Long-Term Safety Analysis of a Fibrinogen Concentrate (RiaSTAP®/Haemocomplettan® P).

Fibrinogen concentrate treatment is recommended for acute bleeding episodes in adult and pediatric patients with congenital and acquired fibrinogen deficiency. Previous studies have reported a low risk of thromboembolic events (TEEs) with fibrinogen concentrate use; however, the post-treatment TEE risk remains a concern. A retrospective evaluation of RiaSTAP®/Haemocomplettan® P (CSL Behring, Marburg, Germany) post-marketing data was performed (January 1986-June 2022), complemented by a literature review of published studies. Approximately 7.45 million grams of fibrinogen concentrate was administered during the review period. Adverse drug reactions (ADRs) were reported in 337 patients, and 81 (24.0%) of these patients experienced possible TEEs, including 14/81 (17.3%) who experienced fatal outcomes. Risk factors and the administration of other coagulation products existed in most cases, providing alternative explanations. The literature review identified 52 high-ranking studies with fibrinogen concentrate across various clinical areas, including 26 randomized controlled trials. Overall, a higher number of comparative studies showed lower rates of ADRs and/or TEEs in the fibrinogen group versus the comparison group(s) compared with those that reported higher rates or no differences between groups. Post-marketing data and clinical studies demonstrate a low rate of ADRs, including TEEs, with fibrinogen concentrate treatment. These findings suggest a favorable safety profile of fibrinogen concentrate, placing it among the first-line treatments effective for managing intraoperative hemostatic bleeding.

Clinical observation of hypofibrinogenemia induced by the treatment of tocilizumab in rheumatic diseases and exploration of risk factor for hypofibrinogenemia.

OBJECTIVE: The objective of this study was to analyze the changes in plasma fibrinogen (FIB) levels during tocilizumab (TCZ) treatment in patients with rheumatic diseases, to clarify the incidence of hypofibrinogenemia and its possible risk factors, and to establish a nomogram model for predicting the probability of hypofibrinogenemia in rheumatoid arthritis (RA) patients treated with TCZ. METHODS: Clinical data of patients treated with TCZ at the Department of Rheumatology and Immunology, the First Affiliated Hospital of Xi'an Jiaotong University from January 2014 to October 2021 were retrospectively analyzed to observe the incidence of hypofibrinogenemia in several rheumatic diseases at different time points. The risk factor of hypofibrinogenemia in RA patients treated with TCZ was determined by using Cox regression analysis. Based on the results of Cox regression analysis, a nomogram for predicting the probability of hypofibrinogenemia in rheumatoid arthritis (RA) patients treated with TCZ was established and validated through RStudio software. RESULTS: A total of 83 TCZ-treated patients were enrolled in this study, and 32 (38.55%) patients developed hypofibrinogenemia during TCZ treatment. There were 8 males and 24 females in the FIB-reduced group, with an average age of 44.88 ± 18.39 years. Hypofibrinogenemia was most common in TCZ-treated patients with takayasu arteritis (TA) and RA. Hypofibrinogenemia typically occured within 3 months after TCZ treatment. In RA patients treated with TCZ, platelet distribution width, parathyroid hormone, bone mineral density, tender joint count, and swollen joint count were independent risk factors for the occurrence of hypofibrinogenemia. The nomogram based on the above risk factors could effectively predict the probability of hypofibrinogenemia in RA patients receiving TCZ. CONCLUSION: Although bleeding symptoms were not observed in this study, the incidence of hypofibrinogenemia remained high after TCZ treatment, usually occurring within 3 months of treatment. Therefore, it is necessary to monitor FIB levels during TCZ treatment. In addition, clinicians can use the nomogram model developed from this study to predict the incidence of hypofibrinogenemia after TCZ treatment in RA patients. Key Points • Hypofibrinogenemia often occurs during TCZ treatment for rheumatic diseases. • PDW, PTH, BMD, tender joint count, and swollen joint count are risk factors for the occurrence of hypofibrinogenemia. • It is necessary to monitor FIB levels during TCZ treatment to avoid bleeding tendency.

Prospective, Randomized Study of Fibrinogen Concentrate Versus Cryoprecipitate for Correcting Hypofibrinogenemia in Cardiac Surgery Patients.

