Peter Hellstern

Relationship between factor XIII activity, fibrinogen, haemostasis screening tests and postoperative bleeding in cardiopulmonary bypass surgery

We investigated the relationship between factor XIII, fibrinogen, blood coagulation screening tests and postoperative bleeding in 98 patients undergoing cardiopulmonary bypass (CPB) surgery. All patients received aprotinin. Blood samples were collected preoperatively (T1),after termination of CPB (T2),12 h (T3) and 24 h (T4) after surgery to determine FXIII activity, fibrinogen, platelet count, prothrombin time (PT), activated partial thromboplastin time (APTT) and D-dimers (DD). Laboratory results were correlated with the chest tube drainage 24 h after surgery and compared between patients with 24-hour chest tube drain volumes in the lower (Group 1) with those in the upper tertile (Group 3). Median FXIII and fibrinogen levels dropped by 33.9% and 34.2%, respectively, during CPB. No association between FXIII activity and the extent of postoperative bleeding was found. However, chest tube bleeding was significantly correlated with preoperative and postoperative fibrinogen. This was confirmed by comparing Groups 1 and 3. Group 3 patients had significantly lower fibrinogen levels than Group 1 at T1 - T4, although most fibrinogen values were within or above the reference range (medians, g/l: 3.5 vs. 4.0, p = 0.043 at T1; 2.3 vs. 2.7, p = 0.015 at T2; 2.9 vs. 3.3, p = 0.008 at T3; 4.2 vs. 5.2, p = 0.002 at T4). There was also a significant relationship of platelet count, PT and APTT, as measured after CPB (T2), with postoperative chest tube drainage. In conclusion, plasma FXIII activity does not influence postoperative bleeding in patients undergoing CPB surgery. There is however an inverse association between preoperative or postoperative plasma fibrinogen levels and postoperative bleeding. These findings indicate a modulation of postoperative bleeding by fibrinogen levels.

Variables influencing Multiplate(TM) whole blood impedance platelet aggregometry and turbidimetric platelet aggregation in healthy individuals.

We investigated the relationship between impedance platelet aggregometry (IPA) as measured by the Multiplate™ system and turbidimetric platelet aggregation (TPA) induced by ADP, arachidonic acid (AA), and collagen; blood cell counts; platelet function analyzer (PFA-100™) closure times (CT), and von Willebrand factor (VWF) in 120 well-characterized healthy individuals. Pre-analytical and analytical conditions were standardized comprehensively. Analytical reliability of IPA and TPA and the influence of pre-analytical variables on assay results were also examined. IPA and TPA did not change significantly between 0.5 and 5 hours after blood collection when samples were stored at room temperature. TPA and IPA showed significantly greater intra-assay imprecision than respective TPA induced by the same agonists. Intra-individual variation did not differ significantly between IPA and TPA. The lower limits of reference range (2.5th percentiles) of AAIPA, ADPIPA and collagen IPA determined AM were 37, 20 and 40 AU, respectively. ADPIPA showed significantly lower maximum aggregation values than AAIPA and collagen IPA (P < 0.0001). There were no significant differences in any parameter between males and females. No significant differences between blood group 0 and non-0 individuals were noted with respect to IPA and TPA. IPA did not change significantly during the day. In contrast, TPA measured PM was significantly lower than corresponding values determined a.m. (p < 0.0001). CEPI-CT, CADP-CT and leukocyte counts increased significantly from a.m. to p.m. (P = 0.008 and P > 0.0001, respectively). Donors had significantly greater IPA induced by any agonist than non-donors (P-values < 0.0001, 0.0001 and 0.001, respectively), whereas TPA was not significantly different between donors and non-donors. IPA did not correlate significantly with TPA nor with PFA-100™ CT. ADPIPA and collagen IPA correlated significantly with platelet count. TPA was not associated with platelet count. An inverse significant correlation was observed between TPA induced by any agonist and leukocyte count, whereas leukocyte count did not influence IPA. CEPI-CT and CADP-CT correlated significantly with VWF:CBA and with each other but not with TPA. We concluded that IPA and TPA measure different aspects of platelet function. IPA results reflect interactions between platelets, red and white cells, while TPA does not. This explains discrepancies in associations of IPA and TPA with cell counts, time of day and blood donation. The clinical significance of IPA determined using the Multiplate™ device remains to be determined in studies on patients with platelet dysfunction and under treatment with antiplatelet agents.

