Virtual Patient Simulator for the Perfusion Resource Management Drill

Shinji Ninomiya; Megumi Tokaji; Asako Tokumine; Tatsuya Kurosaki

doi:10.1051/ject/200941206

All issues

Volume 41 / No 4 (December 2009)

J Extra Corpor Technol, 41 4 (2009) 206-212

Abstract

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Issue		J Extra Corpor Technol Volume 41, Number 4, December 2009


Page(s)		206 - 212
DOI		https://doi.org/10.1051/ject/200941206
Published online		15 July 2009

J Extra Corpor Technol 2009, 41, 206-212

Abstract

Virtual Patient Simulator for the Perfusion Resource Management Drill

Dr. Eng Shinji Ninomiya^*, Megumi TokajiMS^†, Asako TokuminePhD^* and Tatsuya KurosakiMD^‡

^* Department of Clinical Engineering, Hiroshima International University, Hiroshima, Japan
^† Department of Clinical Support, Hiroshima University Hospital, Hiroshima, Japan
^‡ Department of Cardiovascular Surgery, Faculty of Medicine, Hiroshima University, Hiroshima, Japan

Address correspondence to: Shinji Ninomiya, Dr. Eng., Department of Clinical Engineering, Hiroshima International University, 555-36 Gakuen-dai, Kurose-town, Higashi-hiroshima-city, Hiroshima 724-0695, Japan. E-mail: s-nino@hs.hirokoku-u.ac.jp

Received: 15 June 2009
Accepted: 27 August 2009

Abstract

Perfusionists require a detailed understanding of a patient’s physiological status while comprehending the mechanics and engineering of the cardiopulmonary bypass system, so it is beneficial for them to obtain relevant practical skills using extra-corporeal circulation technology and educational physiological simulators. We designed a perfusion simulator system (ECCSIM: Extracorporeal Circulation SIMulator system) based on a hybrid of a simple hydraulic mock circulation loop linked to a computer simulation model. Patient physiological conditions (height, weight, and cardiac indices) were determined by a parameter estimation procedure and used to accurately reproduce hemodynamic conditions. Extracorporeal circulation trainees in pre-clinical education were able to maintain venous oxygen saturation levels above 50%, except during cardiac standstill and a brief resumption of pulsation. Infant amplitudes of reservoir volume oscillation and flow rate were greatly increased compared with adult cardiovascular parameters, this enabled the instructor to control the difficulty level of the operation using different hemodynamic variations. High-fidelity simula tor systems with controllable difficulty levels and high physiological reproducibility are useful in constructing a perfusion resource management environment that enable basic training and periodic crisis management drills to be performed.

Key words: cardiopulmonary bypass / computer simulation / hemodynamics / perfusion / physiology

Presented at the 44th Annual Conference of Japanese Society of Artificial Organs, Kanagawa, Japan, November 2, 2006; and the 45th Annual Conference of Japanese Society of Artificial Organs, Osaka, Japan, October 30, 2007.

The senior author has stated that authors have reported no material, financial, or other relationship with any healthcare-related business or other entity whose products or services are discussed in this paper.

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