OBJECTIVE: Cardiac surgery with cardiopulmonary bypass (CPB) is associated with hypofibrinogenemia and severe bleeding requiring transfusion. Guidelines recommend cryoprecipitate or fibrinogen concentrate (FC) for the treatment of acquired hypofibrinogenemia. This study compared cryoprecipitate and FC for the correction of acquired hypofibrinogenemia and the associated costs. DESIGN: A single-center, prospective, randomized study evaluating patients with hypofibrinogenemia after cardiac surgery. The primary endpoint was direct treatment cost. Secondary endpoints included the change in fibrinogen level after FC and/or cryoprecipitate dosing. SETTING: A single-center study in Astana, Kazakhstan. PARTICIPANTS: Participants who underwent CPB from 2021 to 2022 and developed clinically significant bleeding and hypofibrinogenemia. INTERVENTIONS: Patients were randomized to receive cryoprecipitate or FC. MEASUREMENTS AND MAIN RESULTS: Eighty-eight adult patients with acquired hypofibrinogenemia (<2.0 g/L) after CPB were randomized to receive cryoprecipitate (N = 40) or FC (N = 48), with similar demographics between groups. Overall, mean ± SD 9.33 ± 0.94 units (range, 8-10) cryoprecipitate or 1.40 ± 0.49 g (1-2) FC was administered to the 2 groups. From before administration to 24 hours after, mean plasma fibrinogen increased by a mean ± SD of 125 ± 65 and 96 ± 65 mg/dL in the cryoprecipitate and FC groups, respectively. At 48 hours after administration, there was no significant difference in fibrinogen levels between groups. The mean direct cost of treatment with FC was significantly lower than with cryoprecipitate (p < 0.0001): $1,505.06 ± $152.40 and $631.75 ± $223.67 per patient for cryoprecipitate and FC, respectively. CONCLUSION: Analysis of plasma fibrinogen concentration showed that cryoprecipitate and FC had comparable effectiveness. However, FC is advantageous over cryoprecipitate due to its ease of handling, lower cost, and high purity.

Nomogram for the prediction of tigecycline-induced hypofibrinogenaemia in a Chinese population.

BACKGROUND: Tigecycline has been widely used for multi-drug-resistant bacterial infections in China. Although many studies have reported the risk factors for tigecycline-induced hypofibrinogenaemia, it remains unknown whether valproic acid or voriconazole in combination with tigecycline is associated with the decrease in fibrinogen, as both drugs could lead to coagulation disorders. The aim of this study was to develop a nomogram for the prediction of tigecycline-induced hypofibrinogenaemia. METHODS: This was a multi-centre retrospective case-control study. The primary outcome was the accurate prediction of tigecycline-induced hypofibrinogenaemia. Nomograms were developed from logistic regression models with least absolute shrinkage and selection operator regression for variable selection. Model performance was assessed via calibration plots, and models were validated internally using bootstrapping on a validation cohort. RESULTS: In total, 2362 patients were screened, of which 611 were eligible for inclusion in this study. These 611 patients were divided into the training cohort (n=488) and the validation cohort (n=123). Predictors included in the nomogram for the total population were total dose, age, fibrinogen, prothrombin time (PT), comorbidity, and concomitant use of voriconazole. Total dose, fibrinogen, PT, activated partial thromboplastin time, white blood cell count, and concomitant use of voriconazole were selected to predict hypofibrinogenaemia in patients with malignant haematologic diseases. Both models were calibrated adequately, and their predictions were correlated with the observed outcome. The cut-offs for treatment duration in the total population and the subgroup were 10 and 6 days, respectively. CONCLUSIONS: Tigecycline in combination with voriconazole could increase the risk of hypofibrinogenaemia, and tigecycline-induced hypofibrinogenaemia is more likely to occur in patients with malignant haematologic diseases.

The prevalence and risk factors of coagulopathy in pediatric patients undergoing surgery for epilepsy.

OBJECTIVE: Hematological consequences of novel antiseizure medications (ASMs) or combined therapies are rarely reported, especially in pediatric patients undergoing surgery for epilepsy. This study aimed to assess the prevalence and risk factors of coagulation dysfunction in this population and evaluate their relationship with intra- and postoperative bleeding. METHODS: Three hundred ninety children who underwent surgery for epilepsy and 104 children without epilepsy who underwent nonepilepsy surgery at the authors' center were included in the study. The authors retrospectively collected and analyzed the following clinical data: sex, age, weight, course of epilepsy, antiseizure therapy, first laboratory data after admission, and transfusion-related data. RESULTS: ASMs were responsible for the higher incidence of coagulation dysfunction in pediatric epilepsy surgery patients. Low body weight (OR 0.95, 95% CI 0.92-0.98) and valproic acid (VPA) therapy (OR 5.13, 95% CI 3.25-8.22) were the most relevant factors leading to coagulation dysfunction. The most common hematological side effects of VPA were thrombocytopenia and hypofibrinogenemia, whereas low body weight was only associated with hypofibrinogenemia. Both VPA and low body weight increased the need for intra- or postoperative transfusion (p < 0.001). CONCLUSIONS: Pediatric epilepsy surgery patients often take multiple ASMs, resulting in an increased incidence of coagulopathy. VPA levels and low body weight were found to be the main influential factors associated with an increased risk of coagulation dysfunction. Platelet and fibrinogen levels were the main indices that were affected. Both VPA and low body weight were relevant to additional surgery-related transfusion, necessitating the need for increased awareness of preoperative coagulopathy before pediatric epilepsy surgery. Clinical trial registration no.: NCT05675254 (ClinicalTrials.gov).

Safety of Tigecycline in Patients on Antithrombotic Therapy: A Single-Center Retrospective Study.

