Your search keyword '"Keiko Sugai"' showing total 2 results

1. Structural design of a newly developed pediatric circulatory assist device for fontan circulation by using shape memory alloy fiber

Author

Akihiro Yamada, Akira Tanaka, Shuichi Mochizuki, Takuya Shiga, K. Kamiya, Makoto Yoshizawa, Dai Homma, M. H. Omran, Tomoyuki Yambe, Hidekazu Miura, Masaaki Yamagishi, Telma Keiko Sugai, T. Kitano, and Yasuyuki Shiraishi

Subjects

Pulmonary Circulation, medicine.medical_specialty, Materials science, medicine.medical_treatment, Fontan Procedure, Fontan procedure, Electrical conduit, medicine.artery, Internal medicine, Alloys, Pressure, medicine, Humans, Child, Mechanical Phenomena, Equipment Design, medicine.anatomical_structure, Ventricle, Heat generation, Pulmonary artery, Circulatory system, Cuff, Cardiology, Heart-Assist Devices, Venous return curve, Biomedical engineering

Abstract

Total cavopulmonary connection (TCPC) is commonly applied for the surgical treatment of congenital heart disease such as single ventricle in pediatric patients. Patients with no ventricle in pulmonary circulation are treated along with Fontan algorithm, in which the systemic venous return is diverted directly to the pulmonary artery without passing through subpulmonary ventricle. In order to promote the pulmonary circulation after Fontan procedure, we developed a newly designed pulmonary circulatory assist device by using shape memory alloy fibers. We developed a pulmonary circulatory assist device as a non-blood contacting mechanical support system in pediatric patients with TCPC. The device has been designed to be installed like a cuff around the ePTFE TCPC conduit, which can contract from outside. We employed a covalent type functional anisotropic shape memory alloy fiber (Biometal, Toki Corporation, Tokyo Japan) as a servo actuator of the pulmonary circulatory assist device. The diameter of this fiber was 100 microns, and its contractile frequency was 2-3 Hz. Heat generation with electric current contracts these fibers and the conduit. The maximum contraction ratio of this fiber is about 7% in length. In order to extend its contractile ratio, we fabricated and installed mechanical structural units to control the length of fibers. In this study, we examined basic contractile functions of the device in the mock system. As a result, the internal pressure of the conduit increased to 63 mmHg by the mechanical contraction under the condition of 400 msec-current supply in the mock examination with the overflow tank of 10 mmHg loading.

Published

2011

2. Sensorless control for a sophisticated artificial myocardial contraction by using shape memory alloy fibre

Author

T. Fujimoto, Yasuyuki Shiraishi, Yun Luo, Kouichi Tabayashi, A. Baba, Ryo Sakata, Kou Imachi, Telma Keiko Sugai, Hongjian Liu, Shin-ichi Nitta, Dai Homma, Hiroshi Sasada, Mitsuo Umezu, Satoshi Konno, Fumihiro Sato, Tomoyuki Yambe, Noriyasu Masumoto, Makoto Yoshizawa, Yoshifumi Saijo, Y. Park, Miyuki Uematsu, and Akira Tanaka

Subjects

Engineering, business.industry, Transducers, Reproducibility of Results, Signal Processing, Computer-Assisted, Equipment Design, Heart, Artificial, Shape-memory alloy, Myocardial Contraction, Sensitivity and Specificity, Biometal, Signal, Displacement (vector), Equipment Failure Analysis, Modulation, Control theory, Therapy, Computer-Assisted, Alloys, Humans, Pulse wave, business, Pulse-width modulation

Abstract

The authors have been developing an artificial myocardium, which is capable of supporting natural contractile function from the outside of the ventricle. The system was originally designed by using sophisticated covalent shape memory alloy fibres, and the surface did not implicate blood compatibility. The purpose of our study on the development of artificial myocardium was to achieve the assistance of myocardial functional reproduction by the integrative small mechanical elements without sensors, so that the effective circulatory support could be accomplished. In this study, the authors fabricated the prototype artificial myocardial assist unit composed of the sophisticated shape memory alloy fibre (Biometal), the diameter of which was 100 microns, and examined the mechanical response by using pulse width modulation (PWM) control method in each unit. Prior to the evaluation of dynamic characteristics, the relationship between strain and electric resistance and also the inditial response of each unit were obtained. The component for the PWM control was designed in order to regulate the myocardial contractile function, which consisted of an originally-designed RISC microcomputer with the input of displacement, and its output signal was controlled by pulse wave modulation method. As a result, the optimal PWM parameters were confirmed and the fibrous displacement was successfully regulated under the different heat transfer conditions simulating internal body temperature as well as bias tensile loading. Then it was indicated that this control theory might be applied for more sophisticated ventricular passive or active restraint by the artificial myocardium on physiological demand.

Published

2008