Calibrated automated thrombography displays the concentration of thrombin in clotting plasma with or without platelets (platelet-rich plasma/platelet-poor plasma, PRP/PPP) in up to 48 samples by monitoring the splitting of a fluorogenic substrate and comparing it to a constant known thrombin activity in a parallel, non-clotting sample. Thus, the non-linearity of the reaction rate with thrombin concentration is compensated for, and adding an excess of substrate can be avoided. Standard conditions were established at which acceptable experimental variation accompanies sensitivity to pathological changes. The coefficients of variation of the surface under the curve (endogenous thrombin potential) are: within experiment ∼3%; intra-individual: <5% in PPP, <8% in PRP; interindividual 15% in PPP and 19% in PRP. In PPP, calibrated automated thrombography shows all clotting factor deficiencies (except factor XIII) and the effect of all anticoagulants [AVK, heparin(-likes), direct inhibitors]. In PRP, it is diminished in von Willebrand’s disease, but it also shows the effect of platelet inhibitors (e.g. aspirin and abciximab). Addition of activated protein C (APC) or thrombomodulin inhibits thrombin generation and reflects disorders of the APC system (congenital and acquired resistance, deficiencies and lupus antibodies) independent of concomitant inhibition of the procoagulant pathway as for example by anticoagulants.
The binding of affinity-purified anticardiolipin antibodies (ACA) to liposomes that contained cardiolipin or phosphatidylserine was investigated. ACA bound to these liposomes only in the presence of plasma or serum, which indicated a requirement for a plasma component. This component--referred to as aca-cofactor--was purified; its activity to support ACA binding to liposomes that contained cardiolipin was not destroyed by heat (10 min at 90 degrees C), but was greatly diminished on incubation with trypsin. aca-cofactor bound liposomes that contained negatively charged phospholipid but had no affinity for liposomes that contained neutral phospholipid (eg, phosphatidylcholine); this binding was independent of calcium ions. aca-cofactor was essential for ACA to bind to liposomes that contained cardiolipin or phosphatidylserine and, when coated on a microtitre plate in the absence of any phospholipid, aca-cofactor was an apparent antigen for ACA in an enzyme-linked immunosorbent assay. aca-cofactor is a single chain polypeptide with an apparent molecular weight of 50 kD (non-reduced), which increases to 70 kD upon reduction, and its properties closely resemble those of beta 2-glycoprotein I (apolipoprotein H).
Key Points• Nonanticoagulant heparin is shown to bind histones and provide cytoprotection in mouse models of sterile inflammation and sepsis.Extracellular histones are considered to be major mediators of death in sepsis. Although sepsis is a condition that may benefit from low-dose heparin administration, medical doctors need to take into consideration the potential bleeding risk in sepsis patients who are already at increased risk of bleeding due to a consumption coagulopathy. Here, we show that mechanisms that are independent of the anticoagulant properties of heparin may contribute to the observed beneficial effects of heparin in the treatment of sepsis patients. We show that nonanticoagulant heparin, purified from clinical grade heparin, binds histones and prevents histone-mediated cytotoxicity in vitro and reduces mortality from sterile inflammation and sepsis in mouse models without increasing the risk of bleeding. Our results demonstrate that administration of nonanticoagulant heparin is a novel and promising approach that may be further developed to treat patients suffering from sepsis. (Blood. 2014;123(7):1098-1101) IntroductionSepsis and septic shock are serious clinical problems with high mortality rates for which no adequate treatment currently exists. 1Neutrophils respond to infection with the formation of neutrophil extracellular traps (NETs), 2,3 intricate networks containing DNA as the major structural component and proteins like histones and neutrophil elastase, which have antimicrobial properties. Extracellular histones, however, also exhibit cytotoxic activity toward host cells, including the endothelium. 4,5 Histone release can thus trigger a feedback cascade, resulting in more cell death and additional release of histones.6 Consequently, extracellular histones are considered interesting therapeutic targets for sepsis treatment. 4 Histones are positively charged, and NET-mediated cytotoxicity can be reduced with polysialic acid, a negatively charged polymer. 5 We hypothesized that heparin, a negatively charged polysaccharide, blocks histone cytotoxicity and reduces mortality from sterile inflammation and sepsis. Low dose unfractionated heparin (UFH) has been tested in a clinical trial as a complementary treatment of sepsis. 7 The study rationale linked infection, inflammation, and coagulation in sepsis and sought to inhibit the coagulation part with low doses of heparin so as not to increase the risk of bleeding in a patient who is already at risk due to sepsis-associated consumption coagulopathy. 7,8 Nevertheless, although this study failed to demonstrate a significant benefit on 28-day mortality rate, we hypothesize that the minor beneficial effects of heparin observed might be attributed to a mechanism independent of the anticoagulant properties of heparin. We reasoned that removing the anticoagulant fraction from UFH would yield an antithrombin affinity-depleted heparin (AADH) that neutralizes histone-mediated cytotoxicity and effectively treats sepsis without increasing risk of bleeding....
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