Polymeric Surface Modifications of Tantalum Stents
| Autor: | Arthur B. Fontaine, Randy Hoffman, Kurt W. Koelling, Susan Dos Passos, Dimitrios G. Spigos, Jody Cearlock |
|---|---|
| Rok vydání: | 1996 |
| Předmět: |
Blood Platelets
Time Factors Polymers Surface Properties Swine Polyurethanes Tantalum chemistry.chemical_element Biocompatible Materials 02 engineering and technology Xylenes 030204 cardiovascular system & hematology chemistry.chemical_compound 03 medical and health sciences Arteriovenous Shunt Surgical Platelet Adhesiveness 0302 clinical medicine Parylene Medicine Animals Radiology Nuclear Medicine and imaging Composite material Polymeric surface Polyurethane business.industry Indium Radioisotopes Graft Occlusion Vascular Thrombosis 021001 nanoscience & nanotechnology Microscopy Electron chemistry Stents Surgery business 0210 nano-technology Cardiology and Cardiovascular Medicine |
| Zdroj: | Journal of Endovascular Therapy. 3:276-283 |
| ISSN: | 1545-1550 1526-6028 |
| DOI: | 10.1177/152660289600300306 |
| Popis: | Purpose: To compare two kinds of polymer-coated tantalum stents with bare tantalum stents (control) to determine if the coatings can improve thromboresistance. Methods: Twenty-seven Fontaine-Dake stents were balloon expanded in three 8-mm × 80-cm.polytetrafluoroethylene (PTFE) grafts; 9 stents were bare tantalum (T); 9 were coated with polyetherurethane (PL); and 9 were coated with parylene (PA). There were 9 stents placed in each graft as follows: 3 tantalum, 3 polyetherurethane, and 3 parylene. In swine whose platelets had been radiolabeled with indium 111, the ends of each stented graft were connected to 14F femoral and venous sheaths to create an ex vivo fistula. Each graft was exposed to blood for 30, 60, and 120 minutes. At the end of each test period, the stented grafts were disconnected from the sheaths, flushed with saline until clear, and then flushed with formalin. The stents were removed from the grafts, and a radionuclide well counter recorded radionuclide counts from each stent type at each period of blood contact. These values were converted to platelet density per 1000 mUm2. Stents were then photographed and scanned with electron microscopy (EM) for qualitative analysis. Possible significant differences in platelet adhesion with the three types of stents (both between stent groups and within stent groups) were examined using a two-tailed Student's f-test. Results: There were significantly fewer platelets adsorbed on PA versus T at all time periods (p < 0.005); on PL versus T at 60 and 120 minutes (p < 0.005); and on PA versus PL at 30 and 120 minutes (p < 0.0005). There was no significant difference in platelet density within each stent group (p = 0.1). Mean platelet density (number of platelets per 1000 mUm2 ± SD) was as follows: at 30 minutes: T = 1891 ± 965; PL = 373 ± 193; and PA = 27 ± 3; at 60 minutes: T = 6226 ± 1621; PL = 1573 ± 793; and PA = 1185 ± 710; at 120 minutes: T = 5307 ± 591; PL = 3164 ± 318; and PA = 180 ± 100. Gross inspection of the 120-minute groups demonstrated focal areas of thrombus on T, less on PL, and none on PA. Scanning EM demonstrated extensive platelet accumulation covering T at all time periods, less on PL, and even less on PA. Conclusions: Polymeric surface modification of tantalum stents with parylene and/or polyetherurethane can improve the acute thromboresistance of these devices; parylene appears to be the more thromboresistant of the two coatings. |
| Databáze: | OpenAIRE |
| Externí odkaz: |
|