The Artificial Heart: A Design Example

1. The Artificial Heart:A Design Example BIOE 1000 October 18, 2001

2. The Human Heart • Heart has four chambers • Right chambers pump blood to lungs to receive oxygen • Left chambers pump oxygenated blood from lungs to rest of the body We bring life to engineering!

3. The Human Heart • Right and left atria receive blood • Right and left ventricles pump blood • Valves produce one-way blood flow from atria  ventricles  arteries • Energy to pump blood comes from nutrients and oxygen in blood • The blood supply to the heart is provided by coronary arteries We bring life to engineering!

4. Heart Disease • Heart attack: blockage of coronary artery damages portion of heart muscle • Congestive heart failure: gradual weakening of heart • Millions suffer from heart disease • Many cases are treatable with lifestyle changes, drugs and/or surgery • Surviving patients suffering from most severe cases need new hearts! We bring life to engineering!

5. The Need for a Heart Substitute • 100,000 Americans/year suffering from severe heart disease need new hearts • Only 2,000 patients receive heart transplants • Conclusion: many patients die waiting for a new heart! • A suitable alternative to donor hearts could prolong thousands of lives We bring life to engineering!

6. History of Heart Substitutes • WWII: first open heart surgeries • 1953: heart-lung machine successfully used during heart surgery • 1958: Drs. Willem Kolff and Tetsuzo Akutsu sustain a dog for 90 minutes with a PVC artificial heart • 1967: Dr. Christian Barnard transplants a donor heart into a 59 year old man (he survived 18 days) PVC heart (1958) silicone heart (1965) We bring life to engineering!

7. History of Heart Substitutes • 1969: Dr. Denton Cooley uses an artificial heart to sustain a patient waiting for a donor (survived 3 days) • 1972: Cyclosporine introduced to suppress immune responses of transplant recipients • 1982: Dr. William DeVries implants the Jarvik-7 artificial heart into Dr. Barney Clark (he survived 112 days) Liotta heart (1969) Jarvik-7 (1982) We bring life to engineering!

8. Why Heart Substitutes Fail • Immune response “rejects” transplant or side effects due to immune suppression • Infection due to tubes and wires passing through skin • Formation of clots • Damage to red blood cells • Lack of pulsatile blood flow? We bring life to engineering!

9. Design Process • Identify the problem or need to address • Specify details/criteria of an adequate solution to your problem • Implement various solutions that meet the criteria you specified • Test to determine which solution is most viable • Further testing to refine the solution you chose We bring life to engineering!

10. Design Refinement • Process is iterative • You need to repeat various steps after testing • Make design changes based on test results • Failed designs • Design didn’t meet criteria • Could be due to inappropriate criteria We bring life to engineering!

11. Criteria for a Heart Substitute • Must fit into chest cavity and connect to atria, pulmonary artery and aorta quickly • Provide an adequate blood flow (8 – 10 liters/min) • Send deoxygenated blood to the lungs and oxygenated blood to the body • Operate continuously for an indefinite period of time • Provide adequate warning if something is wrong or if it is going to fail We bring life to engineering!

12. Criteria for a Heart Substitute • Should increase/decrease blood flow based on patient activity level • Should not evoke an immune response • No wires or tubes that penetrate the skin • Should not produce blood clots • Should not damage red blood cells • Ideally should have pulsatile blood flow • Many others we haven’t thought of! We bring life to engineering!

13. The AbioCor® Heart • Implanted into 59 year old Robert Tools on July 2, 2001 at Jewish Hospital in Louisville KY (96 days) • Patient is able to walk around, organs are functioning normally, undergoing daily rehabilitation for eventual release We bring life to engineering!

14. How the AbioCor® Heart Works • Hydraulic pump forces blood to lungs and body • Power is provided by an internal rechargeable battery • Battery is recharged by coils on surface and below skin • Internal controller monitors system and controls pump speed We bring life to engineering!

15. Surgical Procedure • Implant controller, battery and coil • Connect patient to heart-lung machine • Cut away ventricles • Sew grafts onto atria and arteries • Connect implants to grafts • Remove patient from heart-lung machine We bring life to engineering!

16. AbioCor® Design Criteria • Grapefruit size, weighs 2 lbs, requires a 7 hour surgery for implantation • Can provide up to 8 liters/min of blood to the lungs and body • Has two chambers for pumping deoxygenated blood to the lungs and oxygenated blood to the body • Wireless energy transfer system allows for continuous operation • Internal controller monitors operation We bring life to engineering!

17. AbioCor® Design Criteria • Internal controller increases/decreases blood flow based on blood oxygen levels • Materials are inert to the immune system • Completely contained within the chest – no wires or tubing through skin! • Made of special materials and special pump design to prevent clots and RBC damage • Pumping alternates between chambers, creating a pulsatile blood flow We bring life to engineering!