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Clot stability as a determinant of effective factor VIII replacement in hemophilia A

ESSENTIALS: Factor VIII (FVIII) replacement in hemophilia A corrects bleeding due to low thrombin generation. There is uncertainty about the minimal or trough level of FVIII needed for optimal treatment. FVIII improves physical properties of hemophilia clots, including stiffness and permeability. Fi...

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Detalles Bibliográficos
Autores principales: Leong, Lilley, Chernysh, Irina N., Xu, Yifan, Sim, Derek, Nagaswami, Chandrasekaran, de Lange, Zelda, Kosolapova, Sofia, Cuker, Adam, Kauser, Katalin, Weisel, John W.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: John Wiley and Sons Inc. 2017
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5920517/
https://www.ncbi.nlm.nih.gov/pubmed/29713693
http://dx.doi.org/10.1002/rth2.12034
Descripción
Sumario:ESSENTIALS: Factor VIII (FVIII) replacement in hemophilia A corrects bleeding due to low thrombin generation. There is uncertainty about the minimal or trough level of FVIII needed for optimal treatment. FVIII improves physical properties of hemophilia clots, including stiffness and permeability. Fibrinogen and blood cells also stabilize hemophilia clots to decrease bleeding risk. BACKGROUND: Factor VIII (FVIII) replacement is standard of care for patients with hemophilia A (HemA); however, patient response does not always correlate with FVIII levels. We hypothesize this may be in part due to the physical properties of clots and contributions of fibrin, platelets, and erythrocytes, which may be important for hemostasis. OBJECTIVE: To understand how FVIII contributes to effective hemostasis in terms of clot structure and mechanical properties PATIENTS/METHODS: In vitro HemA clots in human plasma or whole blood were analyzed using turbidity waveform analysis, confocal microscopy, and rheometry with or without added FVIII. In vivo clots from saphenous vein puncture in wild‐type and HemA mice with varying FVIII levels were examined using scanning electron microscopy. RESULTS: FVIII profoundly affected HemA clot structure and physical properties; added FVIII converted the open and porous fibrin meshwork and low stiffness of HemA clots to a highly branched and dense meshwork with higher stiffness. Platelets and erythrocytes incorporated into clots modulated clot properties. The clots formed in the mouse saphenous vein model contained variable amounts of compressed erythrocytes (polyhedrocytes), fibrin, and platelets depending on the levels of FVIII, correlating with bleeding times. FVIII effects on clot characteristics were dose‐dependent and reached a maximum at ~25% FVIII, such that HemA clots formed with this level of FVIII resembled clots from unaffected controls. CONCLUSIONS: Effective clot formation can be achieved in HemA by replacement therapy, which alters the architecture of the fibrin network and associated cells, thus increasing clot stiffness and decreasing clot permeability.