Hemopump
The Hemopump was designed to allow for temporary support of a failing heart. It is a continuous flow pump, and does not need to be synced to the rhythm of the heart. It assists in temporary heart stimulation with conditions such as cardiogenic shock following acute myocardial infarction, heart failure from cardiopulmonary bypass, and more. The pump can continually monitor the left ventricle, which allows for perpetual observation of the hearts condition. This allows for any necessary changes to be made when needed. The pump operates at speeds between two hundred and ninety and four hundred and seventy revolutions per minute.[1]
The Hemopump Cardiac Assist System is an older design intra-arterial, axial-flow pump circulatory assist device concept that offers temporary left ventricular support to patients in refractory cardiogenic shock without requiring major surgery for insertion.[2]
The Hemopump draws blood with the impeller from the left ventricle and then exchanges it through the aorta. It can run at a constant speed, or two variable speeds during the cardiac cycle. Volume of the stroke, the rotating speed, or the pressure can all be tuned. These different setting are used for different conditions of the heart. It is optimal to run at two different speeds through a cardiac cycle as opposed to a constant speed. Running the pump at maximum capacity can be dangerous as it has led to complete collapse of the left ventricle in animal trials.[3]
When in use there was low risk involved with the use of the Hemopump. There were not been many complications in patients that had used the pump. Any complications resulting in morbidity were seen to be rare. The Hemopump was deemed safe for use in community hospitals and it was expected that the number of patients supported by this device would increase. More advanced technologies however did outdate this device making it obsolete.[2]
Commercial
The Hemopump was not successful commercially, however it was a precursor to many technologies that were developed off of the same concepts that were much more successful commercially. Attempts to make a low speed effective pump or LVAD are constantly being researched.[3]
Hemopump System Components
The Hemopump is of axial type, with a length twice that of the diameter. It is placed within a silicone cannula for protection. A steel cable is connected to it which drives it. Lubrication is fed to the pump through a catheter in the drive cable. The pump is inserted through the femoral artery, and then moved up until the tip of the cannula passes over the aortic valve.[1]
The pump is powered by a magnet synchronous motor. The motor has three coils which rotate and create a magnetic field. This receives a signal which can be applied to change the rotational speed. If the rotor is not at the proper signaled speed, it will not rotate at all. It uses a consistent voltage of 24 regardless of frequency. Under operation the motor is operated in a closed loop to avoid accidental stalls.[1]
It will pump up to 3-4 liters per minute of fluid in normal operating range.[4]
History
The pump was designed to allow for temporary support of a dying heart .It is a continuous flow pump, it does not need to be synced to the rhythm of the heart. It assists in temporary heart stimulation with conditions such as cardiogenic shock following acute myocardial infarction, heart failure from cardio pulmonary bypass, and more. The pump can continually monitor the left ventricle, which allows for perpetual observation the hearts condition. This allows for any necessary changes to be made when needed. The pump operates at speeds between two hundred and ninety and four hundred and seventy revolutions per minute.[4]
The pump was first used on a man 61 years of age with a failing heart. The pump successfully sustained him for 2 days after which he was discharged from the hospital.[4] It was also tested in 1990 on 7 persons with similar heart conditions. The tests were performed by Frasier and Associates.[5]
The pump is not in use anymore, but its design is being applied to other similar devices.[4]
References
- 1 2 3 E.E. Kunst; J.A. van Alste; T. Arts; H.B.K. Boom. ( November, 1994). Integrated Unit for Programmable Control of the 21F Hemopump and registration of Physiological Signs. Medical & Biological Engineering & Computing.
- 1 2 Robert T. Baldwin, MD; Branislav Radovanevic, MD; J. Michael Duncan, MD; Richard K. Wampler, MD; O.H. Frazier, MD (1992). Management of Patients Supported on the Hemopump® Cardiac Assist System. Texas Heart Institute Journal 1992;19:81-6.
- 1 2 He, P. P., Bai, J. J., & Xia, D. D. (2005). Optimum control of the Hemopump as a left-ventricular assist device. Medical & Biological Engineering & Computing, 43(1), 136-141.
- 1 2 3 4 Texas Heart Institue. (April, 2006). Hemopump.
- ↑ Urban Lönn, MD; John Wulff, MD; Karl-Yngve Keck, MSEE; Bengt Wranne, MD, PhD; Per Ask, MSEE, PhD; Bengt Peterzén, MD; Henrik Casimir-Ahn, MD, PhD. (January, 1997). Flow Characteristics of the Hemopump: An Experimental In Vitro Study. The Annals of Thoracic Surgery.