Title of article
Molecular barriers to biomaterial thrombosis by modification of surface proteins with polyethylene glycol
Author/Authors
Christopher R. Deible، نويسنده , , Patty Petrosko، نويسنده , , Peter C. Johnson، نويسنده , , Eric J. Beckman، نويسنده , , Alan J. Russell، نويسنده , , William R. Wagner، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 1999
Pages
9
From page
101
To page
109
Abstract
For cardiovascular biomaterials, thrombosis, thromboembolism and vascular graft occlusion are believed to be precipitated by the adsorption of proteins containing adhesive ligands for platelets. Polyethylene-glycol-diisocyanate (PEG-diisocyanate, 3400 MW) may potentially react with protein amines to form molecular barriers on adsorbed proteins on biomaterials, thereby masking adhesive ligands and preventing acute surface thrombosis. To test this notion, PE, PTFE, and glass microconduits were pre-adsorbed with fibrinogen and treated with PEG-diisocyanate, non-reactive PEG-dihydroxyl, or remained untreated. Following perfusion of 111In-labeled platelets in whole human blood for 1 min (wall shear rate=312 s-1), PEG-diisocyanate treated surfaces experienced 96% (PE), 97% (PTFE) and 94% (glass) less platelet deposition than untreated surfaces. Similar reductions were seen for PEG-diisocyanate versus PEG-dihydroxyl treatment. Low shear perfusions of plasma for one hour prior to blood contact did not reduce the inhibitory effect of PEG-diisocyanate. Platelet adhesion onto collagen coated glass coverslips and platelet deposition onto preclotted Dacron was also reduced by treatment with PEG-diisocyanate (93 and 91%, respectively). Protein-reactive PEG may thus have utility in forming molecular barriers on surface associated proteins to inhibit acute thrombosis on cardiovascular biomaterials.
Keywords
fibrinogen , Adsorbed proteins , Surface modi?cation , platelet , polyethylene glycol
Journal title
Biomaterials
Serial Year
1999
Journal title
Biomaterials
Record number
543161
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