We identified risk factors associated with death and readmission to intensive care. It was not possible to produce a definitive model based on these risk factors for predicting death or readmission in an individual patient.
Summary. Proteins influencing plasminogen activation to plasmin, namely plasminogen activators tissue-type plasminogen activator (t-PA) and urokinase-type plasminogen activator (u-PA) and their principal inhibitors, plasminogen activator inhibitor 1 (PAI-1) and PAI-2, were measured in the plasma, the polymorph and mononuclear cell fractions taken from patients with major sepsis who were entering a general intensive care unit. The purpose of this study was to elucidate the factors favouring the persistence of fibrin in the microvasculature and thus contributing to multiple organ failure. Levels of u-PA antigen in plasma rose in sepsis and u-PA activity, not detectable in normal plasma, appeared. Levels of u-PA antigen in the cell fractions fell concomitantly. t-PA antigen in plasma and in the mononuclear cell fraction rose in sepsis, but t-PA activity was not detectable. Plasma PAI-1 antigen levels were strikingly raised in sepsis, presumably accounting for the complete neutralization of t-PA activity. PAI-2 antigen, not normally detected in plasma, appeared in the plasma of some patients, whereas it disappeared from the cellular fractions. Appearance of PAI-2 in plasma was associated with non-survival of the patient. The observations indicate that all the agents involved in plasminogen activation are released into the plasma in major sepsis. The levels of PAI-1 reached were quantitatively sufficient to suppress all activity of the released t-PA, but the inhibitors did not prevent expression of u-PA activity in the circulation. Circulating active u-PA and PAI-2 in the plasma of patients with severe sepsis may represent material originating from leucocytes. Leucocyte release of these agents within fibrin deposits may influence the persistence of fibrin and thus the development of multiple organ failure.
Normal human bone marrow from patients undergoing heart surgery was analysed quantitatively for components of the fibrinolytic system, using functional and immunological assays. Marrow was found to contain considerable fibrinolytic activity, reflecting high levels of t-PA (tissue-type plasminogen activator). The t-PA was in an active form, despite the presence of the inhibitors PAI-1 and PAI-2. Plasminogen and alpha2-antiplasmin (alpha2-AP) were also present in marrow. The balance of proteases and inhibitors differed dramatically from that observed in plasma, with higher levels of t-PA, PAI-1 and PAI-2, and lower levels of u-PA (urokinase), plasminogen, alpha2-AP and t-PA-PAI-1 complex in bone marrow, and resulted in favourable conditions for fibrinolysis. The presence of plasmin-alpha2-AP complex at concentrations of the same order of magnitude as total plasminogen and alpha2-AP demonstrated that active generation of plasmin was indeed occurring. A role for the active fibrinolytic system in normal human bone marrow may be the removal of unnecessary fibrin deposits formed in the cavities of the marrow, in order to maintain flow through this tissue.
Nitric oxide (NO) is an important physiological mediator of vascular tone and is thought to be involved in the pathogenesis of septic shock. Plasma nitrate is the stable end product of NO oxidation and in part reflects endogenous NO production. We measured plasma nitrate levels in 47 episodes of suspected septicaemia in 43 in-patients (16 male and 27 female, age 15-63 years). Nitrate concentrations were significantly higher (P < 0.01) compared to healthy controls. Further analysis revealed that significantly elevated levels occurred only in the septic patients who had normal or elevated numbers of neutrophils in the peripheral blood and were hypotensive on presentation. Failure of plasma nitrate concentrations to rise significantly in patients with neutropenia suggests that this cell type may be important in the activation of the arginine-NO system in severe sepsis in man.
SummaryLeucocytes, both polymorphs and mononuclear cells, play a variety of roles in the evolution of human response to sepsis, both local and generalised. In this study, inhibitors of plasminogen activator were measured in leucocytes from normal and septic patients. Plasminogen activator inhibitor-1 (PAI-1) was identified in polymorphs from normal individuals and levels rose significantly in polymorphs from septic patients: neutrophils from normal subjects did not contain PAI-2 but this protein was detectable in significant quantities in polymorph preparations from septic patients. In contrast, mononuclear cells from normal and septic patients contained no detectable quantities of PAI-1. Significant amounts of PAI-2 were present in normal mononuclear cells, and the levels rose significantly in monocytes from septic patients. PAI-2 is thus here identified in human subjects, distinct from those with pregnancy or malignancy, as playing a role in a pathological process. The increased levels of both inhibitors produced by leucocytes may clearly contribute directly to the persistence of fibrin, a characteristic feature of the response to infection, local or general; they may thus participate in successful localisation of infections (abscess formation etc.) and in the evolution of the major systemic complications of disseminated sepsis characterised by microvascular occlusion by fibrin such as renal failure, shock lung or digital ischaemia.
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