Increased proportion of active sheep erythrocyte rosette-forming lymphocytes and plasma rosette enhancement in sarcoidosis

Thromboxane A2 mediates lung vasoconstriction but not permeability after endotoxin

The effect of dazoxiben, a selective thromboxane (Tx) synthetase inhibitor, on systemic and pulmonary hemodynamics, eicosanoids, and lung permeability was assessed in awake goats with lung lymph fistulae following infusion of Escherichia coli endotoxin (1 microgram/kg). Animals received endotoxin either with no treatment or pretreatment with a bolus (25 mg/kg) followed by a maintenance infusion (10 mg/kg per h) of dazoxiben. In untreated animals, the peak rise of 26.8 cm H2O in pulmonary artery (Ppa) and of 13.5 cm H2O in wedge (Pw) pressures occurred at the same time as the peak elevations in plasma thromboxane B2 (T X B2). Maximum reduction in cardiac output (Qt) also occurred at the same time. Lung lymph flow (QL) increased during this period and remained elevated for at least 6 h after endotoxin. T X B2 levels had returned from a peak of 13.1 to 0.7 ng/ml by 2 h. In dazoxiben-treated animals, plasma concentrations of T X B2 were never significantly elevated. Increases in Ppa and Pw were markedly reduced and decreased Qt was transient. QL in treated animals began to increase by 30 min after endotoxin and reached a peak by 2 h. Increased QL in treated animals was not as great as in the untreated animals. Moreover, lymph-plasma protein ratios increased significantly in treated animals. Plasma prostaglandin (PG)F2 alpha and 6-keto-PGF1 alpha concentrations were elevated in both groups after endotoxin with values significantly greater in treated animals. We conclude that selective inhibition of Tx ameliorates many adverse hemodynamic consequences of endotoxemia but does not prevent lung permeability changes.

Acetyl glyceryl ether phosphorylcholine-stimulated human platelets cause pulmonary hypertension and edema in isolated rabbit lungs. Role of thromboxane A2

Macrophages, neutrophils, and platelets may play a role in acute edematous lung injury, such as that seen in the adult respiratory distress syndrome (ARDS), but their potential actions and interactions are unclear. Because stimulated human macrophages and neutrophils can release acetyl glyceryl ether phosphorylcholine (AGEPC), a potent platelet activator, we hypothesized that in ARDS, leukocyte release of AGEPC might stimulate platelets to release thromboxane A2 (TXA2), which then produces pulmonary hypertension and lung edema. In support of this premise, we found that pulmonary hypertension and edema occurred in isolated rabbit lungs perfused with human platelets and AGEPC, but not with platelets or AGEPC alone. Infusion of a vasodilator (nitroglycerin) to maintain base-line pulmonary artery pressures in lungs perfused with platelets and AGEPC prevented the development of lung edema suggesting that platelet and AGEPC-induced edema was hydrostatic in nature. Additional experiments suggested that the increased pressure was a result of TXA2 release from platelets stimulated by AGEPC. Specifically, preincubation of platelets with imidazole, a thromboxane synthetase blocker, prior to infusion with AGEPC significantly diminished pulmonary hypertension and prevented lung edema. Furthermore, pretreating lung preparations with 13-azaprostanoic acid, a TXA2 antagonist, before infusion of AGEPC and untreated platelets also reduced the pulmonary hypertension and blocked the lung edema. The role of TXA2 was further suggested when perfusates from lungs infused with platelets and AGEPC developed high levels of TXA2, whereas perfusates from controls did not. These results suggest that platelet aggregation induced by AGEPC may contribute to ARDS by releasing TXA2, which raises microvascular pressure and increases edema formation, especially when an underlying permeability defect is present.

