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Abstract Objective To compare the impact on thrombin generation of the new combined oral contraceptive containing 15 mg estetrol and 3 mg drospirenone with ethinylestradiol (30 or 20 mcg) associated either with 150 mcg levonorgestrel or with 3 mg drospirenone. Methods Data were collected from the “E4/DRSP Endocrine Function, Metabolic Control and Hemostasis Study” (NCT02957630). Overall, the per-protocol set population included 24 subjects in the ethinylestradiol/levonorgestrel arm, 28 subjects in the ethinylestradiol/drospirenone arm, and 34 subjects in the estetrol/drospirenone arm. Thrombograms and thrombin generation parameters (lag time, peak, time to peak, endogenous thrombin potential, and mean velocity rate index) were extracted for each subject at baseline and after 6 cycles of treatment. Results After 6 cycles of treatment, ethinylestradiol-containing products arms show a mean thrombogram outside the upper limit of the reference range, that is the 97.5th percentile of all baseline thrombograms. On the other hand, the mean thrombogram of estetrol/drospirenone is within this reference interval. After 6 cycles of treatment, all thrombin generation parameters are statistically less affected by estetrol/drospirenone than ethinylestradiol-containing products. Conclusions In conclusion, an association of 15 mg estetrol with 3 mg drospirenone does not have an impact on thrombin generation compared with ethinylestradiol-containing products that, either associated with levonorgestrel or drospirenone, are able to increase the production of procoagulant factors and decrease the production of anticoagulant ones, shifting the patient to a prothrombotic state. Ethinylestradiol-containing products thus generate prothrombotic environments contrary to estetrol which demonstrates a neutral profile on hemostasis.

Microvesicles were isolated from the conditioned media of 3 cell lines (MDA-MB-231, AsPC-1 and A375) by ultracentrifugation at a range of relative centrifugal forces, and the tissue factor (TF) protein and activity, microvesicle number, size distribution and relative density compared. Also, by expressing TF-tGFP in cells and isolating the microvesicles, the relative density of TF-containing microvesicles was established. Nanoparticle tracking analysis (NTA) indicated that the larger-diameter microvesicles (>200 nm) were primarily sedimented at 100,000g and possessed TF-dependent thrombin and factor Xa generation potential, while in the absence of factor VII, all microvesicles possessed some thrombin generation capacity. Immuno-precipitation of TF-containing microvesicles followed by NTA also indicated the range of these microvesicles to be 200-400 nm. Analysis of the microvesicles by gradient density centrifugation showed that lower-density (<1.1 g/ml) microvesicles were mainly present in the samples recovered at 100,000g and were associated with TF antigen and activity. Analysis of these fractions by NTA confirmed that these fractions were principally composed of the larger-diameter microvesicles. Similar analysis of microvesicles from healthy or patient plasma supported those obtained from conditioned media indicating that TF activity was mainly associated with lower-density microvesicles. Furthermore, centrifugation of healthy plasma, supplemented with TF-tGFP-containing microvesicles, resulted in 67% retrieval of the fluorescent microvesicles at 100,000g, but only 26% could be recovered at 20,000g. Pre-centrifugation of conditioned media or plasma at 10,000g improved the speed and yield of recovered TF-containing microvesicles by subsequent centrifugation at either 20,000g or 100,000g. In conclusion, TF appears to be associated with low-density (1.03-1.08 g/ml), larger-diameter (200-350 nm) microvesicles.

