Modelling fibrinolysis: 1D continuum models

Bannish, Brittany E.; Keener, James P.; Woodbury, Michael; Weisel, John W.; Fogelson, Aaron L.

doi:10.1093/imammb/dqs030

Cited by 14 publications

(16 citation statements)

References 18 publications

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“…Together, our experimental and modeling data indicate that fiber diameter determines the prestrain induced by fibrin polymerization, and the pre-strain, in part, governs a fiber’s susceptibility to plasmin. Combining our models involving fiber strain during lysis, with other recently published models of lysis involving stochastic reactions and enzyme diffusion may be required for a complete picture of fibrinolysis [ 37 , 38 ].…”

Section: Resultsmentioning

confidence: 99%

Physical Determinants of Fibrinolysis in Single Fibrin Fibers

et al. 2015

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Fibrin fibers form the structural backbone of blood clots; fibrinolysis is the process in which plasmin digests fibrin fibers, effectively regulating the size and duration of a clot. To understand blood clot dissolution, the influence of clot structure and fiber properties must be separated from the effects of enzyme kinetics and perfusion rates into clots. Using an inverted optical microscope and fluorescently-labeled fibers suspended between micropatterned ridges, we have directly measured the lysis of individual fibrin fibers. We found that during lysis 64 ± 6% of fibers were transected at one point, but 29 ± 3% of fibers increase in length rather than dissolving or being transected. Thrombin and plasmin dose-response experiments showed that the elongation behavior was independent of plasmin concentration, but was instead dependent on the concentration of thrombin used during fiber polymerization, which correlated inversely with fiber diameter. Thinner fibers were more likely to lyse, while fibers greater than 200 ± 30 nm in diameter were more likely to elongate. Because lysis rates were greatly reduced in elongated fibers, we hypothesize that plasmin activity depends on fiber strain. Using polymer physics- and continuum mechanics-based mathematical models, we show that fibers polymerize in a strained state and that thicker fibers lose their prestrain more rapidly than thinner fibers during lysis, which may explain why thick fibers elongate and thin fibers lyse. These results highlight how subtle differences in the diameter and prestrain of fibers could lead to dramatically different lytic susceptibilities.

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Section: Resultsmentioning

confidence: 99%

Physical Determinants of Fibrinolysis in Single Fibrin Fibers

et al. 2015

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“…These results are in line with the observation that the number of fibres per volume determines resistance to the enzymatic lysis rather than an individual fibre diameter 43 . The delay in fibrinolysis rates in densely packed clots with thinner fibres is likely due to the greater number of fibres in the clot that need to be cleaved and other differences in spatio-temporal protein distributions 44 45 . There are a number of other factors that influence lysis speeds in clots of varying structure 46 .…”

Section: Discussionmentioning

confidence: 99%

Circulating Microparticles Alter Formation, Structure and Properties of Fibrin Clots

Zubairova

Набиуллина

Nagaswami

et al. 2015

Sci Rep

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Despite the importance of circulating microparticles in haemostasis and thrombosis, there is limited evidence for potential causative effects of naturally produced cell-derived microparticles on fibrin clot formation and its properties. We studied the significance of blood microparticles for fibrin formation, structure, and susceptibility to fibrinolysis by removing them from platelet-free plasma using filtration. Clots made in platelet-free and microparticle-depleted plasma samples from the same healthy donors were analyzed in parallel. Microparticles accelerate fibrin polymerisation and support formation of more compact clots that resist internal and external fibrinolysis. These variations correlate with faster thrombin generation, suggesting thrombin-mediated kinetic effects of microparticles on fibrin formation, structure, and properties. In addition, clots formed in the presence of microparticles, unlike clots from the microparticle-depleted plasma, contain 0.1–0.5-μm size granular and CD61-positive material on fibres, suggesting that platelet-derived microparticles attach to fibrin. Therefore, the blood of healthy individuals contains functional microparticles at the levels that have a procoagulant potential. They affect the structure and stability of fibrin clots indirectly through acceleration of thrombin generation and through direct physical incorporation into the fibrin network. Both mechanisms underlie a potential role of microparticles in haemostasis and thrombosis as modulators of fibrin formation, structure, and resistance to fibrinolysis.

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“…An issue with some fibrinolysis models was the approximation that fibrin was distributed homogenously rather than in fibers, which does not permit any investigation of the effects of fibrin architecture. Bannish et al [58] approached this problem by developing a one-dimensional reaction-diffusion model that included a concentration of fibrin that was fixed but heterogeneously distributed into fiber patterns. As the lysis front travelled through the clot, the model was able to replicate some features seen in in vitro clot lysis experiments, including concentration of tPA and plasminogen at the lysis front (reported to be up to 30-fold increased for plasminogen in aggregates in the 3 lm lysis front [11]).…”

Section: Models Of Fibrinolysismentioning

confidence: 99%

Basic mechanisms and regulation of fibrinolysis

Longstaff

Kolev

2015

Journal of Thrombosis and Haemostasis

186

155

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To cite this article: Longstaff C, Kolev K. Basic mechanisms and regulation of fibrinolysis. J Thromb Haemost 2015; 13 (Suppl. 1): S98-S105.Summary. Fibrinolysis appears in many diverse physiological situations, and the components of the system are well established, along with mechanistic details for the individual reactions and some high-resolution structures. Key questions in understanding the regulation of fibrinolysis surround mechanisms of initiation and propagation, the localization of fibrinolysis reactions to the fibrin clot, and the influence of fibrin structure and clot composition on thrombolysis. This review covers these key areas with a focus on recent developments on fibrin structure and binding, the effects of a variety of cell types, the consequences of histones and DNA released by neutrophils, and the influence of flow. A complete understanding of the regulation of fibrinolysis will come from the building of detailed mathematical models. Suitable models are at an early stage of development, but may improve as model clots increase in complexity to incorporate the components and interactions listed above.

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Modelling fibrinolysis: 1D continuum models

Cited by 14 publications

References 18 publications

Physical Determinants of Fibrinolysis in Single Fibrin Fibers

Physical Determinants of Fibrinolysis in Single Fibrin Fibers

Circulating Microparticles Alter Formation, Structure and Properties of Fibrin Clots

Basic mechanisms and regulation of fibrinolysis

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