Your search keyword '"Zolkova, Jana"' showing total 9 results

1. Congenital hypofibrinogenemia associated with a novel heterozygous nonsense mutation in the globular C-terminal domain of the γ-chain (p.Glu275Stop).

Author

Simurda T, Caccia S, Asselta R, Zolkova J, Stasko J, Skornova I, Snahnicanova Z, Loderer D, Lasabova Z, and Kubisz P

Subjects

Anticoagulants administration & dosage, Codon, Nonsense, Genetic Predisposition to Disease, Genetic Testing methods, Humans, Male, Middle Aged, Recurrence, Warfarin administration & dosage, Afibrinogenemia diagnosis, Afibrinogenemia genetics, Afibrinogenemia physiopathology, Blood Coagulation Tests methods, Fibrinogen genetics, Thrombelastography methods, Venous Thrombosis diagnosis, Venous Thrombosis drug therapy, Venous Thrombosis etiology

Published

2020

2. Genetic Variants in the FGB and FGG Genes Mapping in the Beta and Gamma Nodules of the Fibrinogen Molecule in Congenital Quantitative Fibrinogen Disorders Associated with a Thrombotic Phenotype.

Author

Simurda T, Brunclikova M, Asselta R, Caccia S, Zolkova J, Kolkova Z, Loderer D, Skornova I, Hudecek J, Lasabova Z, Stasko J, and Kubisz P

Subjects

Afibrinogenemia physiopathology, Blood Coagulation Tests, Factor XIII genetics, Fibrin genetics, Fibrinolysis genetics, Hemorrhage, Hemostasis, Hemostatics, Humans, Phenotype, Thrombosis genetics, Thrombosis physiopathology, Afibrinogenemia genetics, Fibrinogen genetics, Fibrinogen metabolism

Abstract

Fibrinogen is a hexameric plasmatic glycoprotein composed of pairs of three chains (Aα, Bβ, and γ), which play an essential role in hemostasis. Conversion of fibrinogen to insoluble polymer fibrin gives structural stability, strength, and adhesive surfaces for growing blood clots. Equally important, the exposure of its non-substrate thrombin-binding sites after fibrin clot formation promotes antithrombotic properties. Fibrinogen and fibrin have a major role in multiple biological processes in addition to hemostasis and thrombosis, i.e., fibrinolysis (during which the fibrin clot is broken down), matrix physiology (by interacting with factor XIII, plasminogen, vitronectin, and fibronectin), wound healing, inflammation, infection, cell interaction, angiogenesis, tumour growth, and metastasis. Congenital fibrinogen deficiencies are rare bleeding disorders, characterized by extensive genetic heterogeneity in all the three genes: FGA , FGB , and FGG (enconding the Aα, Bβ, and γ chain, respectively). Depending on the type and site of mutations, congenital defects of fibrinogen can result in variable clinical manifestations, which range from asymptomatic conditions to the life-threatening bleeds or even thromboembolic events. In this manuscript, we will briefly review the main pathogenic mechanisms and risk factors leading to thrombosis, and we will specifically focus on molecular mechanisms associated with mutations in the C-terminal end of the beta and gamma chains, which are often responsible for cases of congenital afibrinogenemia and hypofibrinogenemia associated with thrombotic manifestations.

Published

2020

3. Comparison of clinical phenotype with genetic and laboratory results in 31 patients with congenital dysfibrinogenemia in northern Slovakia.

Author

Simurda T, Zolkova J, Kolkova Z, Loderer D, Dobrotova M, Skornova I, Brunclíkova M, Grendar M, Lasabova Z, Stasko J, and Kubisz P

Subjects

Adolescent, Adult, Afibrinogenemia epidemiology, Asymptomatic Diseases, Child, Child, Preschool, Cross-Sectional Studies, Female, Hemorrhage epidemiology, Hemorrhage etiology, Humans, Male, Middle Aged, Rare Diseases, Slovakia epidemiology, Young Adult, Afibrinogenemia genetics, Fibrinogen genetics, Genotype, Hemorrhage genetics, Phenotype, Point Mutation

Abstract

Congenital dysfibrinogenemia (CD) is a rare disorder of hemostasis. The majority of cases are caused by heterozygous missense mutations in one of the three fibrinogen genes. Patients with CD may experience bleeding and thrombosis, but many are asymptomatic. To better describe the clinical, laboratory, and genotypic picture of CD, we evaluated 31 patients from seven unrelated families using standard coagulation tests and genetic analysis. The clinical phenotype consisted of bleeding in 13/31 (42%) patients; other patients (18/31; 58%) were asymptomatic. Among patients with bleeding, symptoms were mostly in single anatomical sites, with variable intensity of bleeding. Compared to results from a previous large systematic survey, our results showed a similar mean bleeding score, but a higher incidence of bleeding episodes without thrombotic complications. In the present study, we identified three known pathogenic point mutations in the FGA (c.95G > A, c.104G > A) and FGB (c.586C > T) genes. The variants of CD identified in this cross-sectional study were either asymptomatic or had bleeding manifestations and showed similar laboratory features, irrespective of genotype. Results from genetic and clinical studies will continue to yield valuable information on the structure and function of the fibrinogen molecule.