The Use of Solvent/Detergent Treatment in Pathogen Reduction of Plasma

The solvent/detergent (SD) process used for plasma can safely inactivate all lipid-enveloped viruses. The introduction of a specific prion-binding ligand gel in combination with SD treatment, time-reduced from 4 to 1–1.5 h, still ensures efficient virus kill, reduces abnormal prion protein by >5 log steps, and preserves levels of plasmin inhibitor at close to the reference range. Infections with known non-enveloped viruses such as HAV or parvovirus B19 are prevented by ensuring low virus loads in the starting plasma units, dilution through pooling of single plasma units, and neutralization of immune antibodies already present in the initial plasma pools. The major advantages of SD plasma over fresh frozen plasma and the other pathogen-inactivated plasmas are its extreme safety with respect to transfusion-related acute lung injury and the significantly lower likelihood of provoking allergic reactions. Both advantages are best interpreted as results of the dilution effect of pooling. No fewer than 18 clinical studies covering all indications for plasma, and extensive clinical experience have shown that reduced levels of coagulation factors and inhibitors as a result of SD treatment do not impair significantly the clinical efficacy or tolerance of plasma. Properly standardized clotting factor and inhibitor potencies and low batch-to-batch variations when compared with single-donor plasma units makes SD plasma more suitable for standardized treatment.

Practical guidelines for the clinical use of plasma

Despite differences in the composition of fresh frozen plasma (FFP) and solvent/detergent-treated plasma, prospective controlled clinical trials have not revealed any significant difference in clinical efficacy and tolerance between the two types of plasma. Evidence of the clinical efficacy of plasma is mainly based on expert opinion, case reports, and on controlled and uncontrolled observational studies. The application of plasma without laboratory analysis to verify the coagulopathy is normally not justified. With the exception of emergency situations when timely clotting assay results are not available, the administration of plasma in coagulopathy must be verified both clinically and by laboratory analysis before plasma is administered. The rapid infusion of at least 10 ml plasma/kg of body weight is required to increase the respective plasma protein levels significantly. Based on the present state of knowledge, plasma is indicated for complex coagulopathy associated with manifest or imminent bleeding in massive transfusion, disseminated intravascular coagulation, and liver disease. Therapeutic plasma exchange with 40 ml plasma/kg of body weight is the treatment of first choice in acute thrombotic-thrombocytopenic purpura-adult hemolytic uremic syndrome (TTP-HUS). A rare indication is the treatment or prevention of bleeding in congenital factor V or factor XI deficiency, plasma exchange in neonates with severe hemolysis or hyperbilirubinemia, and filling of the oxygenator in extracorporeal membrane oxygenation (ECMO) in neonates. Prothrombin complex concentrates should be preferred to plasma for the reversal of oral anticoagulation in emergency situations, since controlled studies have shown a minor efficacy of plasma. Side effects resulting from the administration of plasma are rare but have to be considered.

