Your search keyword '"Kaoru Imanishi"' showing total 2 results

1. The second and third model of the flow transformed pulsatile total artificial heart

Author

A. Suzuki, Akimasa Kouno, Takumi Yonezawa, Yusuke Abe, Iwao Fujimasa, K. Mabuchi, Toshiya Ono, Tsuneo Chinzei, Kazuhiko Atsumi, Takashi Isoyama, Kaoru Imanishi, and Kou Imachi

Subjects

Physics, Hot Temperature, Biophysics, Pulsatile flow, Biomedical Engineering, Hemodynamics, Bioengineering, General Medicine, Blood flow, Heart, Artificial, In Vitro Techniques, Centrifugal pump, Prosthesis Design, law.invention, Biomaterials, Afterload, law, Artificial heart, Heat generation, Pulsatile Flow, Circulatory system, Arterial blood, Humans, Biomedical engineering

Abstract

For the purpose of future total implantation, a new pulsatile total artificial heart, a flow transformed pulsatile total artificial heart (FTPTAH), in which the continuous flow from a single centrifugal pump (CFP) was converted to pulsatile flow by switching two three-way valves that could alternately perfuse the systemic and pulmonary circulation, was proposed, and the data from the prototype model were reported. As the next step, the second model, in which a CFP and a spool valve (SV) driven with a solenoid were fabricated in one piece, was made and tested in a mock circulatory system. The system could send 4.7 L/min of pulsatile output alternately to the pulmonary artery and aorta, with 30 and 100 mmHg afterload, respectively, at 3000 rpm CFP. However, three problems were encountered: the output was not enough, mixture or inversion of venous and arterial blood in the CFP would occur, and heat generation at the solenoid was very severe. To solve these problems, a third model was designed in the current study. To increase pump output, hydrodynamic analysis was performed. The SV was divided into inlet and outlet to control the blood mixture or inversion. To suppress heat generation, each SV was driven back and forth by two solenoids, one on each side of the SV. The model revealed satisfactory results in a mock circulatory system.

Published

1992

2. Fabrication of a jellyfish valve for use in an artificial heart

Author

KUNIHIKO MABUCHI, TSUNEO CHINZEI, YUSUKE ABE, KAORU IMANISHI, TAKUMI YONEZAWA, AKIMASA KOUNO, TOSHIYA ONO, HIROAKI NOZAWA, TAKASHI ISOYAMA, KAZUHIKO ATSUMI, and IWAO FUJIMASA

Subjects

Jellyfish, Fabrication, Biophysics, Biomedical Engineering, Bioengineering, Heart, Artificial, In Vitro Techniques, Prosthesis Design, law.invention, Biomaterials, law, Valve seat, Artificial heart, biology.animal, Materials Testing, Medicine, Animals, Humans, Animal study, Blood compatibility, biology, business.industry, Goats, Hemodynamics, General Medicine, Blood pump, Evaluation Studies as Topic, Heart Valve Prosthesis, Microscopy, Electron, Scanning, Computer-Aided Design, Thin membrane, business, Biomedical engineering

Abstract

For a valve to be fabricated seamlessly into an artificial heart (AH) blood pump, a jellyfish valve has been developed, in which a thin membrane is fixed at the center of a valve seat having several spokes to protect against prolapse of the membrane. The valve is superior in performances to a Bjork-Shiley valve, and reveals good blood compatibility. The valve would be very useful not only for AH animal study, but for future clinical use in infants to adults. Several institutions are already trying the valve. In this paper, the fabrication of the jellyfish valve is introduced, and in vitro and in vivo results summarized. A computer aided design (CAD) system was developed to cut a male wax mold of the valve seat. The input parameters to the CAD are diameter, height, thickness of rim, number of spokes, width and thickness of spokes, etc. Jellyfish valves with diameters of 4 to 27 mm have already been fabricated for many types of AHs and assist pumps.

Published

1992