Abstract
Blood glucose (BG) prediction is an effective approach to avoid hyper- and hypoglycemia, and achieve intelligent glucose management for patients with type 1 or serious type 2 diabetes. Recent studies have tended to adopt deep learning networks to obtain improved prediction models and more accurate prediction results, which have often required significant quantities of historical continuous glucose-monitoring (CGM) data. However, for new patients with limited historical dataset, it becomes difficult to establish an acceptable deep learning network for glucose prediction. Consequently, the goal of this study was to design a novel prediction framework with instance-based and network-based deep transfer learning for cross-subject glucose prediction based on segmented CGM time series. Taking the effects of biodiversity into consideration, dynamic time warping (DTW) was applied to determine the proper source domain dataset that shared the greatest degree of similarity for new subjects. After that, a network-based deep transfer learning method was designed with cross-domain dataset to obtain a personalized model combined with improved generalization capability. In a case study, the clinical dataset demonstrated that, with additional segmented dataset from other subjects, the proposed deep transfer learning framework achieved more accurate glucose predictions for new subjects with type 2 diabetes.
Highlights
Diabetes mellitus (DM) is a chronic metabolic disease, which causes a series of complications and seriously affects the patient’s health and daily life [1]
Deep transfer learning based on segmented blood glucose dataset
This study proposed a deep transfer learning framework to establish a personalized deep learning model for new patients with insufficient historical data
Summary
Diabetes mellitus (DM) is a chronic metabolic disease, which causes a series of complications and seriously affects the patient’s health and daily life [1]. It is necessary that they maintain their blood glucose concentration (BGC) within a target range (e.g., 70–180 mg/ dL) [2]. Continuous glucose-monitoring (CGM) systems [3,4,5] have been widely used in diabetes management to provide accurate and frequent dynamic glucose records in the form of time series data. By analyzing these data, deeper insight into glucose fluctuations could. Accurate glucose prediction is vital for the early and proactive regulation of blood glucose before it drifts to undesirable levels. Numerous approaches, based on physical models or data-driven empirical models, have been proposed to predict glucose levels [6,7,8,9,10,11,12,13]
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