Plasmin-driven fibrinolysis in a quasi-two-dimensional nanoscale fibrin matrix.

Fibrin plays a fundamentally important role during hemostasis. To withstand the shear forces of blood flow and prevent embolisation, fibrin monomers form a three-dimensional polymer network that serves as an elastic scaffold for the blood clot. The complex spatial hierarchy of the fibrin meshwork, however, severely complicates the exploration of structural features, mechanical properties and molecular changes associated with the individual fibers of the clot. Here we developed a quasi-two-dimensional nanoscale fibrin matrix that enables the investigation of fibrin properties by topographical analysis using atomic force microscopy. The average thickness of the matrix was ∼50 nm, and structural features of component fibers were accessible. The matrix could be lysed with plasmin following rehydration. By following the topology of the matrix during lysis, we were able to uncover the molecular mechanisms of the process. Fibers became flexible but retained axial continuity for an extended time period, indicating that lateral interactions between protofibrils are disrupted first, but the axial interactions remain stable. Nearby fibers often fused into bundles, pointing at the presence of a cohesional force between them. Axial fiber fragmentation rapidly took place in the final step. Conceivably, the persisting axial integrity and cohesion of the fibrils assist to maintain global clot structure, to prevent microembolism, and to generate a high local plasmin concentration for the rapid, final axial fibril fragmentation. The nanoscale fibrin matrix developed and tested here provides a unique insight into the molecular mechanisms behind the structural and mechanical features of fibrin and its proteolytic degradation.

Fibrin clot structure in patients with congenital dysfibrinogenaemia.

The clinical phenotype of patients with congenital dysfibrinogenaemia is highly heterogeneous, from absence of symptoms to mild bleeding, or thrombosis. A few mutations are associated with a specific phenotype, but generally the clinical course is not predictable. We investigated whether fibrin clot properties are correlated with the patient's phenotype and/or genotype. Ex vivo plasma fibrin clot characteristics, including turbidity, fibrinolysis, clot permeability and fibrin fibre density assessed by laser scanner confocal microscopy were investigated in 24 genotyped patients with congenital dysfibrinogenaemia compared to normal pool plasma. Compared to normal pool plasma, the patients were characterised by slower fibrin polymerisation (lag time, 345.10 ± 22.98 vs. 166.00s), thinner fibrin fibres (maximum absorbance, 0.15 ± 0.01 vs. 0.31), prolonged clot lysis time (23.72 ± 0.97 vs. 20.32 min) and larger clot pore size (21.5×10(-9) ± 4.48×10(-9) vs. 7.96×10(-9)cm(2)). Laser scanning confocal microscopy images confirmed disorganised fibrin networks in all patients. Patients with tendency to bleed showed an increased permeability compared to asymptomatic patients (p=0.01) and to patients with a thrombotic history (p=0.02) while patients with thrombotic history had a tendency to have a prolonged clot lysis time. Fibrin clot properties were similar among hotspot mutations. Further studies including a larger number of patients are needed to evaluate whether analysis of permeability and clot lysis time may help to distinguish the clinical phenotype in these patients and to assess differences according to the genotype.

Differences in fibrin fiber diameters in healthy individuals and thromboembolic ischemic stroke patients.

Cerebrovascular disease is one of the leading causes of death and the cause of long-term adult disability. An important characteristic of thromboembolic ischemic stroke is a prothrombotic or hypercoagulable state and altered fibrin clot structure, whereas a resistance to fibrinolysis is also present. An expansive fibrin network is created when adding thrombin, and in stroke, the network appears thickened, netted and matted, compared with that of healthy individuals. Although this is clearly visible in micrographs of patients, there is a need to quantify the changes. The current study, therefore, investigates fibrin fiber diameters in stroke patients and compares it to healthy individuals. The fiber diameters were measured in nanometres, with University of Texas Health Science Center at San Antonio (UTHSCSA) Image Tool. A total of 100 measurements were done for each of the 12 patients in the healthy control group, and the same number of measurements was done for 12 stroke patients. These measurements were statistically analysed with NCSS 2007, using a significance level of 0.05. Normality was assessed with the Shapiro-Wilk W test and the thickest and thinnest fiber of each individual in the two groups was quantified and differences between groups were assessed with the Student's t-test. Results showed that there is a statistical difference in fibrin fiber thickness during thromboembolic ischemic stroke. We conclude that the changed coagulation and hemostasis, typically associated with stroke, causes a statistically relevant change in fibrin thickness, and that this netted and matted network is more resistant to lyses.

Polymerization of fibrinogen-derived fragment X and subsequent rearrangement of fibers.

Polymerization of purified fragment X preparations, obtained from a late stage 2 plasmin digest of fibrinogen, was studied by turbidimetry and electron microscopy. The thrombin-induced polymerization of fragment X caused a rapid increase in turbidity followed by a slow decrease. The initial turbidity increase of fragment X polymers was considerably greater than that of normal fibrin. Electron microscopy carried out at different time points in the reaction revealed that initially there was a great deal of lateral aggregation of fragment X fibers. At later times, electron microscopy showed that there was more dispersal or disruption of the fibers, corresponding to the decrease in turbidity. The slow decrease in turbidity was apparently caused by the rearrangement and/or splitting apart of fragment X fibers, starting from a state similar to a very coarse clot, with much aggregation of fibers, to a delicate meshwork, similar to a fine clot. These changes in clot and fiber structure may result from cleavages partly in the carboxy-terminal region of the gamma chains and the amino-terminal region of the B beta chain of fragment X or the influence of other non-clottable fragments present in these preparations.