Dimethylthiourea reverses sepsis-induced pulmonary hypertension in piglets.

Dimethylthiourea (DMTU), a putative hydroxyl radical scavenger, attenuates thromboxane generation and pulmonary hypertension in the piglet model of group B streptococcal (GBS) sepsis. This study tested the hypothesis that DMTU reverses ongoing GBS-induced pulmonary hypertension coincident with decreased thromboxane production. Piglets (n = 15) received a 60 min infusion of GBS (10(-8) cfu/kg/min). Mean pulmonary artery pressure (Ppa), arterial blood gases (ABGs), and thromboxane B2 (TXB) levels were measured at 10 min intervals throughout the study. GBS infusion resulted in a marked increase in pulmonary artery pressure (mean delta Ppa = 31 mm Hg) and a significant decline in PaO2 (mean = -80 torr) within 10 min of beginning the infusion. pH decreased from a mean of 7.47 to 7.37. DMTU, 750 mg/kg, or normal saline vehicle was infused over 10-15 min beginning 10 min after initiating GBS. Ppa decreased significantly within 10 min of DMTU infusion. Piglets receiving vehicle had a slow decline in Ppa. Piglets receiving DMTU also had an improvement in PaO2 and showed no further drop in pH. Piglets receiving vehicle had no improvement in PaO2 and demonstrated a continued decline in pH. TXB levels did not differ between the groups at any time interval. We conclude that DMTU can partially reverse GBS-induced pulmonary hypertension, but may function through mechanisms independent of thromboxane generation.

Organ-specific disposition of group B streptococci in piglets: evidence for a direct interaction with target cells in the pulmonary circulation.

Despite the serious pulmonary manifestations of early onset group B streptococcal (GBS) sepsis, it is not known whether the organism distributes into lung tissue and whether adverse pulmonary hemodynamic abnormalities relate to an interaction between the organism and target cells in the pulmonary vascular bed. Accordingly, this study evaluated the distribution and fate of GBS in the lung, liver, and spleen of anesthetized infant piglets and in isolated, salt solution-perfused piglet lung preparations. GBS were radiolabeled with 111Indium-oxine and infused at a dose of 10(8) organisms/kg/min for 15 min into anesthetized piglets ranging in age from 5-10 d. Forty-five min after termination of the infusion, animals were killed and specimens of lung, liver, spleen, and blood were excised and the relative deposition and viability of GBS were determined. Most of the recovered bacteria were detected in the lung (53.2 +/- 3.9%) followed by the liver (41.4 +/- 2.0%) and spleen (2.2 +/- 0.38%). GBS detected in the blood was estimated to be only 3.2 +/- 1.0% of the infused dose. Viability of GBS was least in the lung (21.4 +/- 2.6%) relative to the liver (45.7 +/- 11.2%) and spleen (83.4 +/- 19.5%). After a 60-min GBS infusion, transmission electron microscopy localized the organism within pulmonary intravascular macrophages in the lung; there was no evidence for bacterial interaction with either neutrophils or endothelial cells. In the liver, GBS was found exclusively in Kupffer cells. In isolated piglet lungs perfused at a constant flow rate with blood-free physiologic salt solution, GBS (10(6) to 10(8) organisms/mL) provoked concentration-dependent increases in pulmonary vascular resistance.(ABSTRACT TRUNCATED AT 250 WORDS)

Group B streptococcus promotes oxygen radical-dependent thromboxane accumulation in young piglets.

Both thromboxane A2 and oxygen-derived free radicals appear to play central roles in group B streptococcus (GBS)-induced pulmonary hypertension in piglets. This study tested the hypothesis that GBS promotes oxygen radical-dependent thromboxane accumulation and pulmonary hypertension in infant piglets. Piglets 4-12 d old were anesthetized and prepared for assessment of pulmonary arterial pressure and arterial blood gases. In control animals, GBS (10(8) organisms/kg/min for 15 min) increased mean pulmonary artery pressure by 30 +/- 1.5 torr and reduced arterial PO2 by 100 +/- 20 torr. Thromboxane A2, radioimmunoassayed in venous blood as thromboxane B2, increased by 2452 +/- 800 pg/mL. A second group of piglets was treated with dimethylthiourea (DMTU: 750 mg/kg), a putative oxygen radical scavenger. In these animals, GBS increased pulmonary arterial pressure by only 7 +/- 1 torr and reduced arterial PO2 by a modest 10 +/- 8 torr. Importantly, thromboxane B2 content in venous blood failed to increase above control levels in DMTU-treated animals. The protective effects of DMTU in GBS-treated piglets could not be ascribed to inhibition of cyclooxygenase or thromboxane synthase because the oxygen radical scavenger failed to attenuate increases in pulmonary arterial pressure and venous thromboxane B2 content or reductions in arterial PO2 caused by i.v. infusions of arachidonic acid. DMTU also did not ameliorate pulmonary hypertension evoked by the thromboxane mimetic U44069, thereby suggesting that the scavenger did not act as an end-organ antagonist of thromboxane receptors. These observations suggest that GBS promotes accumulation of thromboxane A2 and attendant pulmonary hypertension through an oxygen radical-dependent mechanism.

Oxygen radical-dependent bacterial killing and pulmonary hypertension in piglets infected with group B streptococci.

The mechanism by which bacteria are cleared by the pulmonary circulation and the relation of this process to development of hemodynamic abnormalities are not understood. This study tested the hypotheses that clearance of Group B Streptococcus (GBS) during transit through the pulmonary circulation of infant piglets is related to oxygen radical-dependent bacterial killing and that killing of the organism is linked to development of pulmonary hypertension. GBS were radiolabeled with 111In and infused intravenously for 15 min (10(8) organisms/kg/min) into infant piglets ranging in age from 5 to 14 days. Lung specimens were excised at termination of the GBS infusion or 45 min thereafter, and both the relative deposition and viability of the bacteria were determined. The percentage of infused GBS recovered in lung tissue did not differ between the two time points (26 +/- 7% versus 29 +/- 8%), but the relative viability at termination of the infusion, 50 +/- 11%, was reduced to 19 +/- 4% within 45 min. Treatment with an oxygen radical scavenger, dimethylthiourea (DMTU), failed to influence the pulmonary deposition of GBS but significantly increased viability of the organism from 21.4 +/- 2.6 to 33.3 +/- 5.3%. As expected, GBS infusion was accompanied by pulmonary hypertension and arterial hypoxemia; DMTU attenuated these responses by 52 and 78%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)