Classification of Postprandial Glycemic Status with Application to Insulin Dosing in Type 1 Diabetes—An In Silico Proof-of-Concept

Classification of Postprandial Glycemic Status with Application to Insulin Dosing in Type 1 Diabetes—An In Silico Proof-of-Concept

In the daily management of type 1 diabetes (T1D), determining the correct insulin dose to be injected at meal-time is fundamental to achieve optimal glycemic control. Wearable sensors, such as continuous glucose monitoring (CGM) devices, are instrumental to achieve this purpose. In this paper, we sh...

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Main Authors: Giacomo Cappon, Andrea Facchinetti, Giovanni Sparacino, Pantelis Georgiou, Pau Herrero
Format: Article
Language:English
Published: MDPI AG 2019-07-01
Series:Sensors
Subjects:
continuous glucose monitoring
decision support systems
machine learning
type 1 diabetes
gradient boosted trees
postprandial glycaemia
Online Access:https://www.mdpi.com/1424-8220/19/14/3168
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spelling doaj-48c3e1ac107246cc8e65cb484eef38d22020-11-25T00:22:51ZengMDPI AGSensors1424-82202019-07-011914316810.3390/s19143168s19143168Classification of Postprandial Glycemic Status with Application to Insulin Dosing in Type 1 Diabetes—An In Silico Proof-of-ConceptGiacomo Cappon0Andrea Facchinetti1Giovanni Sparacino2Pantelis Georgiou3Pau Herrero4Department of Information Engineering, University of Padova, 35131 Padova (PD), ItalyDepartment of Information Engineering, University of Padova, 35131 Padova (PD), ItalyDepartment of Information Engineering, University of Padova, 35131 Padova (PD), ItalyDepartment of Electrical and Electronical Engineering, Imperial College London, London W5 5SA, UKDepartment of Electrical and Electronical Engineering, Imperial College London, London W5 5SA, UKIn the daily management of type 1 diabetes (T1D), determining the correct insulin dose to be injected at meal-time is fundamental to achieve optimal glycemic control. Wearable sensors, such as continuous glucose monitoring (CGM) devices, are instrumental to achieve this purpose. In this paper, we show how CGM data, together with commonly recorded inputs (carbohydrate intake and bolus insulin), can be used to develop an algorithm that allows classifying, at meal-time, the post-prandial glycemic status (i.e., blood glucose concentration being too low, too high, or within target range). Such an outcome can then be used to improve the efficacy of insulin therapy by reducing or increasing the corresponding meal bolus dose. A state-of-the-art T1D simulation environment, including intraday variability and a behavioral model, was used to generate a rich in silico dataset corresponding to 100 subjects over a two-month scenario. Then, an extreme gradient-boosted tree (XGB) algorithm was employed to classify the post-prandial glycemic status. Finally, we demonstrate how the XGB algorithm outcome can be exploited to improve glycemic control in T1D through real-time adjustment of the meal insulin bolus. The proposed XGB algorithm obtained good accuracy at classifying post-prandial glycemic status (AUROC = 0.84 [0.78, 0.87]). Consequently, when used to adjust, in real-time, meal insulin boluses obtained with a bolus calculator, the proposed approach improves glycemic control when compared to the baseline bolus calculator. In particular, percentage time in target [70, 180] mg/dL was improved from 61.98 (&#177;13.89) to 67.00 (&#177;11.54; <i>p</i> &lt; 0.01) without increasing hypoglycemia.https://www.mdpi.com/1424-8220/19/14/3168continuous glucose monitoringdecision support systemsmachine learningtype 1 diabetesgradient boosted treespostprandial glycaemia
collection DOAJ
language English
format Article
sources DOAJ
author Giacomo Cappon
Andrea Facchinetti
Giovanni Sparacino
Pantelis Georgiou
Pau Herrero
spellingShingle Giacomo Cappon
Andrea Facchinetti
Giovanni Sparacino
Pantelis Georgiou
Pau Herrero
Classification of Postprandial Glycemic Status with Application to Insulin Dosing in Type 1 Diabetes—An In Silico Proof-of-Concept
Sensors
continuous glucose monitoring
decision support systems
machine learning
type 1 diabetes
gradient boosted trees
postprandial glycaemia
author_facet Giacomo Cappon
Andrea Facchinetti
Giovanni Sparacino
Pantelis Georgiou
Pau Herrero
author_sort Giacomo Cappon
title Classification of Postprandial Glycemic Status with Application to Insulin Dosing in Type 1 Diabetes—An In Silico Proof-of-Concept
title_short Classification of Postprandial Glycemic Status with Application to Insulin Dosing in Type 1 Diabetes—An In Silico Proof-of-Concept
title_full Classification of Postprandial Glycemic Status with Application to Insulin Dosing in Type 1 Diabetes—An In Silico Proof-of-Concept
title_fullStr Classification of Postprandial Glycemic Status with Application to Insulin Dosing in Type 1 Diabetes—An In Silico Proof-of-Concept
title_full_unstemmed Classification of Postprandial Glycemic Status with Application to Insulin Dosing in Type 1 Diabetes—An In Silico Proof-of-Concept
title_sort classification of postprandial glycemic status with application to insulin dosing in type 1 diabetes—an in silico proof-of-concept
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2019-07-01
description In the daily management of type 1 diabetes (T1D), determining the correct insulin dose to be injected at meal-time is fundamental to achieve optimal glycemic control. Wearable sensors, such as continuous glucose monitoring (CGM) devices, are instrumental to achieve this purpose. In this paper, we show how CGM data, together with commonly recorded inputs (carbohydrate intake and bolus insulin), can be used to develop an algorithm that allows classifying, at meal-time, the post-prandial glycemic status (i.e., blood glucose concentration being too low, too high, or within target range). Such an outcome can then be used to improve the efficacy of insulin therapy by reducing or increasing the corresponding meal bolus dose. A state-of-the-art T1D simulation environment, including intraday variability and a behavioral model, was used to generate a rich in silico dataset corresponding to 100 subjects over a two-month scenario. Then, an extreme gradient-boosted tree (XGB) algorithm was employed to classify the post-prandial glycemic status. Finally, we demonstrate how the XGB algorithm outcome can be exploited to improve glycemic control in T1D through real-time adjustment of the meal insulin bolus. The proposed XGB algorithm obtained good accuracy at classifying post-prandial glycemic status (AUROC = 0.84 [0.78, 0.87]). Consequently, when used to adjust, in real-time, meal insulin boluses obtained with a bolus calculator, the proposed approach improves glycemic control when compared to the baseline bolus calculator. In particular, percentage time in target [70, 180] mg/dL was improved from 61.98 (&#177;13.89) to 67.00 (&#177;11.54; <i>p</i> &lt; 0.01) without increasing hypoglycemia.
topic continuous glucose monitoring
decision support systems
machine learning
type 1 diabetes
gradient boosted trees
postprandial glycaemia
url https://www.mdpi.com/1424-8220/19/14/3168
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