G. Schlag

Systemic inflammatory response syndrome after cardiac operations

BACKGROUND A systemic inflammatory response after open heart operation may be responsible for hyperdynamic circulatory instability and organ dysfunction. To what extent mediator release is involved needs to be clarified. METHODS Ten patients with postoperative hyperdynamic circulatory dysregulation (group I) requiring application of alpha-constrictors and 10 patients with routine cardiac procedures and stable postoperative hemodynamic indices (group II) were analyzed for mediator release and metabolic and hemodynamic changes until the third postoperative day. RESULTS Group I patients showed a significantly increased cardiac index and decreased systemic vascular resistance after bypass (cardiac index, group I: 5.2 +/- 1.2 L.min-1.m-2, group II: 2.5 +/- 1.6 L.min-1.m-2; systemic vascular resistance, group I: 495 +/- 204 dyne.s. cm-5, group II: 1,356 +/- 466 dyne.s.cm-5) and at 3 hours (cardiac index, group I: 4.4 +/- 0.8 L.min-1.m-2, group II: 2.9 +/- 0.6 L.min-1.m-2; systemic vascular resistance, group I: 567 +/- 211 dyne.s.cm-5, group II: 1,053 +/- 273 dyne.s.cm-5). Significantly higher serum levels of interleukin-6 were assessed in group I (postbypass, group I: 6,812 +/- 9,293 pg/mL, group II: 295 +/- 303 pg/mL; 3 hours, group I: 3,474 +/- 5,594 pg/mL, group II: 286 +/- 296 pg/mL). Concentrations of elastase, tumor necrosis factor, soluble tumor necrosis factor receptor, and interleukin-8 were elevated in group I (not significant). Early postoperative levels of soluble E-selectin and soluble intercellular adhesion molecule were also higher in group I (not significant). Continuously increased levels of endotoxin could be detected in only 3 of 10 patients in group I. Severe lactic acidosis (> or = 5 mmol/L) occurred in group I only. CONCLUSIONS Postoperative hyperdynamic instability after open heart operations appears to be associated with a certain pattern of mediator release. In particular, interleukin-6 appears to be involved in circulatory dysregulation and metabolic derangement.

Impaired energy metabolism in hearts of septic baboons: diminished activities of Complex I and Complex II of the mitochondrial respiratory chain.

Recent findings support the view that the bioenergetic part of septic organ failure is not caused by insufficient supply of oxygen but by disturbances of the mitochondrial function. Therefore, the aim of the present study was to investigate key enzymes of energy metabolism in septic hearts to answer the question whether or not impairment of mitochondrial or glycolytic enzymes occur under these conditions. For this purpose the well established model of septic baboons was used. Baboons under general anesthesia were made septic by infusion of Escherichia coli. Single challenge with infusion of high amounts of bacteria was compared with a multiple challenge protocol (less bacteria infused). Some animals obtained no E. coli (sham). The hearts of the baboons were removed after 72 h (survival: yes) or after death (survival: no) of the animals, frozen in liquid nitrogen, and stored at -80 degrees C until spectrophotometrical measurement of nine mitochondrial and glycolytic enzymes. A reduction of the activity of NADH:cytochrome-c-reductase (Complex I + III) to 67% and succinate:cytochrome-c-reductase (Complex II + III) to 45% was found in the hearts of surviving animals after infusion of high amounts of bacteria. After multiple challenge with lesser amounts of bacteria, no significant changes in enzyme activity were detectable. After lethal septic shock, activities of Complex I + III (12%) and Complex II + III (13%) as well as of phosphofructokinase (16%) were found to be strongly diminished. Decylubiquinol:cytochrome-c-reductase (Complex III, 59%), cytochrome-c-oxidase (51%), succinate dehydrogenase (60%), glucosephosphate isomerase (61%), lactate dehydrogenase (61%), and citrate synthase (120%) were less or unaffected. Similar but less pronounced effects were found after infusion of lesser amounts of bacteria. By means of inhibitor titrations of succinate: cytochrome-c-reductase, it was shown that the loss of activity is not caused by Complex III but by disturbances in Complex II. It is concluded that E. coli-induced sepsis causes decreased activities of Complex I and Complex II in baboon heart mitochondria in a dose-dependent manner.

Local and systemic reactions after lung contusion: an experimental study in the pig.

ABSTRACT The present study was designed to investigate the consequences of isolated unilateral lung contusion on local alveolar and systemic inflammatory responses in an animal model in the pig. Isolated unilateral lung contusion was induced by bolt shot in eight mechanically ventilated animals under general anesthesia (sham: n = 4). Plasma and bronchoalveolar lavage fluid were collected during a period of 8 h following lung contusion. Leukocytes, leukocyte neutral protease inhibitor (LNPI), terminal complement complex (TCC), thrombin-antithrombin-complex (TAT) as well as pulmonary microvascular permeability and surfactant function were determined. Within 30 min, lung contusion was found to cause a significant local and systemic increase in TCC and TAT concentrations and a systemic increase in LNPI concentrations. The latter was accompanied by a sequestration of leukocytes in the contused lung. Complement activation and leukocyte sequestration in the contused lung progressively increased during the investigation period. Although surfactant function decreased in the entire lung 30 min after contusion, TCC, TAT, and leukocyte sequestration was unchanged in the contralateral lung. The first indication of an involvement of the contralateral lung was obtained by an increase in leukocyte sequestration 8 h after lung contusion. Unilateral lung contusion initiates an early systemic activation of humoral and cellular defense systems. Involvement of the contralateral lung appears to be a secondary event caused by a systemic inflammatory reaction.

Does lung contusion affect both the traumatized and the noninjured lung parenchyma? A morphological and morphometric study in the pig.

Isolated unilateral lung contusion (LC) was induced in 12 pigs to determine the pathophysiological role of LC in the high mortality after multiple injury. The Horovitz quotient, pulmonary vascular resistance, mean pulmonary artery pressure, mixed venous oxygen consumption, inspiratory pressure and compliance were significantly decreased in the LC group as compared to controls. The number of polymorphonuclear granulocytes, the microvascular permeability of albumine and the Wilhelmy balance as determined by bronchoalveolar lavage were significantly increased after lung contusion. As indicators of a systemic reaction we found elevated plasma levels of the terminal complement complex and decreased levels of the complement factor 3a after LC. The morphological assessment revealed changes such as those encountered during the early phase of adult respiratory distress syndrome, with granulocyte sticking, endothelial cell adhesion and transendothelial diapedesis. Morphometric analysis demonstrated a significant decrease in alveolar diameter in both the injured and the contralateral lung due to impaired surfactant surface activity. A distinct increase in septal diameter, related to edema and caused by increased microvascular permeability, was found in the injured lungs. These findings emphasize that LC leads to a generalized impairment of the entire lung, which may lead to progressive lung failure.