Absence of Anti-Human Immunodeficiency Virus Types 1 and 2 Seroconversion after the Treatment of Hemophilia A or von Willebrand's Disease with Pasteurized Factor VIII Concentrate

Patients with hemophilia A or von Willebrands disease who are treated with concentrated preparations of human factor VIII made from unscreened pooled plasma are at substantial risk of contracting human immunodeficiency virus (HIV) infection. The purpose of this study was to investigate whether by treating such patients with a pasteurized factor VIII concentrate that had been heated in aqueous solution at 60 degrees C for 10 hours, HIV infection could be avoided. Eleven hemophilia centers in the Federal Republic of Germany and two in Austria identified 155 eligible patients who had been treated exclusively with pasteurized factor VIII concentrate and had not received any other blood products. Between February 1979 and December 1986 they received a total of 15,916,260 IU of pasteurized factor VIII. The United States was the source of 80 percent of the plasma from which the concentrate was made. By September 1988, these 155 patients had been screened for antibody to HIV type 1 (anti-HIV-1) with a total of 657 tests; all were negative. Sixty-seven patients were also tested once for antibody to HIV type 2 (anti-HIV-2); all these tests were negative as well. It appears that pasteurization effectively inactivates HIV, even in plasma that is likely to be highly contaminated with the virus.

Variables influencing Platelet Function Analyzer‐100TM closure times in healthy individuals

We investigated the relationship between platelet function analyzer (PFA‐100TM) closure times (CT) and bleeding time (BT), platelet aggregation (PA) induced by ADP, arachidonic acid, and collagen, blood cell counts, and von Willebrand factor (VWF) in 120 well‐characterised healthy individuals. Pre‐analytical and analytical conditions were standardised comprehensively. In a substantial number of cases the differences between duplicate measurements exceeded 15%. The reference range (5th and 95th percentiles) for CT with the collagen/epinephrine (CEPI) and the collagen/ADP (CADP) cartridge was 93–223 s and 64–117 s respectively. Re‐examination of 11 individuals with CEPI‐CT above the 95th percentile revealed considerable batch‐to‐batch variation of CEPI‐CT. Males had significantly longer CADP than females (P = 0·002). CEPI and CADP‐CT measured pm were significantly longer than corresponding values determined am (P = 0·003 and P < 0·0001 respectively). Blood group O was associated with greater CEPI and CADP‐CT and lower VWF levels compared with non‐O blood groups (P = 0·008, P = 0·0003 and P < 0·0001 respectively). Linear regression analysis revealed association between CEPI‐CT, CADP‐CT and VWF (P < 0·0001), but no relationship was found between CT and BT or between CT and PA. We conclude that VWF plasma levels modulate PFA‐100TM CT to a greater extent than platelet function. Establishment of reliable reference ranges and careful standardisation of pre‐analytical and analytical conditions is a prerequisite for obtaining reliable PFA‐100TM results. Duplicate measurements are necessary.

Manufacture and composition of fresh frozen plasma and virus-inactivated therapeutic plasma preparations: correlation between composition and therapeutic efficacy

The clinical efficacy of the therapeutic plasma used in the treatment of congenital and acquired severe coagulopathy depends on the potency of clotting factor and inhibitor activities. The composition of plasma strongly depends on the conditions under which it is produced. A low citrate anticoagulant-to-blood ratio, short intervals between donation and plasma separation and rapid freezing markedly improve the preservation of unstable coagulation factors. The influence of different leukocyte reduction filters on plasma quality still requires clarification. Recent trials on long-term storage conditions suggest that keeping plasma at -30 degrees C or colder over a period of 24-36 months prevents substantial decrease in clotting factor activities including factor VIII (FVIII). Three types of therapeutic plasma are currently available. Quarantine-stored fresh frozen plasma (FFP) contains physiological activities of therapeutically relevant plasma proteins, but carries a risk of transmitting blood-borne viruses that cannot be detected by human immunodeficiency virus (HIV) and hepatitis B and C screening. In contrast, solvent/detergent-treated plasma (SDP) and methylene blue/light-treated plasma (MBP) is virtually free of HIV and hepatitis C virus (HCV) subtypes. Virus inactivation procedures can have the consequence of reducing several clotting factors and inhibitors in SDP and MBP to varying degrees. However, pooling of plasma units before solvent/detergent (SD) treatment results in well-standardized protein levels of SDP. At least five prospective trials and four observational studies covering different clinical settings suggest that SDP and FFP do not substantially differ in their clinical efficacy or in their tolerance. By way of contrast, there is a lack of data about the clinical efficacy and tolerance of MBP compared to FFP.

