具有运动模型的人工胰腺双激素模型预测控制设计
Design of a dual-hormone model predictive control for artificial pancreas with exercise model.
作者信息
Resalat Navid, El Youssef Joseph, Reddy Ravi, Jacobs Peter G
出版信息
Annu Int Conf IEEE Eng Med Biol Soc. 2016 Aug;2016:2270-2273. doi: 10.1109/EMBC.2016.7591182.
Abstract
The Artificial Pancreas (AP) is a new technology for helping people with type 1 diabetes to better control their glucose levels through automated delivery of insulin and optionally glucagon in response to sensed glucose levels. In a dual hormone AP, insulin and glucagon are delivered automatically to the body based on glucose sensor measurements using a control algorithm that calculates the amount of hormones to be infused. A dual-hormone MPC may deliver insulin continuously; however, it must avoid continuous delivery of glucagon because nausea can occur from too much glucagon. In this paper, we propose a novel dual-hormone (DH) switching model predictive control and compare it with a single-hormone (SH) MPC. We extended both MPCs by integrating an exercise model and compared performance with and without the exercise model included. Results were obtained on a virtual patient population undergoing a simulated exercise event using a mathematical glucoregulatory model that includes exercise. Time spent in hypoglycemia is significantly less with the DH-MPC than the SH-MPC (p=0.0022). Additionally, including the exercise model in the DH-MPC can help prevent hypoglycemia (p <; 0.001).
摘要
人工胰腺(AP)是一项新技术,可通过根据感测到的血糖水平自动输送胰岛素以及视情况输送胰高血糖素,帮助1型糖尿病患者更好地控制血糖水平。在双激素人工胰腺中,胰岛素和胰高血糖素会根据葡萄糖传感器的测量结果,使用一种计算要输注激素量的控制算法自动输送到体内。双激素模型预测控制器(MPC)可能会持续输送胰岛素;然而,它必须避免持续输送胰高血糖素,因为胰高血糖素过多可能会导致恶心。在本文中,我们提出了一种新型双激素(DH)切换模型预测控制,并将其与单激素(SH)MPC进行比较。我们通过整合运动模型对两种MPC进行了扩展,并比较了包含和不包含运动模型时的性能。使用包含运动的数学葡萄糖调节模型,在经历模拟运动事件 的虚拟患者群体上获得了结果。与单激素MPC相比,双激素MPC导致低血糖的时间显著减少(p = 0.0022)。此外,在双激素MPC中纳入运动模型有助于预防低血糖(p < 0.001)。
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