A cost-effective extracorporeal magnetically-levitated centrifugal blood pump employing a disposable magnet-free impeller

Abstract

In the field of rotary blood pumps, contactless support of the impeller by a magnetic bearing has been identified as a promising method to reduce blood damage and enhance durability. The authors developed a two-degrees-of-freedom radial controlled magnetic bearing system without a permanent magnet in the impeller in order that a low-cost disposable pump-head for an extracorporeal centrifugal blood pump could be manufactured more easily. Stable levitation and contactless rotation of the ‘magnet-free’ impeller were realized for a prototype blood-pump that made use of this magnetic bearing. The run-out of the impeller position at between 1000 r/min and 3000 r/min was less than 40 µm in the radial-controlled directions. The total power consumption of the magnetic bearing was less than 1 W at the same rotational speeds. When the pump was operated, a flow rate of 5 l/min against a head pressure of 78.66 kPa was achieved at a rotational speed of 4000 r/min, which is sufficient for extracorporeal circulation support. The proposed technology offers the advantage of low-cost mass production of disposable pump heads.

Keywords

extracorporeal centrifugal blood pump disposable pump head magnetic bearing magnet-free impeller

Get full access to this article

View all access options for this article.

References

World Health Organization (WHO), Disease and injury regional estimates for 2004. http://www.who.int/healthinfo/global_burden_disease/en/.

Hoshi

Shinshi

Takatani

, Third-generation blood pumps with mechanical noncontact magnetic bearings. Artif Organs, 2006, 30(5), 324–338.

Gregoric

I. D.

Cohn

W. E.

Akay

M. H.

Francesca

S. L.

Myers

Frazier

O. H.

CentriMag left ventricular assist system, Tex. Heart Inst. J., 2008, 35(2), 184–185.

John

Liao

Lietz

Kamdar

Colvin-Adams

Boyle

Miller

Joyce

Experience with the Levitronix CentriMag circulatory support system as a bridge to decision in patients with refractory acute cardiogenic shock and multisystem organ failure. J Thorac Cardio Surg, 2007, 134(2), 351–358.

Hijikata

Shinshi

Asama

Hoshi

Takatani

Shimokohbe

, A magnetically levitated centrifugal blood pump with a simple-structured disposable pump head, Artificial Organs, 2008, 32(7), 531–540.

Someya

Kobayashi

Waguri

Ushiyama

Nagaoka

Hijikata

Shinshi

Arai

Takatani

Development of a disposable maglev centrifugal blood pump intended for one-month support in bridge-to-bridge applications: in vitro and initial in vivo evaluation, Artificial Organs, 2009, 33(9), 704–713.

Nagaoka

Someya

Kitao

Kimura

Ushiyama

Hijikata

Shinshi

Arai

Takatani

Development of a disposable magnetically levitated centrifugal blood pump (MedTech Dispo) intended for bridge-to-bridge applications - Two-week in vivo evaluation, Artificial Organs, 2010, 34(9), 778–791.

Dohi

, Recycle and catalytic approaches for the development of a rare-metal-free synthetic method using hypervalent iodine reagent, Chem. Pharm. Bull., 2010, 58(2), 135–142.

Asama

Shinshi

Hoshi

Takani

Shimokohbe

Dynamic characteristics of a magnetically-levitated impeller in a centrifugal blood pump, Artificial Organs, 2007, 31(4), 301–311.

10.

Kaschke

Dust iron core, US patent 1943: 2330590.

11.

Hijikata

Sobajima

Shinshi

Nagamine

Wada

Takatani

Shimokohbe

Disposable maglev centrifugal blood pump utilizing a cone-shaped impeller, Artificial Organs, 2010, 34(8), 669–677.