Design and performance testing of an axial-flow ventricular assist device developed at the Fu Wai Hospital in Beijing

Abstract

Purpose

Various ventricular assist devices (VADs) have been developed for clinical use in recent years. The aim of a multidisciplinary research team at the Fuwai Hospital of the Peking Union Medical College is to design and develop an axial flow left ventricular assist device (LVAD) for adults.

Methods

Using Computational Fluid Dynamics (CFD), the inflow characteristics of the axial flow pump were analyzed. After CFD analysis, the axial pump was fabricated using a 5-axis, computer numerical control (CNC) milling machine. Performances of the pump both in vitro and in vivo were tested.

Results

This VAD, which was developed after numerous CFD analyses for the flow characteristics of the pump, is 58.5 mm long, 30 mm wide and weighs 120 g. The pump can deliver 5 lpm for pressures of 100 mmHg over 8500 rpm. The NIH value was 0.01 g/100 L. The hemolysis, which was evaluated in an in vivo test, was a bit higher than the normal value, but remained within an acceptable range.

Conclusions

Performance of the pump in vitro and in vivo was considered sufficient for an LVAD. Further design improvements are being undertaken in terms of hemolysis and thrombosis to improve the biocompatibility of the pump.

Keywords

Ventricular assist device Axial flow pump Hemolysis Computational Fluid Dynamics

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References

Deng

M.C.

, Edwards

L.B.

, Hertz

M.I.

. Mechanical Circulatory Support Device Database of the International Society for Heart and Lung Transplantation: second annual report- 2004. J Heart Lung Transplant 2004; 23: 1027–34.

Park

S.J.

, Tector

, Piccioni

, Raines

. Left ventricular assist devices as destination therapy: a new look at survival. J Thorac Cardiovasc Surg 2005; 129: 9–17.

Song

, Throckmorton

A.L.

, Untaroiu

. Axial flow blood pumps. ASAIO J 2003; 49: 355–64.

Bludszuweit

. Model for a general mechanical blood damage prediction. Artif Organs 1995; 19: 583–9.

Giersiepen

, Wurzinger

L.J.

, Opitz

, Reul

. Estimation of shear stress-related blood damage in heart valve prostheses - in vitro comparison of 25 aortic valves. Int J Artif Organs 1990; 13: 300–6.

Naito

, Mizuguchi

, Nose

. The need for standardizing the index of hemolysis. Artif Organs 1994; 18: 7–10.

Wesolowski

S.A.

, Sauvage

L.R.

, Pinc

R.D.

. Extracorporeal circulation: the role of the pulse in maintenance of the systemic circulation during heart-lung by-pass. Surgery 1955; 37: 663–82.

Steegers

, Paul

, Reul

, Rau

. Leakage Flow at Mechanical Heart Valve Prostheses: Improved Washout or Increased Blood Damage? J Heart Valve Dis 1999; 8: 312–23.

, Antaki

, Snyder

, Wagner

, Borovetz

, Paden

. Design Optimization of Blood Shearing Instrument by Computational Fluid Dynamics. Artif Organs 2005; 29: 482–9.

10.

Philip

, Jaffrin

, Ding

. Hemolysis During Membrane Plasma Separation with Pulsed Flow Filtration Enhancement. J Biomech Eng 1994; 116: 514–20.

11.

Wood

, Anderson

, Allaire

, McDaniel

, Bearnson

. Numerical Solution for Blood Flow in a Centrifugal Ventricular Assist Device. Int J Artif Organs 1999; 22: 827–36.

12.

Paul

, Apel

, Klaus

, Schugner

, Schwindke

, Reul

. Shear stress related blood damage in laminar couette flow. Int J Artif Organs 2003; 27: 517–29.

13.

Goldstein

D.J.

. Worldwide experience with the MicroMed DeBakey Ventricular Assist Device as a bridge to transplantation. Circulation 2003; 108: 11272–7.