Platelet Control of Fibrin Distribution and Microelasticity in Thrombus Formation Under Flow

Swieringa, Frauke; Baaten, Constance C. F. M. J.; Verdoold, Remco; Mastenbroek, Tom G.; Rijnveld, Niek; Laan, Koen O. van der; Breel, Ernst J.; Collins, Peter William; Lancé, Marcus D.; Henskens, Yvonne; Cosemans, Judith M.E.M.; Heemskerk, Johan W. M.; Meijden, Paola E. J. van der

doi:10.1161/atvbaha.115.306537

Cited by 55 publications

(87 citation statements)

References 42 publications

(32 reference statements)

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“…Blood flow is one of the most important physical factors that affects profoundly formation of the fibrin network, its structure and properties in vivo (Swieringa et al 2016). Clot formation in static conditions stops when all soluble fibrinogen is converted to insoluble fibrin.…”

Section: 4 Variations and Modulation Of Fibrin(ogen) Structure Andmentioning

confidence: 99%

Fibrin Formation, Structure and Properties

Weisel

Litvinov

2017

Subcellular Biochemistry

520

498

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Fibrinogen and fibrin are essential for hemostasis and are major factors in thrombosis, wound healing, and several other biological functions and pathological conditions. The X-ray crystallographic structure of major parts of fibrin(ogen), together with computational reconstructions of missing portions and numerous biochemical and biophysical studies, have provided a wealth of data to interpret molecular mechanisms of fibrin formation, its organization, and properties. On cleavage of fibrinopeptides by thrombin, fibrinogen is converted to fibrin monomers, which interact via knobs exposed by fibrinopeptide removal in the central region, with holes always exposed at the ends of the molecules. The resulting half-staggered, double-stranded oligomers lengthen into protofibrils, which aggregate laterally to make fibers, which then branch to yield a three-dimensional network. Much is now known about the structural origins of clot mechanical properties, including changes in fiber orientation, stretching and buckling, and forced unfolding of molecular domains. Studies of congenital fibrinogen variants and post-translational modifications have increased our understanding of the structure and functions of fibrin(ogen). The fibrinolytic system, with the zymogen plasminogen binding to fibrin together with tissue-type plasminogen activator to promote activation to the active proteolytic enzyme, plasmin, results in digestion of fibrin at specific lysine residues. In spite of a great increase in our knowledge of all these interconnected processes, much about the molecular mechanisms of the biological functions of fibrin(ogen) remains unknown, including some basic aspects of clotting, fibrinolysis, and molecular origins of fibrin mechanical properties. Even less is known concerning more complex (patho)physiological implications of fibrinogen and fibrin.

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Section: 4 Variations and Modulation Of Fibrin(ogen) Structure Andmentioning

confidence: 99%

Fibrin Formation, Structure and Properties

Weisel

Litvinov

2017

Subcellular Biochemistry

520

498

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show abstract

“…Furthermore, the shear rate affects clot formation triggered on tissue factor- plus collagen-coated plates, resulting in different fibrin deposition in different regions of a thrombus. 48 Nanoindentation analysis to evaluate clot biophysical properties shows this fibrin distribution pattern determines clot microelasticity, which may impact thrombus stability and risk of embolization. 48 Fourth, thrombin movement through the thrombus is substantially influenced by solute transport mechanisms mediated by cell packing density; this may also influence the amount of fibrin deposition in different regions of the clot.…”

Section: Fibrin Formation Structure and Stabilitymentioning

confidence: 99%

Fibrinogen and Fibrin in Hemostasis and Thrombosis

Kattula

Byrnes

Wolberg

2017

ATVB

292

249

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“…5 Despite these differences, platelet adhesion/activation, and fibrin deposition as the result of coagulation constitute the fundamental processes of thrombus formation. 6,7 Platelet activation occurs when they interact with activated ECs (with increased VWF release and selectin expression) via glycoprotein Ib-V-IX complex binding to VWF, or when they expose to subendothelial extracellular matrix components, such as collagen (via glycoprotein VI receptor), in the cases of endothelial injury or plaques rupture. 1,8 Coagulation cascade is triggered by coagulation factor VII binding to tissue factor (TF; extrinsic pathway) or by contact system activation via factor XII (FXII; intrinsic pathway), followed by a common pathway that leads to fibrin formation through intricate enzymatic actions of different coagulation factors (Figure).…”

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confidence: 99%