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Multi-Horizon Glucose Prediction Across Populations With Deep Domain Generalization

Taiyu Zhu, Ioannis Afentakis, Kezhi Li, Ryan Armiger, Neil Hill, Nick Oliver, Pantelis Georgiou

2024IEEE Journal of Biomedical and Health Informatics12 citationsDOIOpen Access PDF

Abstract

Real-time continuous glucose monitoring (CGM), augmented with accurate glucose prediction, offers an effective strategy for maintaining blood glucose levels within a therapeutically appropriate range. This is particularly crucial for individuals with type 1 diabetes (T1D) who require long-term self-management. However, with extensive glycemic variability, developing a prediction algorithm applicable across diverse populations remains a significant challenge. Leveraging meta-learning for domain generalization, we propose GPFormer, a Transformer-based zero-shot learning method designed for multi-horizon glucose prediction. We developed GPFormer on the REPLACE-BG dataset, comprising 226 participants with T1D, and proceeded to evaluate its performance using three external clinical datasets with CGM data. These included the OhioT1DM dataset, a publicly available dataset including 12 T1D participants, as well as two proprietary datasets. The first proprietary dataset included 22 participants, while the second contained 45 participants, encompassing a diverse group with T1D, type 2 diabetes, and those without diabetes, including patients admitted to hospitals. These four datasets include both outpatient and inpatient settings, various intervention strategies, and demographic variability, which effectively reflect real-world scenarios of CGM usage. When compared with a group of machine learning baseline methods, GPFormer consistently demonstrated superior performance and achieved the lowest root mean square error for all the evaluated datasets up to a prediction horizon of two hours. These experimental results highlight the effectiveness and generalizability of the proposed model across a variety of populations, demonstrating its substantial potential to enhance glucose management in a wide range of practical clinical settings.

Topics & Concepts

Generalizability theoryMachine learningComputer scienceArtificial intelligenceGlycemicBaseline (sea)Predictive modellingMean squared errorGeneralizationDeep learningData miningDiabetes mellitusMedicineStatisticsMathematicsEndocrinologyOceanographyMathematical analysisGeologyDiabetes Management and ResearchDiabetes and associated disordersHyperglycemia and glycemic control in critically ill and hospitalized patients