INTRODUCTION: The aims of the study were to investigate the risk factors of tigecycline-induced hypofibrinogenemia and to evaluate the safety of tigecycline with concomitant antithrombotic drugs. METHODS: We performed a retrospective analysis of patients who received tigecycline for more than 3 days between January 2015 and June 2019. Clinical and laboratory data were collected including fibrinogen concertation, tigecycline dose, duration of treatment, disease severity, complete blood count, indicators of infection, liver and renal function. Risk factors of hypofibrinogenemia were analyzed by univariate and multivariate analysis. To evaluate the safety of tigecycline and concomitant antithrombotic drugs, bleeding events were assessed by comparing the decline in hemoglobin and the amount of red blood cell transfusion in patients with antithrombotic drugs and those without. RESULTS: This study included a total of 68 cases, 20 of which experienced hypofibrinogenemia while receiving tigecycline treatment. Duration of treatment, cefoperazone/sulbactam combination therapy, and fibrinogen levels prior to initiation of tigecycline were risk factors associated with tigecycline-induced hypofibrinogenemia. There were 26 recorded bleeding incidents, 25 of which happened before the start of tigecycline. Antithrombotic and non-antithrombotic patients did not differ in their hemoglobin decline or need for red blood cell transfusions while taking tigecycline. CONCLUSION: A longer treatment duration, cefoperazone/sulbactam combination therapy, and a lower level of fibrinogen before tigecycline were associated with an increased risk of tigecycline-induced hypofibrinogenemia. A combination of antithrombotic drugs and tigecycline did not aggravate the bleeding events during tigecycline treatment.

Acute pancreatitis caused by tigecycline and furosemide combination treatment and hypofibrinogenemia caused by tigecycline: A case report.

OBJECTIVE: We describe a case of acute pancreatitis (AP) and hypofibrinogenemia associated with drug treatment with the aim to increase awareness of uncommon yet possibly life-threatening adverse reactions of tigecycline and furosemide. CASE SUMMARY: A 75-year-old Chinese male was hospitalized for acute non-ST-elevation myocardial infarction and acute heart failure. The patient underwent successful percutaneous coronary intervention and MitraClip. Furosemide was taken since admission. Because Acinetobacter baumannii was detected in the blood and sputum, the patient was treated with tigecycline from the 14th day of hospitalization. Abnormal pancreatitis parameters were observed, and pancreatic CT was undertaken 12 days after the treatment of tigecycline. AP was diagnosed and symptomatic treatment was carried out, but no significant improvement was observed. On the 33rd day of hospitalization, the patient presented with acute upper gastrointestinal bleeding and decreased levels of fibrinogen and platelets. After withdrawal of tigecycline, the coagulation and pancreatitis parameters improved significantly. However, the pancreatitis parameters increased again after stopping somatostatin. Therefore, somatostatin was given again for 1 day, and furosemide was discontinued. After that, the pancreatitis parameters returned to baseline levels after a slight recovery. CONCLUSION: Clinicians should pay attention to clinical signs, symptoms, and pancreatic enzymes during tigecycline or furosemide treatment, especially when used in combination. In addition, regular monitoring of fibrinogen and platelet count during tigecycline treatment is suggested.

Population pharmacokinetic modelling of fibrinogen in patients with congenital or acquired-chronic or acute-hypofibrinogenaemia.

AIMS: Fibrinogen is the key substrate for coagulation. Fibrinogen pharmacokinetics (PK) after single doses of fibrinogen concentrate (FC), using modelling approaches, has only been evaluated in congenital afibrinogenaemic patients. The aims of this study are to characterize the fibrinogen PK in patients with acquired-chronic (cirrhosis) or acute-hypofibrinogenaemia (critical haemorrhage), showing endogenous production. Influencing factors of differences on the fibrinogen PK between subpopulations will be identified. METHODS: A total of 428 time-concentration values from 132 patients were recorded. Eighty-two out of 428 values were from 41 cirrhotic patients administered with placebo and 90 out of 428 were from 45 cirrhotic patients that were given FC, 161 out of 428 values were from 14 afibrinogenaemic patients and 95 out of 428 values were from 32 severe acute trauma haemorrhagic patients. A turnover model that accounted for endogenous production and exogenous dose was fitted using NONMEM74. The production rate (Ksyn), distribution volume (V), plasma clearance (CL) and concentration yielding to 50% of maximal fibrinogen production (EC50) were estimated. RESULTS: Fibrinogen disposition was described by a one-compartment model with CL and V values of 0.0456 L·h-1 and 4.34 L·70 kg-1 , respectively. Body weight was statistically significant in V. Three different Ksyn values were identified that increased from 0.00439 g·h-1 (afibrinogenaemia), to 0.0768 g·h-1 (cirrhotics) and 0.1160 g·h-1 (acute severe trauma). EC50 was of 0.460 g·L-1 . CONCLUSIONS: This model will be key as a support tool for dose calculation to achieve specified target fibrinogen concentrations, in each of the studied populations.

Cost-effectiveness of Fibrinogen Concentrate vs Cryoprecipitate for Treating Acquired Hypofibrinogenemia in Bleeding Adult Cardiac Surgical Patients.