Fibrinogen is a well-known risk factor for arterial and venous thrombosis. Its function is not restricted to clot formation, however, as it partakes in a complex interplay between thrombin, soluble plasma fibrinogen, and deposited fibrin matrices. Fibrinogen, like thrombin, participates predominantly in hemostasis to maintain vascular integrity, but executes some important pleiotropic effects: firstly, as observed in thrombin generation experiments, fibrin removes thrombin from free solution by adsorption. The adsorbed thrombin is protected from antithrombins, notably α2-macroglobulin, and remains physiologically active as it can activate factors V, VIII, and platelets. Secondly, immobilized fibrinogen or fibrin matrices activate monocytes/macrophages and neutrophils via Mac-1 interactions. Immobilized fibrin(ogen) thereby elicits a pro-inflammatory response with a reciprocal stimulating effect of the immune system on coagulation. In contrast, soluble fibrinogen prohibits recruitment of these immune cells. Thus, while fibrin matrices elicit a procoagulant response, both directly by protecting thrombin and indirectly through the immune system, high soluble fibrinogen levels might protect patients due to its immune diminutive function. The in vivo influence of the ‘protective’ plasma fibrinogen versus the ‘pro-thrombotic’ fibrin matrices on thrombosis should be explored in future research.

Abstract Context Testosterone therapy has been variably associated with increased thrombotic risk but investigations of global coagulation in this setting are lacking. Objective This work aimed to compare global coagulation of hypogonadal men before (T0) and 6 months after (T1) starting testosterone replacement therapy (TRT), and healthy controls (HCs). Methods An observational prospective cohort study was conducted at 2 tertiary endocrinological ambulatory care centers. Patients included 38 men with hypogonadism (mean age 55 years, SD 13) and 38 age-matched HCs. Thrombin generation assay (TGA) was performed at T0 and T1 in hypogonadal men and in HCs. TGA is an in vitro procedure based on the continuous registration of thrombin generation and decay under conditions mimicking the process that occurs in vivo. The following TGA parameters were recorded: lag time; thrombin-peak concentration; time-to-reach peak, velocity index, and endogenous thrombin potential (ETP), the latter representing the total amount of thrombin generated under the driving forces of procoagulants opposed by the anticoagulants. Protein C, antithrombin, factor (F) VIII, and fibrinogen were assessed. Results No changes in TGA parameters were observed between T0 and T1. Hypogonadal men displayed significantly higher ETP, fibrinogen, and significantly lower antithrombin levels both at T0 and T1 compared to HCs. Thrombin peak of hypogonadal men was significantly higher than HCs at T0 but not at T1. ETP and antithrombin were correlated with testosterone levels. Conclusion Hypogonadal men display a procoagulant imbalance detected by increased thrombin generation. Short-term TRT does not worsen global coagulation, suggesting that the treatment can be safely prescribed to men diagnosed with hypogonadism.

Dabigatran acylglucuronide, an active metabolite of dabigatran, exhibits higher plasma concentrations and distinct anticoagulant effects compared to dabigatran, suggesting that it may play a more significant role in overall anticoagulant activity than previously assumed. Idarucizumab, a monoclonal antibody fragment, binds to both free and thrombin-bound dabigatran, neutralizing its anticoagulant effects. However, its efficacy in reversing anticoagulation induced by dabigatran acylglucuronide remains unclear. This study aimed to evaluate whether idarucizumab differentially reverses the anticoagulant effects of dabigatran and dabigatran acylglucuronide. In vitro experiments were conducted using blood from healthy, drug-free donors. Plasma samples were spiked with either dabigatran or dabigatran acylglucuronide, followed by idarucizumab. Standard coagulation assays, including prothrombin time (PT), activated partial thromboplastin time (aPTT), thrombin time (TT), as well as thrombin generation assays (TGA), were performed. At a concentration of 1 µM, idarucizumab demonstrated significantly greater reversal of dabigatran acylglucuronide-induced anticoagulation than that of dabigatran in PT, aPTT, and TT assays. Consistently, TGA showed stronger neutralization of dabigatran acylglucuronide, with IC 50 values for C max , endogenous thrombin potential, and lag time at least 2.0-fold higher than those of dabigatran. These findings indicate that idarucizumab exerts a more potent reversal effect on dabigatran acylglucuronide compared to dabigatran.

