IEEE Trans Biomed Eng. 2022 Feb;69(2):558-568. doi: 10.1109/TBME.2021.3101589. Epub 2022 Jan 20.
Type-1 diabetes (T1D) is a disease characterized by impaired blood glucose (BG) regulation, forcing patients to multiple daily therapeutic actions, including insulin administration. T1D management could considerably benefit of accurate BG predictions and automated insulin delivery. For both tasks, the large inter- and intra-individual variability in glucose response represents a major challenge. This work investigates different techniques to learn individualized linear models of glucose response to insulin and meal, suitable for model-based prediction and control.
We focus on data-driven techniques for linear model-learning and compare the state-of-art parametric pipeline with a novel non-parametric approach based on Gaussian regression and Stable-Spline kernel. On data collected by 11 T1D individuals, the effectiveness of different models was evaluated by measuring root mean squared error (RMSE), coefficient of determination (COD), and time gain associated with BG predictors.
Among the tested approaches, the non-parametric technique results in the best prediction performance: median RMSE = 29.8 mg/dL, and median COD = 57.4%, for a prediction horizon (PH) of 60 min. With respect to the state-of-the-art parametric techniques, the non-parametric approach grants a COD improvement of about 2%, 7%, 21%, and 41% for PH = 30, 60, 90, and 120 min (paired-sample t-test p ≤ 0.001, p = 0.003, p = 0.03, and p = 0.07 respectively).
Non-parametric linear model-learning grants statistically significant improvement with respect to the state-of-art parametric approach. The higher PH, the more pronounced the improvement.
The use of a linear non-parametric model-learning approach for model-based prediction and control could bring to a more prompt, safe and effective T1D management.
1 型糖尿病(T1D)的特征是血糖(BG)调节受损,迫使患者进行多次日常治疗操作,包括胰岛素给药。T1D 的管理可以从准确的 BG 预测和自动胰岛素输送中获益良多。对于这两个任务,血糖反应的个体内和个体间的巨大变异性都是一个主要的挑战。本工作研究了不同的技术,以学习适合基于模型的预测和控制的胰岛素和餐食对个体血糖反应的个体化线性模型。
我们专注于线性模型学习的数据驱动技术,并比较了基于参数的最新技术管道与基于高斯回归和稳定样条核的新的非参数方法。在 11 名 T1D 个体收集的数据上,通过测量 BG 预测器的均方根误差(RMSE)、决定系数(COD)和与时间相关的增益,评估了不同模型的有效性。
在所测试的方法中,非参数技术的预测性能最佳:对于 60 分钟的预测时窗(PH),中位数 RMSE = 29.8mg/dL,中位数 COD = 57.4%。与最新的参数技术相比,非参数方法在 PH = 30、60、90 和 120 分钟时的 COD 提高了约 2%、7%、21%和 41%(配对样本 t 检验,p ≤ 0.001,p = 0.003,p = 0.03 和 p = 0.07)。
非参数线性模型学习与最新的参数方法相比具有统计学上的显著改善。预测时窗越高,改善越明显。
基于线性非参数模型学习的方法用于基于模型的预测和控制,可以实现更迅速、更安全和更有效的 T1D 管理。
