Clinical use of thrombin generation assays.

Determining patient's coagulation profile, i.e. detecting a bleeding tendency or the opposite, a thrombotic risk, is crucial for clinicians in many situations. Routine coagulation assays and even more specialized tests may not allow a relevant characterization of the hemostatic balance. In contrast, thrombin generation assay (TGA) is a global assay allowing the dynamic continuous and simultaneous recording of the combined effects of both thrombin generation and thrombin inactivation. TGA thus reflects the result of procoagulant and anticoagulant activities in blood and plasma. Because of this unique feature, TGA has been widely used in a wide array of settings from both research, clinical and pharmaceutical perspectives. This includes diagnosis, prognosis, prophylaxis, and treatment of inherited and acquired bleeding and thrombotic disorders. In addition, TGA has been shown to provide relevant information for the diagnosis of coagulopathies induced by infectious diseases, comprising also disturbance of the coagulation system in COVID-19, or for the assessment of early recurrence in breast cancer. This review article aims to document most clinical applications of TGA.

Thrombin generation assays are versatile tools in blood coagulation analysis: A review of technical features, and applications from research to laboratory routine.

Thrombin is the pivotal enzyme in the biochemistry of secondary hemostasis crucial to maintaining homeostasis of hemostasis. In contrast to routine coagulation tests (PT or aPTT) or procoagulant or anticoagulant factor assays (e.g. fibrinogen, factor VIII, antithrombin or protein C), the thrombin generation assay (TGA), also named thrombin generation test (TGT) is a so-called "global assay" that provides a picture of the hemostasis balance though a continuous and simultaneous measurement of thrombin formation and inhibition. First described in the early 1950s, as a manual assay, efforts have been made in order to standardize and automate the assay to offer researchers, clinical laboratories and the pharmaceutical industry a versatile tool covering a wide range of clinical and non-clinical applications. This review describes technical options offered to properly run TGA, including a review of preanalytical and analytical items, performance, interpretation, and applications in physiology research and pharmacy.

The Dual Role of a Polyvalent IgM/IgA-Enriched Immunoglobulin Preparation in Activating and Inhibiting the Complement System.

Activation of the complement system is important for efficient clearance of a wide variety of pathogens via opsonophagocytosis, or by direct lysis via complement-dependent cytotoxicity (CDC). However, in severe infections dysregulation of the complement system contributes to hyperinflammation. The influence of the novel IgM/IgA-enriched immunoglobulin preparation trimodulin on the complement pathway was investigated in in vitro opsonophagocytosis, binding and CDC assays. Immunoglobulin levels before and after trimodulin treatment were placed in relation to complement assessments in humans. In vitro, trimodulin activates complement and induces opsonophagocytosis, but also interacts with opsonins C3b, C4b and anaphylatoxin C5a in a concentration-dependent manner. This was not observed for standard intravenous IgG preparation (IVIg). Accordingly, trimodulin, but not IVIg, inhibited the downstream CDC pathway and target cell lysis. If applied at a similar concentration range in healthy subjects, trimodulin treatment resulted in C3 and C4 consumption in a concentration-dependent manner, which was extended in patients with severe community-acquired pneumonia. Complement consumption is found to be dependent on underlying immunoglobulin levels, particularly IgM, pinpointing their regulative function in humans. IgM/IgA provide a balancing effect on the complement system. Trimodulin may enhance phagocytosis and opsonophagocytosis in patients with severe infections and prevent excessive pathogen lysis and release of harmful anaphylatoxins.

Functional relevance of in vivo half antibody exchange of an IgG4 therapeutic antibody-drug conjugate.

An increasing number of monoclonal antibodies and derivatives such as antibody-drug conjugates (ADC) are of the IgG1 and IgG4 isotype with distinct structural and functional properties. In cases where antibody-mediated cytotoxicity is not desired, IgG4 is often used, as its Fc region is relatively poor at inducing antibody-dependent cell-mediated or complement-dependent cytotoxicity. IgG4 ADCs with highly cytotoxic drugs against proliferating target cells but which lack or have diminished antibody effector functions against quiescent cells may have a favorable safety profile compared to IgG1. Another unique property of the IgG4 subclass is the capability to exchange half antibodies in vivo creating randomly bispecific antibodies. To investigate the functional properties of process-derived antibody species, and determine the influence of shuffling on the therapeutic efficacy, several model antibodies on the basis of the anti-CD138 antibody-drug conjugate BT062 (Indatuximab ravtansine) were generated: (I) A wild type nBT062, (II) a stable nBT062 comprising mutations to prevent half-antibody exchange, (III) a half nBT062 lacking covalent binding between two heavy chains and (IV) a stabilized, bispecific nBT062-natalizumab antibody with a second, monovalent specificity against CD49d. All nBT062 model variants were capable of CD138-specific binding and antigen-mediated internalization into cells. Furthermore, all nBT062 models inhibited tumor growth in vitro after conjugation with the maytansinoid DM4. The in vivo effects of the different molecular variants were assessed in the MAXF1322 xenograft model. The bispecific nBT062-natalizumab-DM4 demonstrated the least efficacy and was only moderately active even without the co-administration of a human IgG preparation. Wild type, stable and half nBT062-DM4 models demonstrated great anti-tumor activities. The efficacy of wild type and half nBT062-DM4 was reduced in the presence of IgG, while stable nBT062-DM4 was only marginally influenced. These pre-clinical data demonstrate the advantage of introducing half-antibody exchange-preventing mutations into therapeutic IgG4-based antibody drug-conjugates.

Functional Properties of Human Cytomegalovirus Hyperimmunoglobulin and Standard Immunoglobulin Preparations.

BACKGROUND Cytomegalovirus hyperimmunoglobulin (CMV-HIG) preparations reduce mortality after solid organ transplantation. Polyspecific intravenous immunoglobulin (IVIg) products are also used prophylactically by some centers. Since direct comparative characterizations of the preparations are scarce, it is challenging to compare different clinical studies. MATERIAL AND METHODS The functionality of 2 CMV-HIG preparations (Cytotect® CP, Cytogam®) and 2 IVIg preparations (Ig Vena®, Flebogamma®) were compared in terms of: (i) CMV-specific immunoglobulin G (IgG) antibody levels determined by enzyme-linked immunoabsorbent assay (ELISA), (ii) avidity index using a CMV IgG avidity enzyme immunoassay, (iii) immunoblot assay against CMV-specific antigens, and (iv) anti-CMV microneutralization assay. RESULTS Median CMV-specific IgG antibody concentration was similar in the 2 CMV-HIG preparations (Cytotect® CP 101.8 PEIU/ml, Cytogam® 112.5 PEIU/ml) but markedly lower in the IVIg preparations (13.5 PEIU/ml and 21.3 PEIU/ml). CMV binding avidity was virtually identical for both CMV-HIG products (~90%). Immunoblot assay showed consistently high binding of both CMV-HIG preparations against all antigenic CMV glycoproteins tested. Recognition of some CMV-specific antigens (IE1, CM2, and p65) was weaker for the 2 IVIg products. Median CMV neutralizing antibody titers were identical for both CMV-HIG preparations (1:256), and 4-fold lower (1:64) for the IVIg products. CMV IgG antibody concentration correlated with the CMV neutralization titer. CONCLUSIONS Compared to the polyspecific IVIg products tested here, CMV-HIG preparations showed higher CMV binding activity and wider recognition of tested CMV-specific glycoprotein antigens, with markedly higher neutralizing activity. There do not appear to be any relevant distinctions between the Cytotect® CP and Cytogam® CMV-HIG products in terms of functional activity.