Thrombin generation (TG) is reduced after cardiac surgery using cardiopulmonary bypass (CPB), contributing to coagulopathy and bleeding. Plasma transfusion or four-factor prothrombin complex concentrate (PCC) are commonly used to treat coagulopathic bleeding after CPB without knowledge of how each may restore TG. To determine the effect of PCC infusion on restoration of thrombin generation compared with plasma transfusion, we performed a laboratory-based secondary analysis of a randomized, controlled trial of adult patients undergoing cardiac surgery to assess efficacy and safety of 4 F-PCC versus plasma for treatment of perioperative coagulopathic bleeding after CPB. Participants were randomized to receive either PCC (15 IU/kg) or plasma (10–15 ml/kg) after separation from CPB. Participant blood samples were obtained at pre-specified serial timepoints, with laboratory assays for TG and factor levels subsequently performed. The primary outcome was change in thrombin generation (TG) parameters after each randomized treatment through postoperative day 5. Secondary outcomes included serially derived clotting factor levels. Of 100 randomized participants, 99 were included in this laboratory analysis (PCC group, N  = 51; plasma group, N  = 48). After treatment, participants in the PCC group compared with those in the plasma group showed higher endogenous thrombin potential (ETP, Median, Interquartile range, IQR: 688 [371–1069] vs. 1088 [550–1691] nM minutes, P  = 0.01), a greater increase din ETP ( P  = 0.002) and peak TG ( P  = 0.01) in the timepoints between heparin reversal and after treatment administration. Both groups demonstrated similar values in all TG assays by postoperative day 1 ( P  > 0.05). The PCC group also demonstrated higher levels of proteins C, S, and Factors II, VII, IX and X, early after treatment ( P  < 0.001 for all comparisons). Antithrombin levels were initially higher in the plasma group after treatment (Median, IQR: 66% [61-71%] vs. 56% [51-65%], P  = 0.002) but differences did not persist beyond postoperative day 3. In this laboratory analysis from a recent randomized trial in adult cardiac surgery, PCC administration restored thrombin generation more rapidly than plasma in the early postoperative period without laboratory evidence of hypercoagulability. ClinicalTrials.gov identifier: NCT02557672 [1]. Key points Question How does prothrombin complex concentrate (PCC) compare with plasma to restore thrombin generation (TG) in patients with coagulopathic bleeding after cardiopulmonary bypass? Findings In this subanalysis of a randomized clinical trial in 99 adult cardiac surgical patients, TG was restored more rapidly in the PCC group compared with the plasma group after treatment: endogenous thrombin potential (PCC, 688 [371–1069] vs. plasma, 1088 [550–1691], P  = 0.01nM minutes). Both groups displayed similar post-treatment TG by postoperative day one. Meaning These results support PCC administration to restore TG while avoiding acquired hypercoagulability in the early period after cardiac surgery.

Hypercoagulability and endothelial dysfunction are strongly involved in the worsening of the clinical condition in COVID-19 patients. In severe cases, the inflammatory process triggers the release of angiopoietin 2, which could decrease circulating thrombomodulin (TM), a major regulatory mechanism in thrombin generation. Although some studies have described an increased TM resistance, further data are needed to obtain robust results. The objective of our study was to evaluate TM resistance in hospitalized COVID-19 patients using the thrombin generation test and its correlation with development of any severe clinical events (SCE). Forty-seven hospitalized COVID-19 patients were included (median age was 59 years (50–75); 42.6% women). Measurement of endogenous thrombin potential (ETP) revealed that 54.8% of patients had a percentage (%) of ETP inhibition < 40%, suggesting TM resistance. 23% (23%) of patients ( n  = 11/47) presented at least one SCE. Significant resistance to TM was observed in patients with SCE: percentage (%) of ETP inhibition was 24.3% vs. 47.6% ( p  = 0.019) in the non-SCE group. Furthermore, lower percentage (%) of ETP inhibition significantly correlated with increased clot stiffness ( r = -0.372, p  = 0.0167). The percentage (%) of ETP inhibition was a strong predictor of SCE, with an AUC of 0.803 (95%CI: 0.670–0.936). To conclude, thrombin generation can be a powerful tool for risk stratification in hospitalized COVID-19 patients. In addition, increased TM resistance, quantified by a lower percentage (%) of ETP inhibition is strongly associated with the development of SCE and shows promise as a powerful and new independent marker of poor prognosis.