Importance: Excessive bleeding requiring fibrinogen replacement is a serious complication of cardiac surgery. However, the relative cost-effectiveness of the 2 available therapies-fibrinogen concentrate and cryoprecipitate-is unknown. Objective: To determine cost-effectiveness of fibrinogen concentrate vs cryoprecipitate for managing active bleeding in adult patients who underwent cardiac surgery. Design, Setting, and Participants: A within-trial economic evaluation of the Fibrinogen Replenishment in Surgery (FIBERS) randomized clinical trial (February 2017 to November 2018) that took place at 4 hospitals based in Ontario, Canada, hospitals examined all in-hospital resource utilization costs and allogeneic blood product (ABP) transfusion costs incurred within 28 days of surgery. Participants included a subset of 495 adult patients from the FIBERS trial who underwent cardiac surgery and developed active bleeding and acquired hypofibrinogenemia requiring fibrinogen replacement. Interventions: Fibrinogen concentrate (4 g per dose) or cryoprecipitate (10 units per dose) randomized (1:1) up to 24 hours postcardiopulmonary bypass. Main Outcomes and Measures: Effectiveness outcomes included number of ABPs administered within 24 hours and 7 days of cardiopulmonary bypass. ABP transfusion (7-day) and in-hospital resource utilization (28-day) costs were evaluated and a multivariable net benefit regression model built for the full sample and predefined subgroups. Results: Patient level costs for 495 patients were evaluated (mean [SD] age 59.2 [15.4] years and 69.3% male.) Consistent with FIBERS, ABP transfusions and adverse events were similar in both treatment groups. Median (IQR) total 7-day ABP cost was CAD $2280 (US dollars [USD] $1697) (CAD $930 [USD $692]-CAD $4970 [USD $3701]) in the fibrinogen concentrate group and CAD $2770 (USD $1690) (IQR, CAD $1140 [USD $849]-CAD $5000 [USD $3723]) in the cryoprecipitate group. Median (interquartile range) total 28-day cost was CAD $38 180 (USD $28 431) $(IQR, CAD $26 350 [USD $19 622]-CAD $65 080 [USD $48 463]) in the fibrinogen concentrate group and CAD $38 790 (USD $28 886) (IQR, CAD $26 180 [USD $19 495]-CAD $70 380 [USD $52 409]) in the cryoprecipitate group. After exclusion of patients who were critically ill before surgery (11%) due to substantial variability in costs, the incremental net benefit of fibrinogen concentrate vs cryoprecipitate was positive (probability of being cost-effective 86% and 97% at $0 and CAD $2000 (USD $1489) willingness-to-pay, respectively). Net benefit was highly uncertain for nonelective and patients with critical illness. Conclusions and Relevance: Fibrinogen concentrate is cost-effective when compared with cryoprecipitate in most bleeding adult patients who underwent cardiac surgery with acquired hypofibrinogenemia requiring fibrinogen replacement. The generalizability of these findings outside the Canadian health system needs to be verified.

Pharmacokinetics, efficacy and safety of a novel fibrinogen concentrate in pediatric patients with congenital afibrinogenemia.

INTRODUCTION: Congenital afibrinogenemia treatment with plasma-derived fibrinogen concentrates in pediatric patients is limited. This study investigated the pharmacokinetics, surrogate efficacy, and safety of a plasma-derived fibrinogen concentrate (FIB Grifols) in pediatric patients with congenital afibrinogenemia. METHODS: Patients aged <18 years old diagnosed with congenital afibrinogenemia were included in this prospective, multinational, phase 1-2, single-arm study. After a single dose of a plasma-derived fibrinogen concentrate (70 mg/kg body weight), pharmacokinetic parameters were determined from plasma fibrinogen activity (Clauss method) and antigen method (ELISA), and calculated by noncompartmental and population pharmacokinetic (popPK) models. Patients were followed up over 14 days. Efficacy variables were the mean change on thromboelastographic variables (maximum clot firmness [MCF], alpha angle [ α ]) and coagulation tests (prothrombin time, activated partial thromboplastin time, and thrombin time) 1 h postinfusion. Safety parameters were assessed. RESULTS: Eleven patients with a median (range) age 8.80 (3.7-12.7) years were treated with the plasma-derived fibrinogen concentrate. Using the popPK modeling, fibrinogen activity reached a mean (standard deviation) Cmax of 1.3 (0.225) g/l, half-life ( t1/2 ) of 60.6 (4.48) h and incremental in vivo recovery (IVR) of 1.86 (0.322) (mg/dl)/(mg/kg). Surrogate efficacy was demonstrated by significant increase in MCF (9.23 [3.94] mm; P  < 0.001; 95% confidence interval 6.58, 11.87). All coagulation times were significantly shortened after fibrinogen concentrate infusion. Adverse events were mild or moderate in severity, and unrelated to fibrinogen concentrate. CONCLUSIONS: In pediatric patients with congenital afibrinogenemia, plasma-derived fibrinogen concentrate revealed a favorable and specific pharmacokinetic profile, demonstrated efficacy in coagulation and was safe and well tolerated.

