Shock : molecular, cellular, and systemic pathobiological aspects and therapeutic approaches : the official journal the Shock Society, the European Shock Society, the Brazilian Shock Society, the International Federation of Shock Societies
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Hemorrhagic shock results in hepatocellular dysfunction and hepatic injury that may contribute to the development of liver failure and multiple organ dysfunction in trauma patients. The specific mediators involved in this process remain incompletely defined. We have previously demonstrated that inhibition of nitric oxide (NO) synthesis in a rat model of moderately severe hemorrhagic shock increases hepatic injury, suggesting that NO synthesis is beneficial after hemorrhage. ⋯ The increased hepatic injury produced by L-NAME was associated with increased myeloperoxidase content in the lung, suggesting that L-NAME led to a greater accumulation of neutrophils during shock. Administration of the NO donor S-nitroso-N-acetylpenicillamine reduced hepatocellular enzyme release. Our results suggest that ongoing NO synthesis during the hypotensive phase of hemorrhagic shock is essential in preventing shock-induced hepatic injury and this may be due, in part, to the interaction between NO and circulating neutrophils.
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When oxygen delivery (DO2) critically decreases, oxygen consumption (VO2) becomes supply dependent. We examined whether end-tidal PCO2 (PetCO2) would identify supply dependency during shock. Five dogs (Group I) underwent progressive hemorrhage to decrease DO2 until they could no longer maintain a stable blood pressure. ⋯ The PetCO2 versus time inflection point was compared with the DO2 at onset of supply dependency (DO2crit). DO2crit for Groups I and II were 6.9 +/- .4 and 8.1 +/- 1.3, respectively (p = NS), and not statistically different from the DO2 values at which PetCO2 decreased (6.6 +/- .7 and 6.3 +/- .7 mL/kg per min, respectively). AT constant minute volume, PetCO2 effectively indicated the onset of supply dependency and rapidly increased during resuscitation, paralleling the changes in VO2 in this model of hemorrhagic shock.
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Randomized Controlled Trial Clinical Trial
Antithrombin III supplementation in severe sepsis: beneficial effects on organ dysfunction.
Activation of thrombin and of the coagulation system plays an important role in the pathophysiology of sepsis-associated organ dysfunction. Antithrombin III (AT III) is a natural inhibitor of thrombin, a central procoagulatory factor with pleiotropic activities. Experimental supplementation of AT III improved coagulation parameters and ameliorated organ dysfunction. ⋯ In AT III patients a progressive increase in oxygenation index (PaO2/FiO2 ratio) and a continuous decrease in pulmonary hypertension index (mean pulmonary artery pressure/mean arterial pressure (PAP/MAP) ratio) indicated an improvement of lung function (p < .05 vs. control). AT III prevented the continuous rise in total serum bilirubin concentration observed in control patients and diminished the frequency of artificial renal support therapy (p < .05). Long-term supplementation with AT III may improve lung function and prevent the development of septic liver and kidney failure in patients with severe sepsis.
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The overzealous production of proinflammatory cytokines in sepsis can result in shock, multiorgan dysfunction, and even death. In this study we assessed the role of endogenously produced interleukin (IL)-12 in murine models of endotoxemia and Gram-negative peritoneal sepsis. Initial studies indicated that intraperitoneal lipopolysaccharide (LPS) administration to mice induced a significant time-dependent increase in plasma, lung, and liver IL-12 levels. ⋯ Interestingly, there was an approximately 70-fold increase in peritoneal fluid E. coli colony-forming units and the early onset of bacteremia in animals treated with anti-IL-12 serum, as compared with control animals. These results indicate that IL-12 is produced in response to LPS exposure, and the neutralization of this cytokine improves survival in endotoxin-challenged animals. However, IL-12 represents an essential component of antibacterial host defense, as anti-IL-12 therapy results in significant impairment in the host's ability to clear Gram-negative bacterial infection.
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This study was performed to quantify the impact of Haldane effect (HE) on the relationship between O2 extraction (O2Ex; mL O2/dL blood) and venous pH in 247 measurements performed in 91 septic patients (73 patients with intra-abdominal sepsis, 11 with retroperitoneal abscesses, 6 with severe cholangitis, and 1 with gangrenous fasclitis). The severity of sepsis varied from relatively compensated to extremely diseased conditions. This allowed a detailed assessment of the impact of HE over a wide range of cardiorespiratory and metabolic abnormalities. ⋯ Their sum (total DpH) was .033 +/- .017 and was related directly and strongly to O2Ex: DpH = -.002 + .009 (O2Ex) [r2 = .85, p < < .001], thus confirming the quantitative impact of HE in moderating the decrease in venous pH relative to arterial pH. The loss of this effect was responsible for the larger decreases in venous pH observed in hypodynamic patients developing impaired O2Ex. These results allow an easy quantification of the Haldane component, separated from the other components affecting pH, and are also useful for assessing the protective role exerted by HE against excessive decreases in venous pH in circulatory failure.