The high occurrence of cancer-associated thrombosis is associated with elevated thrombin generation. Tumour cells increase the potential for thrombin generation both directly, through the expression and release of procoagulant factors, and indirectly, through signals that activate other cell types (including platelets, leukocytes and erythrocytes). Furthermore, cancer treatments can worsen these effects. Coagulation factors, including tissue factor, and inhibitors of coagulation are altered and extracellular vesicles (EVs), which can promote and support thrombin generation, are released by tumour and other cells. Some phosphatidylserine-expressing platelet subsets and platelet-derived EVs provide the surface required for the assembly of coagulation factors essential for thrombin generation in vivo. This review will explore the causes of increased thrombin production in cancer, and the availability and utility of tests and biomarkers. Increased thrombin production not only increases blood coagulation, but also promotes tumour growth and metastasis and as a consequence, thrombin and its contributors present opportunities for treatment of cancer-associated thrombosis and cancer itself.

There is ongoing debate as to whether abacavir (ABC) increases the risk for cardiovascular disease(CVD) in people living with HIV (PLHIV) and the mechanisms underlying this possible association. We recently showed that the use of an ABC-containing regimen was independently associated with increased thrombin generation (TG). In the present study, we aim to explore these findings further, by studying the mechanistical processes that underly the global thrombin generation test via thrombin dynamics analysis. Thrombin dynamics analysis can pinpoint the cause of increased thrombin generation associated with ABC-use either to the procoagulant prothrombin conversion pathway or the anticoagulant thrombin inactivation pathway. In this cross-sectional study, 208 virally suppressed PLHIV were included, of whom 94 were on a ABC-containing regimen, 92 on a tenofovir disoproxil fumarate (TDF)-containing regimen, and the remainder on other regimens. We used Calibrated Automated Thrombinography to measure thrombin generation and perform thrombin dynamics analysis. The total amount of prothrombin conversion, as well as the maximum rate of prothrombin conversion were significantly increased in PLHIV on an ABC containing regimen compared to other treatment regimens. The levels of pro- and anticoagulant factors were comparable, indicating that the ABC-induced changes affect the kinetics of prothrombin conversion rather than procoagulant factor levels. Moreover, Von Willebrand Factor (VWF), active VWF and VWF pro-peptide levels were significantly higher in PLHIV than controls without HIV. However, they did not differ between ABC and non-ABC treated participants.

Platelet extracellular vesicles (PEVs) have emerged as potential mediators in intercellular communication. PEVs exhibit several activities with pathophysiological importance and may serve as diagnostic biomarkers. Here, imaging and analytical techniques were employed to unveil morphological pathways of the release, structure, composition, and surface properties of PEVs derived from human platelets (PLTs) activated with the thrombin receptor activating peptide (TRAP). Based on extensive electron microscopy analysis, we propose four morphological pathways for PEVs release from TRAP-activated PLTs: (1) plasma membrane budding, (2) extrusion of multivesicular α-granules and cytoplasmic vacuoles, (3) plasma membrane blistering and (4) “pearling” of PLT pseudopodia. The PLT extracellular vesiculome encompasses ectosomes, exosomes, free mitochondria, mitochondria-containing vesicles, “podiasomes” and PLT “ghosts”. Interestingly, a flow cytometry showed a population of TOM20 + LC3 + PEVs, likely products of platelet mitophagy. We found that lipidomic and proteomic profiles were different between the small PEV (S-PEVs; mean diameter 103 nm) and the large vesicle (L-PEVs; mean diameter 350 nm) fractions separated by differential centrifugation. In addition, the majority of PEVs released by activated PLTs was composed of S-PEVs which have markedly higher thrombin generation activity per unit of PEV surface area compared to L-PEVs, and contribute approximately 60% of the PLT vesiculome procoagulant potency.