Effectiveness of Administration of Fibrinogen Concentrate as Prevention of Hypofibrinogenemia in Patients with Traumatic Brain Injury with a Higher Risk for Severe Hyperfibrinolysis: Single Center Before-and-After Study.

BACKGROUND: Coagulopathy is often observed in severe traumatic brain injury (sTBI), and hyperfibrinolysis (HF) is associated with a poor prognosis. Although the efficacy of fibrinogen concentrate (FC) in multiple trauma has been reported, its efficacy in sTBI is unclear. Therefore, we delineated severe HF risk factors despite fresh frozen plasma transfusion. Using these risk factors, we defined high-risk patients and determined whether FC administration to this group improved fibrinogen level. METHODS: In the first part of this study, successive adults with sTBI treated at our hospital between April 2016 and March 2019 were reviewed. Patients underwent transfusion as per our conventional protocol and were divided into two groups based on whether fibrinogen levels of ≥ 150 mg/dL were maintained 3-6 h after arrival to delineate the risk factors of severe HF. In the second part of the study, we conducted a before-and-after study in patients with sTBI who were at a higher risk for severe HF (presence of at least one of the risk factors identified in the first part of the study), comparing those treated with FC between April 2019 and March 2021 (FC group) with those treated with conventional transfusion before FC between April 2016 and March 2019. The primary outcome was maintenance of fibrinogen levels, and the secondary outcome was 30-day mortality. RESULTS: In the first part of the study, 78 patients were included. Twenty-three patients did not maintain fibrinogen levels ≥ 150 mg/dL. A D-dimer level on arrival > 50 µg/mL, a fibrinogen level on arrival < 200 mg/dL, depressed skull fracture, and multiple trauma were severe HF risk factors. In the second part, compared with 46 patients who were identified as being at high risk for severe HF but were not administered FC (non-FC group), fibrinogen levels ≥ 150 mg/dL 3-6 h after arrival were maintained in 14 of 15 patients in the FC group (odds ratio: 0.07; 95% confidence interval: 0.01-0.59). Although there were significant differences in fibrinogen levels, no significant differences were observed in terms of 30-day mortality between the groups. CONCLUSIONS: Coagulation abnormalities on arrival, severe skull fracture, and multiple trauma are severe HF risk factors. FC administration may contribute to rapid correction of developing hypofibrinogenemia.

Efficacy and safety of fibrinogen concentrate for perioperative prophylaxis of bleeding in adult, adolescent, and pediatric patients with congenital fibrinogen deficiency: FORMA-02 and FORMA-04 clinical trials.

BACKGROUND: Congenital fibrinogen deficiency (CFD) is a rare coagulation disorder placing patients at increased bleeding risk. Human fibrinogen concentrate (HFC) represents current standard of care for fibrinogen replacement in CFD, however, limited data are available on HFC for prophylactic administration before/during surgery. Here, we report results and dosing considerations for HFC treatment in perioperative bleeding management in adult, adolescent, and pediatric patients with CFD. STUDY DESIGN AND METHODS: FORMA-02/FORMA-04 were multinational, prospective, open-label, uncontrolled Phase 3 HFC efficacy/safety studies for surgical bleeding prophylaxis in adult/adolescent (≥12 years) and pediatric patients (<12 years) respectively. HFC dosing was calculated to achieve pre-established target fibrinogen plasma levels. Overall hemostatic efficacy was assessed as success/failure by an Independent Data Monitoring and Endpoint Adjudication Committee (IDMEAC) according to objective criteria. RESULTS: Twelve patients (≥12 years, N = 9; <12 years, N = 3) received HFC for surgical prophylaxis (15 surgeries; 13 minor, 2 major). Eleven minor surgeries in patients aged ≥12 years required a median of 1 infusion (range; 1-5), with a mean (±SD) dose of 93.50 mg/kg [±41.43] and two minor surgeries in patients <12 years required 1 infusion (91.55 mg/kg [±23.40]). The major surgery in an adult patient required eight infusions (225.3 mg/kg total dose). The major surgery in a pediatric patient required six infusions (450.4 mg/kg). All surgeries were rated successful by the IDMEAC. DISCUSSION: In adults/adolescents and pediatric patients with fibrinogen deficiency, HFC treatment for hemostatic management during/after minor and major surgery was successful, with efficacy comparable across the different age groups.

Serum concentration as a predictor of tigecycline-induced hypofibrinogenemia in critically ill patients: A retrospective cohort study.