Ibuprofen in canine endotoxin shock

The participation of prostaglandins in the physiologic alterations of endotoxin shock has been well established with the aid of prostaglandin synthetase inhibitors. Our study was designed to investigate the potential of ibuprofen, a highly specific cyclooxygenase inhibitor, to reverse the hemodynamic and acid base abnormalities of canine endotoxin shock. Mean blood pressure fell to 49.8 +/- 6.6 mm Hg in dogs given endotoxin by 5 min after injection, and remained below 83 mm Hg for the duration of the 120-min observation period. In animals given endotoxin followed by ibuprofen, a similar initial drop of systemic blood pressure was seen, but it subsequently recovered to 150.2 +/- 4.1 mm Hg by 120 min (P less than 0.001). Cardiac index increased in animals given ibuprofen (2.3 +/- 0.28 liter/m2 per min) compared with animals given endotoxin alone (1.0 +/- 0.09 liter/m2 per min) by termination of the experiment. The arterial pH dropped in endotoxin treated animals to 7.18 +/- 0.03 by 120 min. Ibuprofen prevented the acidosis, the final pH in ibuprofen and endotoxin treated animals measuring 7.36 +/- 0.01. We conclude that ibuprofen protects against the hypotension, acidosis, and depression of cardiac index of canine endotoxin shock.

Prevention by granulocyte depletion of increased vascular permeability of sheep lung following endotoxemia

To see whether circulating granulocytes are necessary for the lung vascular reaction to endotoxin, we measured the endotoxin response in chronically instrumented sheep before and after granulocyte depletion with hydroxyurea. Granulocyte depletion did not affect the pulmonary hypertension caused by endotoxin (peak mean pulmonary artery pressures = 38 +/- 2 cm H2O before depletion and 42 +/- 2 after depletion, P = NS). The late phase increase in lung lymph flow after endotoxin was significantly lower in the granulocytopenic animals as reflected by lung lymph flow (mean steady state lymph flow before depletion = 30.6 +/- 2.0 SE ml/h; mean steady state lymph flow after granulocyte depletion = 15.4 +/- 1.0; P less than 0.01) even though late phase pulmonary vascular pressures were similar before and after granulocyte depletion. Lung lymph protein clearance (lymph flow x lymph/plasma protein concentration) was also significantly lower after granulocyte depletion (mean steady state before depletion = 2.14 +/- 1.4 SE ml/h; and after depletion = 10.4 +/- 1.0; P less than 0.01). We conclude that circulating granulocytes are necessary for the development of increased lung vascular permeability to fluid and protein following endotoxin. The pulmonary vasopressor effects of endotoxin in sheep are independent of granulocytes.

Methylprednisolone prevention of increased lung vascular permeability following endotoxemia in sheep

To see whether methylprednisolone would affect the pulmonary vascular response to endotoxemia, we studied responses to endotoxemia in the presence and absence of methylprednisolone in the same chronically instrumented, unanesthetized sheep. Infusion of Escherichia coli endotoxin (0.70-1.33 mug/kg) caused an initial period of marked pulmonary hypertension followed several hours later by a long period of increased vascular permeability when pulmonary vascular pressures were near base line (base-line pulmonary artery pressure (PPa) = 21+/-1 cm H(2)O SE, left atrial pressure (Pla) = 1+/-3; experimental PPa = 20+/-3, Pla = 3+/-4; P = NS), lung lymph flow ( Qlym) was high (base-line Qlym = 7.2+/-0.2 ml/h; experimental Qlym = 23.2+/-1.0; P < 0.05) and lymph/plasma protein concentration (L/P) was high (base-line L/P = 0.65+/-0.04; experimental L/P = 0.79+/-0.05; P < 0.05). When methylprednisolone (1.0 g + 0.5 g/h i.v.) was begun 30 min before the same dose of endotoxin was infused, the initial pulmonary hypertension was less and the late phase increase in lung vascular permeability was prevented (experimental PPa = 24+/-1, Pla = 1+/-1, Qlym = 10.0+/-0.4; L/P = 0.56+/-0.03). Qlym and L/P were significantly (P < 0.05) lower than with endotoxin alone. Methylprednisolone began during the initial pulmonary hypertensive response to endotoxin also prevented the late phase increase in lung vascular permeability, but the drug had no effect once vascular permeability was increased. We conclude that large doses of methylprednisolone given before or soon after endotoxemia prevent the increase in lung vascular permeability that endotoxin causes, but do not reverse the abnormality once it occurs.