Deep transfer learning and data augmentation improve glucose levels prediction in type 2 diabetes patients

Deep transfer learning and data augmentation improve glucose levels prediction in type 2 diabetes patients

Abstract Accurate prediction of blood glucose variations in type 2 diabetes (T2D) will facilitate better glycemic control and decrease the occurrence of hypoglycemic episodes as well as the morbidity and mortality associated with T2D, hence increasing the quality of life of patients. Owing to the co...

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Main Authors: Yixiang Deng, Lu Lu, Laura Aponte, Angeliki M. Angelidi, Vera Novak, George Em Karniadakis, Christos S. Mantzoros
Format: Article
Language:English
Published: Nature Publishing Group 2021-07-01
Series:npj Digital Medicine
Online Access:https://doi.org/10.1038/s41746-021-00480-x
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spelling doaj-880a0997af744705abe7461726f7f5482021-07-18T11:08:30ZengNature Publishing Groupnpj Digital Medicine2398-63522021-07-014111310.1038/s41746-021-00480-xDeep transfer learning and data augmentation improve glucose levels prediction in type 2 diabetes patientsYixiang Deng0Lu Lu1Laura Aponte2Angeliki M. Angelidi3Vera Novak4George Em Karniadakis5Christos S. Mantzoros6School of Engineering, Brown UniversityDepartment of Chemical and Biomolecular Engineering, University of PennsylvaniaDepartment of Medicine, Beth Israel Deaconess Medical Center, Harvard Medical SchoolDepartment of Medicine, Beth Israel Deaconess Medical Center, Harvard Medical SchoolDepartment of Medicine, Beth Israel Deaconess Medical Center, Harvard Medical SchoolSchool of Engineering, Brown UniversityDepartment of Medicine, Beth Israel Deaconess Medical Center, Harvard Medical SchoolAbstract Accurate prediction of blood glucose variations in type 2 diabetes (T2D) will facilitate better glycemic control and decrease the occurrence of hypoglycemic episodes as well as the morbidity and mortality associated with T2D, hence increasing the quality of life of patients. Owing to the complexity of the blood glucose dynamics, it is difficult to design accurate predictive models in every circumstance, i.e., hypo/normo/hyperglycemic events. We developed deep-learning methods to predict patient-specific blood glucose during various time horizons in the immediate future using patient-specific every 30-min long glucose measurements by the continuous glucose monitoring (CGM) to predict future glucose levels in 5 min to 1 h. In general, the major challenges to address are (1) the dataset of each patient is often too small to train a patient-specific deep-learning model, and (2) the dataset is usually highly imbalanced given that hypo- and hyperglycemic episodes are usually much less common than normoglycemia. We tackle these two challenges using transfer learning and data augmentation, respectively. We systematically examined three neural network architectures, different loss functions, four transfer-learning strategies, and four data augmentation techniques, including mixup and generative models. Taken together, utilizing these methodologies we achieved over 95% prediction accuracy and 90% sensitivity for a time period within the clinically useful 1 h prediction horizon that would allow a patient to react and correct either hypoglycemia and/or hyperglycemia. We have also demonstrated that the same network architecture and transfer-learning methods perform well for the type 1 diabetes OhioT1DM public dataset.https://doi.org/10.1038/s41746-021-00480-x
collection DOAJ
language English
format Article
sources DOAJ
author Yixiang Deng
Lu Lu
Laura Aponte
Angeliki M. Angelidi
Vera Novak
George Em Karniadakis
Christos S. Mantzoros
spellingShingle Yixiang Deng
Lu Lu
Laura Aponte
Angeliki M. Angelidi
Vera Novak
George Em Karniadakis
Christos S. Mantzoros
Deep transfer learning and data augmentation improve glucose levels prediction in type 2 diabetes patients
npj Digital Medicine
author_facet Yixiang Deng
Lu Lu
Laura Aponte
Angeliki M. Angelidi
Vera Novak
George Em Karniadakis
Christos S. Mantzoros
author_sort Yixiang Deng
title Deep transfer learning and data augmentation improve glucose levels prediction in type 2 diabetes patients
title_short Deep transfer learning and data augmentation improve glucose levels prediction in type 2 diabetes patients
title_full Deep transfer learning and data augmentation improve glucose levels prediction in type 2 diabetes patients
title_fullStr Deep transfer learning and data augmentation improve glucose levels prediction in type 2 diabetes patients
title_full_unstemmed Deep transfer learning and data augmentation improve glucose levels prediction in type 2 diabetes patients
title_sort deep transfer learning and data augmentation improve glucose levels prediction in type 2 diabetes patients
publisher Nature Publishing Group
series npj Digital Medicine
issn 2398-6352
publishDate 2021-07-01
description Abstract Accurate prediction of blood glucose variations in type 2 diabetes (T2D) will facilitate better glycemic control and decrease the occurrence of hypoglycemic episodes as well as the morbidity and mortality associated with T2D, hence increasing the quality of life of patients. Owing to the complexity of the blood glucose dynamics, it is difficult to design accurate predictive models in every circumstance, i.e., hypo/normo/hyperglycemic events. We developed deep-learning methods to predict patient-specific blood glucose during various time horizons in the immediate future using patient-specific every 30-min long glucose measurements by the continuous glucose monitoring (CGM) to predict future glucose levels in 5 min to 1 h. In general, the major challenges to address are (1) the dataset of each patient is often too small to train a patient-specific deep-learning model, and (2) the dataset is usually highly imbalanced given that hypo- and hyperglycemic episodes are usually much less common than normoglycemia. We tackle these two challenges using transfer learning and data augmentation, respectively. We systematically examined three neural network architectures, different loss functions, four transfer-learning strategies, and four data augmentation techniques, including mixup and generative models. Taken together, utilizing these methodologies we achieved over 95% prediction accuracy and 90% sensitivity for a time period within the clinically useful 1 h prediction horizon that would allow a patient to react and correct either hypoglycemia and/or hyperglycemia. We have also demonstrated that the same network architecture and transfer-learning methods perform well for the type 1 diabetes OhioT1DM public dataset.
url https://doi.org/10.1038/s41746-021-00480-x
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