{"id":2223,"date":"2018-04-10T13:44:55","date_gmt":"2018-04-10T17:44:55","guid":{"rendered":"https:\/\/med.sites.unc.edu\/wolberglab\/files\/2018\/04\/contributions-of-fxiiia-to-clot-stability.jpeg"},"modified":"2018-04-10T13:46:38","modified_gmt":"2018-04-10T17:46:38","slug":"contributions-of-fxiiia-to-clot-stability","status":"inherit","type":"attachment","link":"https:\/\/www.med.unc.edu\/wolberglab\/scientific-images-2\/contributions-of-fxiiia-to-clot-stability\/","title":{"rendered":"Contributions of FXIIIa to clot stability"},"author":9746,"featured_media":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_acf_changed":false,"_links_to":"","_links_to_target":""},"class_list":["post-2223","attachment","type-attachment","status-inherit","hentry","odd"],"acf":[],"description":{"rendered":"

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Contributions of FXIIIa to clot biochemical and mechanical stability. FXIIIa cross-linking of plasma proteins (i.e., \u03b12-antiplasmin [\u03b12-AP]) increases the resistance of the clot to fibrinolysis. Cross-linking of the fibrin \u03b1- (purple) and \u03b3-chains (green) stiffens fibrin fibers and increases the mechanical stability of the clot. Increased mechanical stability renders the clot more resistant to shear forces. \u03b1-chain cross-linking enables RBC retention during clot contraction.<\/p>\n"},"caption":{"rendered":"

Contributions of FXIIIa to clot biochemical and mechanical stability. FXIIIa cross-linking of plasma proteins (i.e., \u03b12-antiplasmin [\u03b12-AP]) increases the resistance of the clot to fibrinolysis. Cross-linking of the fibrin \u03b1- (purple) and \u03b3-chains (green) stiffens fibrin fibers and increases the mechanical stability of the clot. Increased mechanical stability renders the clot more resistant to shear … Read more<\/a><\/p>\n"},"alt_text":"","media_type":"image","mime_type":"image\/jpeg","media_details":{"width":800,"height":463,"file":"2018\/04\/contributions-of-fxiiia-to-clot-stability.jpeg","sizes":{"thumbnail":{"file":"contributions-of-fxiiia-to-clot-stability-150x87.jpeg","width":150,"height":87,"mime_type":"image\/jpeg","source_url":"https:\/\/www.med.unc.edu\/wolberglab\/wp-content\/uploads\/sites\/645\/2018\/04\/contributions-of-fxiiia-to-clot-stability-150x87.jpeg"},"medium":{"file":"contributions-of-fxiiia-to-clot-stability-300x174.jpeg","width":300,"height":174,"mime_type":"image\/jpeg","source_url":"https:\/\/www.med.unc.edu\/wolberglab\/wp-content\/uploads\/sites\/645\/2018\/04\/contributions-of-fxiiia-to-clot-stability-300x174.jpeg"},"medium_large":{"file":"contributions-of-fxiiia-to-clot-stability-768x444.jpeg","width":768,"height":444,"mime_type":"image\/jpeg","source_url":"https:\/\/www.med.unc.edu\/wolberglab\/wp-content\/uploads\/sites\/645\/2018\/04\/contributions-of-fxiiia-to-clot-stability-768x444.jpeg"},"magicbox":{"file":"contributions-of-fxiiia-to-clot-stability-768x444.jpeg","width":768,"height":444,"mime_type":"image\/jpeg","source_url":"https:\/\/www.med.unc.edu\/wolberglab\/wp-content\/uploads\/sites\/645\/2018\/04\/contributions-of-fxiiia-to-clot-stability-768x444.jpeg"},"post_thumbnail":{"file":"contributions-of-fxiiia-to-clot-stability-64x64.jpeg","width":64,"height":64,"mime_type":"image\/jpeg","source_url":"https:\/\/www.med.unc.edu\/wolberglab\/wp-content\/uploads\/sites\/645\/2018\/04\/contributions-of-fxiiia-to-clot-stability-64x64.jpeg"},"post_thumbshort":{"file":"contributions-of-fxiiia-to-clot-stability-800x420.jpeg","width":800,"height":420,"mime_type":"image\/jpeg","source_url":"https:\/\/www.med.unc.edu\/wolberglab\/wp-content\/uploads\/sites\/645\/2018\/04\/contributions-of-fxiiia-to-clot-stability-800x420.jpeg"},"full":{"file":"contributions-of-fxiiia-to-clot-stability.jpeg","width":800,"height":463,"mime_type":"image\/jpeg","source_url":"https:\/\/www.med.unc.edu\/wolberglab\/wp-content\/uploads\/sites\/645\/2018\/04\/contributions-of-fxiiia-to-clot-stability.jpeg"}},"image_meta":{"aperture":"0","credit":"asilver2","camera":"","caption":"Contributions of FXIIIa to clot biochemical and mechanical stability. FXIIIa cross-linking of plasma proteins (i.e., \u03b12-antiplasmin [\u03b12-AP]) increases the resistance of the clot to fibrinolysis. Cross-linking of the fibrin \u03b1- (purple) and \u03b3-chains (green) stiffens fibrin fibers and increases the mechanical stability of the clot. Increased mechanical stability renders the clot more resistant to shear forces. \u03b1-chain cross-linking enables RBC retention during clot contraction.","created_timestamp":"0","copyright":"","focal_length":"0","iso":"0","shutter_speed":"0","title":"Contributions of FXIIIa to clot stability","orientation":"1","keywords":[]}},"post":2219,"source_url":"https:\/\/www.med.unc.edu\/wolberglab\/wp-content\/uploads\/sites\/645\/2018\/04\/contributions-of-fxiiia-to-clot-stability.jpeg","_links":{"self":[{"href":"https:\/\/www.med.unc.edu\/wolberglab\/wp-json\/wp\/v2\/media\/2223","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/www.med.unc.edu\/wolberglab\/wp-json\/wp\/v2\/media"}],"about":[{"href":"https:\/\/www.med.unc.edu\/wolberglab\/wp-json\/wp\/v2\/types\/attachment"}],"author":[{"embeddable":true,"href":"https:\/\/www.med.unc.edu\/wolberglab\/wp-json\/wp\/v2\/users\/9746"}],"replies":[{"embeddable":true,"href":"https:\/\/www.med.unc.edu\/wolberglab\/wp-json\/wp\/v2\/comments?post=2223"}]}}