Vasopressors and Inotropes in the Treatment of Human Septic Shock: Effect on Innate Immunity?

The optimal adrenergic support in shock is controversial. We investigated whether dopamine administration influences the outcome from shock. Cohort, multiple-center, observational study. One hundred and ninety-eight European intensive care units. All adult patients admitted to a participating intensive care unit between May 1 and May 15, 2002. None. Patients were followed up until death, until hospital discharge, or for 60 days. Shock was defined as hemodynamic compromise necessitating the administration of vasopressor catecholamines. Of 3,147 patients, 1,058 (33.6%) had shock at any time; 462 (14.7%) had septic shock. The intensive care unit mortality rate for shock was 38.3% and 47.4% for septic shock. Of patients in shock, 375 (35.4%) received dopamine (dopamine group) and 683 (64.6%) never received dopamine. Age, gender, Simplified Acute Physiology Score II, and Sequential Organ Failure Assessment score were comparable between the two groups. The dopamine group had higher intensive care unit (42.9% vs. 35.7%, p=.02) and hospital (49.9% vs. 41.7%, p=.01) mortality rates. A Kaplan-Meier survival curve showed diminished 30 day-survival in the dopamine group (log rank=4.6, p=.032). In a multivariate analysis with intensive care unit outcome as the dependent factor, age, cancer, medical admissions, higher mean Sequential Organ Failure Assessment score, higher mean fluid balance, and dopamine administration were independent risk factors for intensive care unit mortality in patients with shock. This observational study suggests that dopamine administration may be associated with increased mortality rates in shock. There is a need for a prospective study comparing dopamine with other catecholamines in the management of circulatory shock.

Interleukin-6 (IL-6) is likely to be an important mediator of the inflammatory response. We measured levels of this cytokine in plasma samples from 37 patients with sepsis or septic shock obtained at the time of admission to the intensive care unit and related these levels to hemodynamic and biochemical parameters as well as to clinical outcome. In 32 of the 37 patients, increased levels of IL-6 were found, occasionally up to 7,500 times the normal level. The highest IL-6 levels were encountered in patients who suffered from septic shock (P value of the difference between patients with and without shock less than .0001). In addition, IL-6 significantly correlated with plasma lactate (P less than .0001), heart rate (P = .05) and, inversely, with mean arterial pressure (P = .01) and platelet counts (P = .0002). Significant correlations of IL-6 with the anaphylatoxins C3a (P = .0001) and C4a (P = .0002) and with the main inhibitor of the classical pathway of complement, C1-inhibitor (inverse correlation, P = .05), were also observed. IL-6 on admission appeared to be of prognostic significance: levels were higher in septic patients who subsequently died than in those who survived (P = .0003), in particular when only patients with septic shock were considered (P less than .0001). All nine septic patients with levels of less than 40 U/mL on admission survived, whereas 89% of the nine patients with levels exceeding 7,500 U/mL died. These data provide evidence for a role of IL-6 in the pathophysiology of septic shock. Further studies are needed to reveal whether IL-6 in sepsis is directly involved in mediating lethal complications or whether it is to be considered as an "alarm hormone" that reflects endothelial cell injury probably mediated by the anaphylatoxines.

It is well established that catecholamines (CAs), which regulate immune and inflammatory responses, derive from the adrenal medulla and from presynaptic neurons. Recent studies reveal that T cells also can synthesize and release catecholamines which then can regulate T cell function. We have shown recently that macrophages and neutrophils, when stimulated, can generate and release catecholamines de novo which, then, in an autocrine/paracrine manner, regulate mediator release from these phagocytes via engagement of adrenergic receptors. Moreover, regulation of catecholamine-generating enzymes as well as degrading enzymes clearly alter the inflammatory response of phagocytes, such as the release of proinflammatory mediators. Accordingly, it appears that phagocytic cells and lymphocytes may represent a major, newly recognized source of catecholamines that regulate inflammatory responses.