OBJECTIVES: This study aimed to determine the thresholds of serum concentration as a predictor of tigecycline (TGC)-induced hypofibrinogenemia (HF) in critically ill patients. METHODS: A retrospective cohort study was conducted in intensive care unit patients treated with TGC. The clinical data and serum concentration were extracted from the patients' electronic medical records. Patients were divided into an HF group and a normal group according to fibrinogen value. The receiver operating characteristic curves and logistic regression were used to derive serum concentration thresholds and quantify the association between exposure thresholds and HF while adjusting for confounders. RESULTS: In total, 100 patients were included. The receiver operating characteristic curves analysis showed that TGC concentration parameters were strongly predictive of HF. Adjusting for duration of TGC, serum concentration at the 6 hours after the dosing (C1/2) ≥ 0.645 mg/l, area under the concentration-time curve over a 24-hour period (AUC 0-24) ≥ 20.76 mg·h/l, and serum concentration of 30 minutes before next dose (Cmin) ≥ 0.455 mg/l were associated with a three- to five-fold increased risk of TGC-induced HF in logistic regression. CONCLUSION: The findings from this study provide evidence that TGC exposure is highly predictive of HF, with an approximately three- to five-fold increased risk. Serum concentration at the 6 hours after the dosing (C1/2) ≥ 0.645 mg/l with best area under the receiver operating characteristic curve and negative predictive value appears to be the most appropriate toxicity threshold.

Analysis of fibrinogen concentrate pharmacokinetics and dosing for bleeds and surgery in adults, adolescents, and children with congenital afibrinogenaemia and hypofibrinogenaemia.

INTRODUCTION: Congenital afibrinogenaemia and hypofibrinogenaemia are rare coagulation disorders where clotting is impaired due to a lack of fibrinogen. Consequent bleeding episodes (BEs) are treated using human fibrinogen concentrate (HFC). AIM: This post-hoc analysis compared HFC pharmacokinetics (PK) and dosing between patient age groups and defined the in vivo recovery (IVR) for children with a- and hypofibrinogenaemia. METHODS: The analysis used data from the FORMA-01 (Phase 2), FORMA-02 and FORMA-04 (Phase 3) multinational, prospective, open-label studies in patients with a- and hypofibrinogenaemia. HFC PK in adults/adolescents (≥12 years; FORMA-01) and children (<12 years; FORMA-04) was examined. Haemostatic efficacy in BE treatment and perioperative prophylaxis was examined in FORMA-02 and FORMA-04 using an objective 4-point scale, with success defined as excellent/good. RESULTS: Median (range) age was 23 years for FORMA-01 (12-53; n = 22), 26.5 years for FORMA-02 (12-54; n = 25), and 6 years for FORMA-04 (1-10; n = 13). Mean PK parameters were lower for children (AUC, Cmax , IVR; p = .02), while clearance was higher. Median (range) total dose of HFC for all BEs was 59.41 mg/kg (32.12-273.80) in adults/adolescents and was 24% higher (ns) in children at 73.91 mg/kg (47.45-262.50). Treatment was successful in 98.9% of the 89 BEs in adults/adolescents and in 100% of the 10 BEs in children, with comparable results for perioperative prophylaxis. CONCLUSION: As expected, HFC PK differed between adults/adolescents and children. However, with the higher doses given to children, HFC showed similar efficacy across age groups. Dose adaptation based on age groups appears recommendable.

Practice patterns of ABO-matching for cryoprecipitate and patient outcomes after ABO-compatible versus incompatible cryoprecipitate.

BACKGROUND AND OBJECTIVES: This sub-study of the FIBRES trial sought to examine the patterns of ABO-compatible cryoprecipitate administration and to identify adverse consequences of ABO-incompatible cryoprecipitate. MATERIALS AND METHODS: This was a post hoc analysis of data collected from the FIBRES randomized clinical trial comparing fibrinogen concentrate with cryoprecipitate in the treatment of bleeding related to hypofibrinogenemia after cardiac surgery. The primary outcome was the percentage of administered cryoprecipitate that was ABO-compatible. Secondary outcomes were adverse events at 28 days. A follow-up survey was distributed to the FIBRES participating sites to examine the rationale behind the identified cryoprecipitate ABO-matching practice patterns. RESULTS: A total of 363 patients were included: 53 (15%) received ABO-incompatible cryoprecipitate and 310 (85%) received ABO-compatible cryoprecipitate. There was an increased incidence of post-operative anaemia in the ABO-incompatible group (15; 28.3%) in comparison to the ABO-compatible (44; 14.2%) group (p = 0.01) at 28 days, which was unrelated to haemolysis, without a significant difference in transfusion requirement. In the multivariable logistic regression models accounting for clustering by site, there was no observed statistically significant association between the administration of ABO-incompatible cryoprecipitate and any other adverse outcomes. Nine out of 11 sites did not have a policy requiring ABO-matched cryoprecipitate. CONCLUSION: This sub-study demonstrated that most cryoprecipitate administered in practice is ABO-compatible, despite the absence of guidelines or blood bank policies to support this practice. A signal towards increased risk of post-operative anaemia may be explained by higher rates of urgent surgery (vs. elective) in the ABO-incompatible group. Future studies should prospectively examine the impact of ABO-compatible versus incompatible cryoprecipitate to conclusively establish if there is a meaningful clinical impact associated with the administration of ABO-incompatible cryoprecipitate.

Efficacy and safety of fibrinogen administration in acute post-traumatic hypofibrinogenemia in isolated severe traumatic brain injury: A randomized clinical trial.