Published

2020

4. Identification of Two Novel Fibrinogen Bβ Chain Mutations in Two Slovak Families with Quantitative Fibrinogen Disorders.

Author

Simurda T, Zolkova J, Snahnicanova Z, Loderer D, Skornova I, Sokol J, Hudecek J, Stasko J, Lasabova Z, and Kubisz P

Subjects

Adult, Afibrinogenemia metabolism, Afibrinogenemia physiopathology, Base Sequence, Blood Coagulation Tests, Family, Fibrinogen chemistry, Fibrinogen metabolism, Fibrinogens, Abnormal genetics, Fibrinogens, Abnormal metabolism, Gene Expression, Hemorrhage metabolism, Hemorrhage physiopathology, Homozygote, Humans, Male, Middle Aged, Models, Molecular, Pedigree, Protein Structure, Secondary, Severity of Illness Index, Venous Thrombosis metabolism, Venous Thrombosis physiopathology, Afibrinogenemia genetics, Fibrinogen genetics, Hemorrhage genetics, Mutation, Venous Thrombosis genetics

Abstract

Congenital fibrinogen disorders are caused by mutations in one of the three fibrinogen genes that affect the synthesis, assembly, intracellular processing, stability or secretion of fibrinogen. Functional studies of mutant Bβ-chains revealed the importance of individual residues as well as three-dimensional structures for fibrinogen assembly and secretion. This study describes two novel homozygous fibrinogen Bβ chain mutations in two Slovak families with afibrinogenemia and hypofibrinogenemia. Peripheral blood samples were collected from all subjects with the aim of identifying the causative mutation. Coagulation-related tests and rotational thromboelastometry were performed. All exons and exon-intron boundaries of the fibrinogen genes ( FGA , FGB and FGG ) were amplified by PCR followed by direct sequencing. Sequence analysis of the three fibrinogen genes allowed us to identify two novel homozygous mutations in the FGB gene. A novel Bβ chain truncation (BβGln180Stop) was detected in a 28-year-old afibrinogenemic man with bleeding episodes including repeated haemorrhaging into muscles, joints, and soft tissues, and mucocutaneous bleeding and a novel Bβ missense mutation (BβTyr368His) was found in a 62-year-old hypofibrinogenemic man with recurrent deep and superficial venous thromboses of the lower extremities. The novel missense mutation was confirmed by molecular modelling. Both studying the molecular anomalies and the modelling of fibrinogenic mutants help us to understand the extremely complex machinery of fibrinogen biosynthesis and finally better assess its correlation with the patient's clinical course., Competing Interests: The authors declare no conflict of interest.

Published

2017

5. Basic Principles of Rotational Thromboelastometry (ROTEM ®) and the Role of ROTEM—Guided Fibrinogen Replacement Therapy in the Management of Coagulopathies.

Author

Drotarova, Miroslava, Zolkova, Jana, Belakova, Kristina Maria, Brunclikova, Monika, Skornova, Ingrid, Stasko, Jan, and Simurda, Tomas

Subjects

*FIBRINOGEN, *THROMBELASTOGRAPHY, *BLOOD coagulation disorders, *BLOOD transfusion, *MEDICAL care costs

Abstract

Rotational thromboelastometry (ROTEM) is a viscoelastic method, which provides a graphical and numerical representation of induced hemostasis in whole blood samples. Its ability to quickly assess the state of hemostasis is used in the management of bleeding from a variety of causes. The separate activation of particular parts of hemocoagulation in INTEM, EXTEM, and FIBTEM tests allows for a more comprehensive and faster evaluation of the missing component of hemostasis followed by targeted therapy. One of the most common cause of coagulopathy is trauma-induced coagulopathy. Fibrinogen replacement therapy by ROTEM allows for the use of a standard dosage of fibrinogen, which has been shown to be successful in preventing dilutional coagulopathy following colloid and crystalloid replacement and excessive amount of allogeneic blood transfusions. The best reflection of fibrinogen activity is observed in the FIBTEM assay, where fibrinogen replacement therapy is recommended at an MCF (maximum clot firmness) of FIBTEM < 10 mm and FIBTEM A10 < 7 mm. ROTEM also plays an important role in the diagnostic and management of inherited fibrinogen disorders. These can be manifested by bleeding complications, where changes in the MCF parameter are the most useful tool for assessing the effectiveness of fibrinogen replacement therapy. ROTEM-guided bleeding management algorithms effectively reduce the number of transfusions, healthcare costs, and complications, leading to the improvement of patient safety and overall health. [ABSTRACT FROM AUTHOR]

