Kashihara Koji
RIKEN, Brain Science Institute, 2-1, Hirosawa, Wako-shi, Saitama, 351-0198, Japan.
Ann Biomed Eng. 2006 Dec;34(12):1846-69. doi: 10.1007/s10439-006-9190-9. Epub 2006 Oct 18.
Automated drug-delivery systems that can tolerate various responses to therapeutic agents have been required to control hemodynamic variables with heart failure. This study is intended to evaluate the control performance of a multiple adaptive predictive control based on neural networks (MAPC(NN)) to regulate the unexpected responses to therapeutic agents of cardiac output (CO) and mean arterial pressure (MAP) in cases of heart failure. The NN components in the MAPC(NN) learned nonlinear responses of CO and MAP determined by hemodynamics of dogs with heart failure. The MAPC(NN) performed ideal control against unexpected (1) drug interactions, (2) acute disturbances, and (3) time-variant responses of hemodynamics [average errors between setpoints (+35 ml kg(-1) min(-1) in CO and +/-0 mmHg in MAP) and observed responses; 6.4, 3.7, and 4.2 ml kg(-1) min(-1) in CO and 1.6, 1.4, and 2.7 mmHg (10.5, 20.8, and 15.3 mmHg without a vasodilator) in MAP] during 120-min closed-loop control. The MAPC(NN) could also regulate the hemodynamics in actual heart failure of a dog. Robust regulation of hemodynamics by the MAPC(NN) was attributable to the ability of on-line adaptation to adopt various responses and predictive control using the NN. Results demonstrate the feasibility of applying the MAPC(NN) using a simple NN to clinical situations.
为了控制心力衰竭患者的血流动力学变量,需要能够耐受对治疗药物的各种反应的自动给药系统。本研究旨在评估基于神经网络的多重自适应预测控制(MAPC(NN))在心力衰竭情况下调节心输出量(CO)和平均动脉压(MAP)对治疗药物的意外反应的控制性能。MAPC(NN)中的神经网络组件学习了由心力衰竭犬的血流动力学决定的CO和MAP的非线性反应。在120分钟的闭环控制期间,MAPC(NN)对意外的(1)药物相互作用、(2)急性干扰和(3)血流动力学的时变反应进行了理想控制[设定值(CO为+35 ml kg(-1) min(-1),MAP为±0 mmHg)与观察到的反应之间的平均误差;CO分别为6.4、3.7和4.2 ml kg(-1) min(-1),MAP分别为1.6、1.4和2.7 mmHg(无血管扩张剂时为10.5、20.8和15.3 mmHg)]。MAPC(NN)还可以调节犬实际心力衰竭时的血流动力学。MAPC(NN)对血流动力学的稳健调节归因于其在线适应各种反应的能力以及使用神经网络的预测控制。结果证明了使用简单神经网络的MAPC(NN)应用于临床情况的可行性。