AIM: This study was conducted to evaluate clinical outcomes after fibrinogen administration in hypofibrinogenemia following severe traumatic brain injury. BACKGROUND: Post traumatic coagulopathy (PTC) is a common but devastating medical condition in patients with severe head injury. Hypofibrinogenemia is considered as an indicator for poor clinical outcomes in traumatic brain injury (TBI). METHODS: In this randomized clinical trial (RCT), primarily 137 patients with severe traumatic brain injury (Glasgow coma scale score: GCS < 9) were enrolled. Thereafter, their plasma fibrinogen level was measured. The patients with primary hypofibrinogenemia (<200 mg/dL) with no concurrent coagulopathy were randomly allocated into fibrinogen-receiving (n = 50) and control (n = 54) groups. P-value < 0.05 was considered as statistically significant. RESULTS: Seventy-one patients were analyzed in the final step of the study. The mean value for age in fibrinogen and control groups was 25.64 ± 10.71 and 28.91 ± 12.25 years old, respectively. Male - female patients in both groups were equally distributed. In the fibrinogen receiving group, GCS scores were significantly higher after 24, 48, and 72 h compared to the control group (p = 0.000). Hematoma expansion was better controlled in the fibrinogen receiving group (p = 0.000). Notably, the number needed to treat (NNT) for fibrinogen infusion and hematoma expansion control was 2.3. Glasgow outcome scale-extended (GOSE) was significantly better in the fibrinogen group (p = 0.25). Multiple regression tests showed intracerebral hematoma (ICH) and severe brain edema had the most detrimental effect on GOSE outcomes. The need for cranial surgery, hospital stay duration, mechanical ventilator dependency, in hospital and 90-day post discharge mortality rates were similar in both study groups. CONCLUSION: In severe TBI, hypofibrinogenemia correction (>200 mg/dL) could improve GOSE, GCS score progression within 3 days after primary head injury and hematoma expansion controllability.

Impact of cardiopulmonary bypass duration on efficacy of fibrinogen replacement with cryoprecipitate compared with fibrinogen concentrate: a post hoc analysis of the Fibrinogen Replenishment in Surgery (FIBRES) randomised controlled trial.

BACKGROUND: Coagulopathy in cardiac surgery is frequently associated with acquired hypofibrinogenaemia, which can be treated with either purified fibrinogen concentrate (FC) or cryoprecipitate. Because the latter is not purified and therefore contains additional coagulation factors, it is thought to be more effective for treatment of coagulopathy that occurs after prolonged cardiopulmonary bypass (CPB). We examined the impact of CPB duration on the efficacy of the two therapies in cardiac surgery. METHODS: This was a post hoc analysis of the Fibrinogen Replenishment in Surgery (FIBRES) RCT comparing FC (4 g) to cryoprecipitate (10 U) in adult patients undergoing cardiac surgery and experiencing bleeding with acquired hypofibrinogenaemia (n=735). The primary outcome was allogeneic blood products transfused within 24 h after CPB. Subjects were stratified by CPB duration (≤120, 121-180, and >180 min). The interaction of treatment assignment with CPB duration was tested. RESULTS: Subjects with longer CPB duration experienced more bleeding and transfusion. With CPB time ≤120 min (FC, n=134; cryoprecipitate, n=146), the ratio of least-squares means between the FC and cryoprecipitate groups for total allogeneic blood products at 24 h was 0.90 (one-sided 97.5% confidence interval [CI]: 0.00-1.12); P=0.004. For subjects with CPB time 121-180 min, it was 1.00 ([one-sided 97.5% CI: 0.00-1.22]; P=0.03], and for CPB time >180 min it was 0.91 ([one-sided 97.5% CI: 0.00-1.12]; P=0.005). Results were similar for all secondary outcomes, with no interaction between treatment and CPB duration for all outcomes. CONCLUSIONS: The haemostatic efficacy of FC was non-inferior to cryoprecipitate irrespective of CPB duration in cardiac surgery. CLINICAL TRIAL REGISTRATION: NCT03037424.

Medical Management of a Mural Thrombus Inducing Repeated Ischemic Strokes in a Patient with Congenital Afibrinogenemia.

OBJECTIVES: Congenital afibrinogenemia is an autosomal recessive inherited disorder that can cause thrombotic as well as hemorrhagic events. We describe a case of repeated mild ischemic strokes due to a mural thrombus in the carotid artery and our medical treatment. CASE DESCRIPTION: A 49-year-old woman with congenital afibrinogenemia developed two minor ischemic strokes in two months. Clinical images revealed scattered fresh infarcts in the right middle cerebral artery region and mild cervical carotid artery stenosis. The risk for surgical treatment was considered to be extraordinarily high. The patient was treated with 100 mg/day of aspirin and 3 g fibrinogen infusion every two weeks. After the one-year course of medication, the mural thrombus gradually decreased, and there were no bleeding or ischemic stroke events. CONCLUSION: This case report highlights the successful treatment of an ischemic stroke in a patient with a congenital afibrinogenemia with an antiplatelet agent and fibrinogen replacement. There are no guidelines for managing ischemic stroke in patients with congenital afibrinogenemia, and further studies are needed.