Published

2023

6. Use of Fibrinogen Determination Methods in Differential Diagnosis of Hypofibrinogenemia and Dysfibrinogenemia.

Author

Skornova, Ingrid, Simurda, Tomas, Stasko, Jan, Horvath, Denis, Zolkova, Jana, Holly, Pavol, Brunclikova, Monika, Samos, Matej, Bolek, Tomas, Schnierer, Martin, Slavik, Ludek, and Kubisz, Peter

Subjects

FIBRINOGEN, DISSEMINATED intravascular coagulation, DIFFERENTIAL diagnosis, DIAGNOSIS methods, THROMBOLYTIC therapy

Abstract

Background: Fibrinogen plays an important role in hemostasis. The normal concentration of fibrinogen in blood plasma is between 1.8 - 4.2 g/L. Decreased fibrinogen levels are observed in congenital afibrinogenemia, hypofi-brinogenemia, dysfibrinogenemia, disseminated intravascular coagulation, fibrinolytic therapy, some more severe hepatic parenchymal disorders, and increased blood loss. Elevated fibrinogen levels occur in inflammatory diseases and neoplastic diseases, in pregnancy, and postoperative conditions. Functional fibrinogen measurement is also one of the basic coagulation screening tests. The fibrinogen antigen assay is used to distinguish between qualitative and quantitative fibrinogen disorders. Methods: The aim of the study was the use of fibrinogen determination methods in differential diagnosis of hypofibrinogenemia and dysfibrinogenemia, statistical evaluation and determine the relationship of fibrinogen Clauss assay, prothrombin time (PT) derived fibrinogen assay, and fibrinogen antigen in the group of 60 patients with congenital fibrinogen disorders (n = 40 dysfibrinogenemia; n = 20 hypofibrinogenemia). Results: The results measured by the PT-derived fibrinogen assay were approximately four times higher compared to the fibrinogen Clauss assay in the group of patients with dysfibrinogenemia. In patients with hypofibrino-genemia, there is a correlation (r = 0.9016) between the fibrinogen Clauss assay and PT-derived fibrinogen assay with a statistical significance of p < 0.0001. Using a linear or quadratic interpolation function, we were able to determine the fibrinogen Clauss assay and the fibrinogen antigen assay before analysis. Conclusions: The higher level of the PT-derived fibrinogen assay compared to the fibrinogen Clauss assay in the group of patients with dysfibrinogenemia may pose a greater risk to asymptomatic patients who require diagnosis and treatment in case of bleeding. The fibrinogen value using the PT-derived fibrinogen assay could erroneously give a normal level. The use of the interpolation function is important to estimate the value of fibrinogen activity and antigen before the analysis itself by the Clauss assay or analysis by the fibrinogen antigen assay. [ABSTRACT FROM AUTHOR]

Published

2021

7. Identification of Two Novel Fibrinogen Bβ Chain Mutations in Two Slovak Families with Quantitative Fibrinogen Disorders.

Author

Simurda, Tomas, Zolkova, Jana, Snahnicanova, Zuzana, Loderer, Dusan, Skornova, Ingrid, Sokol, Juraj, Hudecek, Jan, Stasko, Jan, Lasabova, Zora, and Kubisz, Peter

Subjects

FIBRINOGEN polymorphisms, FIBRINOGEN, CONGENITAL disorders, BLOOD coagulation, HEMORRHAGE

Abstract

Congenital fibrinogen disorders are caused by mutations in one of the three fibrinogen genes that affect the synthesis, assembly, intracellular processing, stability or secretion of fibrinogen. Functional studies of mutant Bβ-chains revealed the importance of individual residues as well as three-dimensional structures for fibrinogen assembly and secretion. This study describes two novel homozygous fibrinogen Bβ chain mutations in two Slovak families with afibrinogenemia and hypofibrinogenemia. Peripheral blood samples were collected from all subjects with the aim of identifying the causative mutation. Coagulation-related tests and rotational thromboelastometry were performed. All exons and exon-intron boundaries of the fibrinogen genes (FGA, FGB and FGG) were amplified by PCR followed by direct sequencing. Sequence analysis of the three fibrinogen genes allowed us to identify two novel homozygous mutations in the FGB gene. A novel Bβ chain truncation (BβGln180Stop) was detected in a 28-year-old afibrinogenemic man with bleeding episodes including repeated haemorrhaging into muscles, joints, and soft tissues, and mucocutaneous bleeding and a novel Bβ missense mutation (BβTyr368His) was found in a 62-year-old hypofibrinogenemic man with recurrent deep and superficial venous thromboses of the lower extremities. The novel missense mutation was confirmed by molecular modelling. Both studying the molecular anomalies and the modelling of fibrinogenic mutants help us to understand the extremely complex machinery of fibrinogen biosynthesis and finally better assess its correlation with the patient's clinical course. [ABSTRACT FROM AUTHOR]

Published

2018

8. Heterogeneity of Genotype–Phenotype in Congenital Hypofibrinogenemia—A Review of Case Reports Associated with Bleeding and Thrombosis.

