty, beating heart; however, when the relationships of multiple determinants of left ventricular work and load were compared before and after epinephrine administration, no oxygen wasting effect was observed. Using multivariate linear regression analysis, a hierarchy of hemodynamic determinants of myocardial oxygen consumption was created. In the untreated heart, stroke work and cardiac output were the primary hemodynamic determinants of oxygen consumption; epinephrine significantly altered the determinants such that wall stress became the dominant hemodynamic determinant of myocardial oxygen consumption. Focused manipulation of wall stress in the treated, failing heart may limit the potentially deleterious effects of inotropic stimulation in this setting.

Penetrating injury to the heart requiring cardiopulmonary bypass: a case study.

Penetrating wounds to the heart represent a significant surgical challenge because of their unique clinical course and the need for emergent operative care. This operative care, which may include cardiopulmonary bypass (CPB), must be initiated in a prompt yet careful fashion to optimize outcome, while minimizing morbidity. Trauma, because of its unpredictable and non-routine nature, may present many challenges to the perfusionist in an attempt to anticipate surgical needs and requirements. In this case report, we describe the successful surgical repair of a cardiac nail gun injury, as well as strategies we feel are essential for the safe, successful, and timely application of emergent CPB.

Coronary vasomotor dysfunction following hemorrhagic shock.

Myocardial dysfunction and subendocardial ischemia have been described during hemorrhagic shock, but technical limitations have precluded the in vitro examination of coronary reactivity following hemorrhage. We tested the hypothesis that in vitro coronary artery contraction and relaxation are impaired by hemorrhagic shock (HS). HS was produced in awake rats (n = 6) 24 hr after surgery for arterial cannulation, by bleeding to a mean arterial pressure of 50 mm Hg for 2 hr followed by reinfusion of shed blood. Using a small vessel myograph, reactivity of coronary arterial ring segments from three groups of rats not undergoing HS were compared to coronaries harvested from rats after HS (Group 4). The three nonshock treatments included normal rats without pretreatment (Group 1), rats undergoing prior surgical cannulation alone (Group 2), and rats undergoing prior surgical cannulation followed by nonhypotensive hemorrhage (Group 3). Responses to 125 mM potassium (KCl) and to 10(-6) M serotonin (STN) determined smooth muscle contraction. Acetylcholine administration determined endothelium-mediated smooth muscle relaxation, whereas acetylcholine plus nitroprusside combined determined maximum smooth muscle relaxation. Rats following HS demonstrated impaired coronary arterial smooth muscle contraction to KCl when compared to normal rats, but the response to STN did not differ among groups. Maximum smooth muscle relaxation was significantly lower in rats following HS as compared to rats in Groups 1 and 2. Endothelium-dependent relaxation was significantly impaired when compared to each of the three nonshock groups. Thus, in coronary arteries isolated from neurohumoral influences, HS was associated with diminished smooth muscle contraction and relaxation as well as impaired endothelium-mediated relaxation.(ABSTRACT TRUNCATED AT 250 WORDS)

Pulmonary artery endothelial cell function in swine pseudomonas sepsis.

A substantial increase in pulmonary vascular resistance is associated with sepsis and its sequelae (sepsis syndrome and septic shock). It is postulated that increased resistance may result from sepsis-induced endothelial cell injury or altered vasoreactivity secondary to pulmonary hypertension. We, therefore, tested the hypothesis that sepsis causes endothelial cell injury and that increased pulmonary pressure alters vascular reactivity. Young swine (15-25 kg) were anesthetized and ventilated. Septic animals received a 1-hr infusion of live Pseudomonas aeruginosa (n = 11), and the control cohort received 0.9% NaCl (n = 7). All animals were studied for 300 min following the infusion. Postmortem branches of peripheral pulmonary arteries were prepared and tested in a vessel myograph. Ring segments were set to 90% of the circumference the vessels would have at pressures of 20, 30, 40, or 50 mmHg (L90), corresponding to varying pulmonary pressures observed in sepsis. A high dose of potassium was used to obtain maximum possible contraction. Prostaglandin was used to precontract the vessels before testing endothelial cell responses to acetylcholine or bradykinin. Sodium nitroprusside was added at the end of each experiment to obtain maximum possible smooth muscle relaxation. No differences in contraction or relaxation were observed when vessels were set to different pressures (i.e., 20 vs 50 mmHg). Maximum possible contraction to KCl was significantly decreased after 300 min of sepsis compared to control. No differences between groups were found in contractility to prostaglandin. Bradykinin-induced EDRF/NO production, mediated by BK2 receptors, was not altered in Pseudomonas sepsis (97-98% of total relaxation control and 91-95% septic cohort). Response to acetylcholine was significantly decreased after sepsis (89-95% of total relaxation control and 51-61% of septic cohort relaxation). Decreased response to acetylcholine could not be attributed to decreased smooth muscle sensitivity to nitric oxide because the response to bradykinin plus sodium nitroprusside was not altered following sepsis. Vessel reactivity was not altered by increasing pressure settings reflective of changing pulmonary pressure in vivo. These results strongly suggest a sepsis-induced alteration in pulmonary artery endothelial cell receptor sensitivity to acetylcholine, independent of changing pulmonary arterial pressures. This is the first time this decrease has been shown in pseudomonas sepsis.