Successful intravenous thrombolysis for acute ischemic stroke caused by aortic dissection with severe hypofibrinogenemia: a case report and literature review.

BACKGROUND: Intravenous thrombolysis (IVT) for acute brain infarctions caused by aortic dissection (AD) may lead to fatal outcomes; thus, it should be ruled out, especially if hypofibrinogenemia occurs after IVT. Successful management of AD-related acute brain infarction with hypofibrinogenemia after IVT has not been reported previously. CASE REPORT: An 84-year-old woman developed sudden left limb weakness and aphasia for almost 4 h. Alteplase was administered intravenously immediately after cerebral hemorrhage was ruled out by emergent head computed tomography (CT). An anomaly suspected to be AD was detected during subsequent routine chest CT, which was confirmed by CT angiography to be a thoracoabdominal aortic dissecting aneurysm (DeBakey type I). Severe hypofibrinogenemia was also noted. After effective blood pressure control, intramuscular injection of vitamin K, and rehydration therapy, her brain cell metabolism improved, hemiplegia improved slightly, and hypofibrinogenemia recovered gradually. The patient's cerebral hemorrhage did not progress, there was no chest pain or no aggravation of hemiplegia, and the fibrinogen level gradually returned to normal. The condition was stable during hospitalization. At 1.5 months after discharge, the patient showed minimal change in condition. CONCLUSION: The symptoms of AD may be nonspecific and latent. IVT may be allowed to perform for some patients with AD related ischemical stroke, And IVT can improve the neural symptoms of AD-related ischemic stroke, but close monitoring is needed to avoid aneurysm rupture. Fibrinogen levels should also be monitored periodically after IVT for early detection of hypofibrinogenemia.

Uso de concentrados de fibrinógeno para el tratamiento de la hipofibrinogenemia adquirida / Use of Fibrinogen Concentrates for the Treatment of Acquired Hypofibrinogenemia

Resumen Introducción: Un adecuado manejo del sangrado debe incluir la correcta valoración y eventual reposición de fibrinógeno. Las fuentes tradicionales de este elemento hemostático incluyen el plasma fresco congelado y los crioprecipitados. Los concentrados liofilizados de fibrinógeno humano (CFH) son una alternativa terapéutica novedosa en el mercado chileno. Objetivo: Este estudio describe el curso clínico de los primeros pacientes en nuestra institución requirentes de CFH, dentro de un algoritmo de reposición hemostática por metas. Materiales y Método: Serie de pacientes con hipofibrinogenemia secundaria a sangrado perioperatorio severo, en los que se utilizó CFH como método de reposición de fibrinógeno. Se utilizó tromboelastometría para definir dosis. Se registraron variables demográficas, operatorias, complicaciones y seguimiento hasta los 3 meses. Resultados: Se utilizaron CFH en 18 pacientes. La mediana de edad fue 40,7 (56,5-63) años y dos tercios de los pacientes fueron de sexo masculino. Fallecieron 5 pacientes de la serie. Todos los pacientes requirieron manejo posoperatorio en una unidad de cuidados intensivos. Ocho pacientes fueron sometidos a cirugía cardiaca. El uso de hemocomponentes y concentrados liofilizados fue heterogéneo, pero en todos los casos su uso fue determinado por tromboelastometría. Ningún paciente fue reintervenido a causa de sangrado posoperatorio. Conclusión: El uso de concentrados de fibrinógeno humano dentro de un algoritmo de manejo de sangrado guiado por tromboelastometría, es un recurso hemostático factible en la realidad nacional. El impacto clínico de esta intervención requiere una subsiguiente evaluación basada en la evidencia.

Introduction: An adequate bleeding management should include a proper assessment of fibrinogen values and consequent replacement. Traditional sources for this hemostatic element include fresh frozen plasma and cryoprecipitates. Lyophilized human fibrinogen concentrates are a novel therapeutic alternative for the chilean market. Aim: This study aims to describe the clinical course of the first patients in our institution receiving fibrinogen concentrates, included in a goal directed hemostatic management algorithm. Materials and Method: Case series of patients with hypofibrinogenemia secondary to severe perioperative bleeding, in which fibrinogen concentrate was used for fibrinogen replacement. Thromboelastometry was used to define dose regimens. Demographic and surgical variables, complications and follow-up up to 3 months were registered. Results: Fibrinogen concentrate was used in 18 patients. Median age was 40.7 (56.5-63) years, and two thirds of the patients were male. Five patients died. All of the cases required postoperative intensive care. Eight patients underwent cardiac surgery. There was a heterogenic use of blood derived products and lyophilized concentrates, but in all cases its use was guided by thromboelastometry. No patients needed a secondary exploration due to bleeding. Conclusion: The use of human fibrinogen concentrate included in a bleeding management algorithm is a feasible hemostatic resource in the chilean current situation. The clinical impact of this intervention requires further evidence-based evaluation.