Over the past several years, we have made significant progress in the mechanistic study of surface thrombus formation and prevention using novel surface modification methods. In the precious application, heparin immobilized polymer surfaces using dynamic hydrophilic spacer groups (by in situ surface immobilization and coating of SPUU-PEO-Heparin graft copolymer) demonstrated a significant reduction in thrombus formation on surfaces in in vitro, ex vivo and in vivo studies. In this renewal application, we propose to modify medical polymer surfaces using surface immobilized genetically engineered antithrombotic agent (Hirudin) and fibrinolytic (t-PA) agents. Hirudin and t-PA will be used because they demonstrate distinct pharmacologic advantages over the more commonly used heparin and urokinase, respectively. Novel surface amplification chemistry will be introduced to immobilize Hirudin or t-PA on the polymer surfaces, based on our hydrophilic spacer hypothesis. It is expected that the use of amplifying polymer and PEO spacer can increase surface bioactivity as well as the surface concentration of the immobilized agents. In addition, the dynamic hydrophilic environment at the blood/polymer interface can reduce protein absorption and platelet interaction. Hirudin (or t-PA) immobilized surfaces should suppress the formation of surface-induced thrombi by Hirudin's thrombin inhibitation (i.e., platelet activation and fibrin formation) or by t-PA's fibrinolytic activity. The detailed suppression mechanism will be investigated in both in vitro and vivo studies. Obtained results will be correlated with results form our previous studies of heparin immobilized surfaces. This valuable information will be used to provide a more effective model for surface behavior using genetically engineered bioactive agents and to design blood contacting medical devices.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL020251-16
Application #
3336090
Study Section
Surgery and Bioengineering Study Section (SB)
Project Start
1976-12-01
Project End
1995-11-30
Budget Start
1992-12-01
Budget End
1993-11-30
Support Year
16
Fiscal Year
1993
Total Cost
Indirect Cost
Name
University of Utah
Department
Type
Schools of Pharmacy
DUNS #
City
Salt Lake City
State
UT
Country
United States
Zip Code
84112
Kim, S W; Jacobs, H (1996) Design of nonthrombogenic polymer surfaces for blood-contacting medical devices. Blood Purif 14:357-72
Byun, Y; Jacobs, H A; Feijen, J et al. (1996) Effect of fibronectin on the binding of antithrombin III to immobilized heparin. J Biomed Mater Res 30:95-100
Byun, Y; Jacobs, H A; Kim, S W (1996) Binding of antithrombin III and thrombin to immobilized heparin under flow conditions. Biotechnol Prog 12:217-25
Byun, Y; Jacobs, H A; Kim, S W (1994) Heparin surface immobilization through hydrophilic spacers: thrombin and antithrombin III binding kinetics. J Biomater Sci Polym Ed 6:1-13
Byun, Y; Jacobs, H A; Kim, S W (1992) Binding kinetics of thrombin and antithrombin III with immobilized heparin using a spacer. ASAIO J 38:M649-53
Piao, A Z; Jacobs, H A; Park, K D et al. (1992) Heparin immobilization by surface amplification. ASAIO J 38:M638-43
Nojiri, C; Okano, T; Koyanagi, H et al. (1992) In vivo protein adsorption on polymers: visualization of adsorbed proteins on vascular implants in dogs. J Biomater Sci Polym Ed 4:75-88
Park, K D; Kim, W G; Jacobs, H et al. (1992) Blood compatibility of SPUU-PEO-heparin graft copolymers. J Biomed Mater Res 26:739-56
Kim, W G; Park, K D; Mohammad, S F et al. (1991) SPUU-PEO-heparin graft copolymer surfaces. Patency and platelet deposition in canine small diameter arterial grafts. ASAIO Trans 37:M148-9
Lin, S C; Jacobs, H A; Kim, S W (1991) Heparin immobilization increased through chemical amplification. J Biomed Mater Res 25:791-5

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