View clinical trials related to Multi Organ Dysfunction Syndrome.
Filter by:The human body knows a biphasic immunological reaction to sepsis. First, the pro-inflammatory reaction takes place, marked by the release of pro-inflammatory cytokines like TNF-α, as a reaction to the bacterial toxins. Secondly, the counter regulatory anti-inflammatory reaction arises. This phase is acting as negative feedback on the inflammation by inhibition of the pro-inflammatory cytokines. This is called "immunoparalysis", a pronounced immunosuppressive state, which renders patients vulnerable to opportunistic infections. Most of the septic patients survive the initial pro-inflammatory phase, but die during this second stage.Research in the past has shown that immunostimulatory therapy with GM-CSF or IFN-γ has promising effects on the pro-inflammatory reaction during immunoparalysis ex vivo. Both drugs are known for their immunostimulatory effects. Recent pilot studies have showed in septic patients, that long-lasting monocyte deactivation in sepsis ex vivo can be reversed by these two immunostimulants. However, the mechanism and extent of immunoparalysis recovery may be different between the two compounds. Previously it has been shown that human endotoxemia (induced by LPS), leads to marked immunosuppression in healthy individuals, characterized by a transient refractory state to a subsequent LPS challenge (endotoxin tolerance). Consequently, human endotoxemia can serve as a standardized, controlled model for sepsis-induced immunoparalysis. Until now, all studies have focused on the ex vivo tolerance. However, we have recently proved, that the ex vivo condition is not completely representative for the in vivo situation. Ex vivo, leukocyte tolerance to LPS resolves within one day, while the in vivo immunoparalysis persists for two weeks. In this project, we will investigate the effects of both GM-CSF and IFN-γ in a parallel double-blind placebo controlled randomized manner on the immunoparalysis following human endotoxemia, both in-vitro and in vivo. As a result, we hope to get more insight in the pathophysiology of sepsis-induced immunoparalysis and thereby develop new immunostimulatory therapies that improve patient outcome
Excessive inflammation, production of free radicals and vascular injury are considered the main contributors to the development of organ dysfunction in patients with severe infections and sepsis. The endogenously produced unconjugated bilirubin is one of the most powerful anti-oxidants of the human body and the administration of bilirubin in animal experiments has been shown to protect from inflammation-induced death. However, bilirubin for human administration is not yet available. Therefore, we wish to exploit one of the side effects of atazanavir, a registered drug currently used as a protease inhibitor in HIV infected patients. Atazanavir inhibits the enzyme UPD glucuronosyl transferase enzyme (UGT1A1) and therefore increases endogenously produced bilirubin levels moderately. To study the effect of hyperbilirubinemia during inflammation we will apply the human endotoxemia model. The human endotoxemia model permits elucidation of key players in the immune response to a gram negative stimulus in vivo, therefore serving as a useful tool to investigate potential novel therapeutic strategies in a standardized setting. We hypothesize that atazanavir-induced hyperbilirubinemia has beneficial anti-inflammatory and vascular effects during human endotoxemia.
Excessive inflammation is associated with tissue damage caused by over-activation of the innate immune system. This can range from mild disease to extreme conditions such as multiple organ failure (MOF). In marked contrast to adaptive immunity which is very sensitive to immune modulators such as steroids, the innate immune system cannot be sufficiently targeted by currently available anti-inflammatory drugs. We hypothesize that C1-esterase inhibitor can modulate the innate immune response. In this study, human endotoxemia will be used as a model for inflammation. Subjects will, additionally to endotoxin, receive C1 esterase inhibitor or placebo. Blood will be sampled to determine the levels of markers of the innate immune response.