Recurrent Pregnancy Loss and Its Relation to FV Leiden, FII G20210A and Polymorphisms of Plasminogen Activator and Plasminogen Activator Inhibitor

Thrombophilic disorders and hypofibrinolysis were demonstrated to be risk factors in a majority of women with recurrent pregnancy loss (RPL) and infertility. We investigated the association of FV G1691A mutation, F II G20210A gene polymorphism (PM), 4G/5G PAI-1 and Alu I/D tPA PM in 32 women with infertility and 49 women with at least 2 unexplained early abortions. FV Leiden mutation was significantly more common in women with RPL (10%, p = 0.02) and infertility (19%, p = 0.0005) compared with controls (2%). PAI-1 4G PM and t-PA Alu I PM, alone or in combination, were not associated with RPL or infertility. 9/49 women with RPL showed coagulation disorders with heterozygous FV Leiden mutation (5), FXII (1), protein C (1) or protein S (2) deficiency. However, due to the small number of patients studied, no definite conclusion can be drawn.

Production and Composition of Prothrombin Complex Concentrates: Correlation between Composition and Therapeutic Efficiency

Four-factor PCCs are most frequently used for replacement of vitamin K-dependent clotting factors and inhibitors proteins C and S in patients bleeding after phenprocoumon or warfarin overdose, in vitamin K-deficient patients presenting life-threatening bleeding, and liver disease. Since many of these patients are prone to thromboembolic complications including DIC, all conceivable measures should be taken against the thrombogenic potential of PCC preparations. This thrombogenic potential of PCCs is obviously dependent on several factors including activated clotting factors, lack of inhibitors of blood coagulation, and coagulation factor overload, as well as predisposing factors referred to recipients and drug interactions. The composition of PCC should meet the following criteria: Antithrombin in addition to heparin for the neutralization of FIXa and FXa should be present in the preparations; no overloading with FII and FX; substantially lower FVII than FIX potencies in order to minimize contamination with or generation of FVIIa; and substantial protein C as well as protein S activities. Quality control should include determinations as recommended by the European Pharmacopoeia. Specific assays for quantification of FIXa and FXa are urgently required, and validity of these assays must be proven in surveys. All lots should also be tested for their FVIIa content. Furthermore, the safety of PCCs must be proven by suitable animal models. Whenever possible, patients receiving PCCs should be under low-dose heparin prophylaxis; simultaneous administration of heparin-neutralizing drugs or antifibrinolytic agents must be avoided.

Indications for plasma in massive transfusion

The initial aim in massive transfusion (MT) is to supply crystalloids, colloids, and plasma-poor red cell concentrates (RCCs) to maintain normovolemia and oxygen supply. This frequently leads to dilution coagulopathy, which is frequently aggravated and accelerated by hypothermia, acidosis, shock-induced impairment of liver function and disseminated intravascular coagulation (DIC), and increased consumption of clotting factors and platelets at extensive wound sites. Disorders of hemostasis deteriorate the prognosis of massively transfused patients dramatically. Therefore, the second therapeutic objective is the timely administration of plasma and platelet concentrates as required to halt the microvascular bleeding (MVB) induced by impaired hemostasis. Close laboratory monitoring, to include as a minimum platelet count, prothrombin time (PT), activated partial thromboplastin time (APTT), and fibrinogen, is essential to identify hemostatic disorders requiring therapeutic intervention. Coagulopathy promoting microvascular bleeding can be assumed when PT or APTT values exceed 1.5 times mean controls and/or when fibrinogen levels fall below 1.0 g/l. Repeated rapid infusion of 10-15 ml plasma per kg of body weight will be required to raise clotting factor levels significantly and to achieve adequate hemostasis. The turnaround time for obtaining laboratory results and for readying plasma for transfusion must be taken into particular consideration in cases of rapid blood loss.