Mechanical Support for Heart Failure

Part I. Overview of the Mechanical Circulatory Support (MCS).- 1. A History of Mechanical Circulatory Support.- 2. A Personalized History of Rotary Blood Pumps.- 3. Overview of Mechanical Circulatory Support Devices and Concepts.- 4. Physiology of Blood-pump Circulation in Heart Failure.- 5. Physiology of Blood Pump Circulation in Heart Failure.- 6. Engineering Requirements for Mechanical Circulatory Support Devices.- 7. Clinical Requirements for Mechanical Circulatory Support Devices.- 8. Engineering Perspectives for Mechanical Circulatory Support Devices.- Part II: Indications and Selection for Mechanical Circulatory Support.-9. Patient Population and Selection Criteria for Mechanical Circulatory Support.- 10. Mechanical Circulatory Support Therapies; Right Timing and Prognosis Considerations.- 11. Perioperative Considerations in Left Ventricular Assist Device Placement.- 12. Left Ventricular Assist Devices: Management and Surgical Techniques.- 13. Mechanical Circulatory Support for Biventricular Failure: Patient Selection and Management Options.- 14. Status and Availability of a Total Artificial Heart.- 15. Extracorporeal Membrane Oxygenation Techniques and Modern Considerations.- 16. Less Invasive Extra-Pericardial Placement (LIEPP) of LVAD.- Part III. Parameters of Physiologic and Non-Physiologic Blood Flow.- 17. Pulsatile Mechanical Circulation, Physiology and Pump Technology.- 18. Pathophysiological Determinants Relevant in Blood Pump Control.- 19. End-Organ Physiology under Continuous Flow Mechanical Circulatory Support.- 20. Quantification of Pulsatility during Mechanical Circulatory Support.-21. Pulsatility as an Option with Continuous-Flow Mechanical Circulatory Support Devices.- Part IV. Current Technology and Methods.-22. Implantable Continuous-Flow Blood Pump Technology and Features.- 23. Partial Support with Mechanical Circulatory Support Devices.- 24. Percutaneous Mechanical Circulatory Support Technologies.- 25. Computational Fluid Dynamics for Mechanical Circulatory Support Device Development.- 26. Hemodynamic Modelling and Simulations for Mechanical Circulatory Support.- 27. Options for Modeling and Simulations Used in Mechanical Circulatory Support Development.- Part V. Evolving Technologies and Device Concepts.- 28. Emerging Continuous Flow Blood Pump Technologies.- 29. The Development of Advanced Ventricular Assist Device as a Next Generation Ventricular Assist Device.- 30. Cleveland Clinic Total Artificial Heart.- 31. The ReinVAD LVAD – Smart Technology to Enhance Long-Term Circulatory Support Therapy.- 32. EVAHEART 2 Left Ventricular Assist System: A Hemocompatible Centrifugal Pump with Physiological Pulsatility.-33. A Novel Rotary Total Artificial Heart Using a Single Shuttling Impeller.- 34. New Mechanical Circulatory Device: TORVAD.- 35. BiVACOR Total Artificial Heart.-36. The Penn State Pediatric Total Artificial Heart.- 37. CorWave LVAD: Insight Into Device Concept And Stage of Development.- 38. Progress on Total Artificial Heart for Pediatric Patients.- 39. Progress on Wireless LVAD and Energy Sources for Mechanical Circulatory Systems.- Part VI. Management Strategies and Limitations of MCS.- 40. Risk Factors for Mechanical Circulatory Support Use and Risk Assessment.- 41. Gastrointestinal Bleeding in Mechanical Circulatory Support Patients.- 42. Postoperative Management Strategies in Mechanical Circulatory Support Patients.- 43. Palliative Care in MCS patients: Insights into Current Practice and Outcomes.- Part VII. Future Perspectives.- 44. Clinical Demands and Challenges for Future Mechanical Circulatory Support Technologies.- 45. Smart Mechanical Circulatory Support Devices:Requirements and Perspectives.- 46. Novel Solutions for Patient Monitoring and Mechanical Circulatory Support Device  Control.