Hemocompatibility of Biomaterials for Clinical Applications

<p>1. Introduction </p> <p>Part I General<br>2. Blood composition, function and response to biomaterials <br>3. Modelling the hemocompatibility of biomaterials and medical devices <br>4. Tuning platelet responses to improve implant integration <br>5. Standards and test protocols for testing the hemocompatibility of biomaterials <br>6. Test methods for hemocompatibility of biomaterials </p> <p>Part II Improving the hemocompatibility of biomaterial surfaces<br>7. Analysing biomaterial surfaces and blood-surface interactions <br>8. Techniques for modifying biomaterial surfaces to improve hemocompatibility <br>9. Coatings for biomaterials to improve hemocompatibility </p> <p>Part III Improving the hemocompatibility of types of biomaterial<br>10. Improving the hemocompatibility of biomedical polymers <br>11. Improving the hemocompatibility of metallic biomaterials <br>12. Improving the hemocompatibility of ceramic biomaterials <br>13. Improving the hemocompatibility of biomedical composites </p> <p>Part IV Improving the hemocompatibility of biomedical devices<br>14. Improving the hemocompatibility of stents <br>15. Improving the hemocompatibility of blood filters for biomedical applications <br>16. Improving the hemocompatibility of oxygenators for biomedical applications <br>17. Improving the hemocompatibility of vascular grafts <br>18. Improving the hemocompatibility of heart valves <br>19. Improving the hemocompatibility of neural implants </p>