Author

Brunclikova, Monika, Simurda, Tomas, Zolkova, Jana, Sterankova, Miroslava, Skornova, Ingrid, Dobrotova, Miroslava, Kolkova, Zuzana, Loderer, Dusan, Grendar, Marian, Hudecek, Jan, Stasko, Jan, and Kubisz, Peter

Subjects

CONGENITAL disorders, THROMBOSIS, HEMORRHAGE, FIBRINOGEN, HETEROGENEITY, SYMPTOMS

Abstract

Congenital fibrinogen disorders are diseases associated with a bleeding tendency; however, there are also reports of thrombotic events. Fibrinogen plays a role in the pathogenesis of thrombosis due to altered plasma concentrations or modifications to fibrinogen's structural properties, which affect clot permeability, resistance to lysis, and its stiffness. Several distinct types of genetic change and pathogenetic mechanism have been described in patients with bleeding and a thrombotic phenotype, including mutations affecting synthesis or processing in three fibrinogen genes. In this paper, we focused on familial hypofibrinogenemia, a rare inherited quantitative fibrinogen disorder characterized by decreased fibrinogen levels with a high phenotypic heterogeneity. To begin, we briefly review the basic information regarding fibrinogen's structure, its function, and the clinical consequences of low fibrinogen levels. Thereafter, we introduce 15 case reports with various gene mutations derived from the fibrinogen mutation database GFHT (French Study Group on Hemostasis and Thrombosis), which are associated with congenital hypofibrinogenemia with both bleeding and thrombosis. Predicting clinical presentations based on genotype data is difficult. Genotype–phenotype correlations would be of help to better understand the pathologic properties of this rare disease and to provide a valuable tool for the identification of patients who are not only at risk of bleeding, but also at risk of a thrombotic event. [ABSTRACT FROM AUTHOR]

Published

2022

9. A Novel Nonsense Mutation in FGB (c.1421G>A; p.Trp474Ter) in the Beta Chain of Fibrinogen Causing Hypofibrinogenemia with Bleeding Phenotype.

Author

Simurda, Tomas, Vilar, Rui, Zolkova, Jana, Ceznerova, Eliska, Kolkova, Zuzana, Loderer, Dusan, Neerman-Arbez, Marguerite, Casini, Alessandro, Brunclikova, Monika, Skornova, Ingrid, Dobrotova, Miroslava, Grendar, Marian, Stasko, Jan, and Kubisz, Peter

Subjects

NONSENSE mutation, PHENOTYPES, FIBRINOGEN, GENETIC mutation, PROTEIN models, VON Willebrand disease

Abstract

Congenital hypofibrinogenemia is a rare bleeding disorder characterized by a proportional decrease of functional and antigenic fibrinogen levels. Hypofibrinogenemia can be considered the phenotypic expression of heterozygous loss of function mutations occurring within one of the three fibrinogen genes (FGA, FGB, and FGG). Clinical manifestations are highly variable; most patients are usually asymptomatic, but may appear with mild to severe bleeding or thrombotic complications. We have sequenced all exons of the FGA, FGB, and FGG genes using the DNA isolated from the peripheral blood in two unrelated probands with mild hypofibrinogenemia. Coagulation screening, global hemostasis, and functional analysis tests were performed. Molecular modeling was used to predict the defect of synthesis and structural changes of the identified mutation. DNA sequencing revealed a novel heterozygous variant c.1421G>A in exon 8 of the FGB gene encoding a Bβ chain (p.Trp474Ter) in both patients. Clinical data from patients showed bleeding episodes. Protein modelling confirmed changes in the secondary structure of the molecule, with the loss of three β sheet arrangements. As expected by the low fibrinogen levels, turbidity analyses showed a reduced fibrin polymerisation and imaging difference in thickness fibrin fibers. We have to emphasize that our patients have a quantitative fibrinogen disorder; therefore, the reduced function is due to the reduced concentration of fibrinogen, since the Bβ chains carrying the mutation predicted to be retained inside the cell. The study of fibrinogen molecules using protein modelling may help us to understand causality and effect of novel genetic mutations. [ABSTRACT FROM AUTHOR]

Published

2020