An artificial intelligence decision support system for the management of type 1 diabetes.
Nichole S TylerClara M Mosquera-LopezLeah M WilsonRobert H DodierDeborah L BraniganVirginia B GaboFlorian H GuillotWade W HiltsJoseph El YoussefJessica R CastlePeter G JacobsPublished in: Nature metabolism (2020)
Type 1 diabetes (T1D) is characterized by pancreatic beta cell dysfunction and insulin depletion. Over 40% of people with T1D manage their glucose through multiple injections of long-acting basal and short-acting bolus insulin, so-called multiple daily injections (MDI)1,2. Errors in dosing can lead to life-threatening hypoglycaemia events (<70 mg dl-1) and hyperglycaemia (>180 mg dl-1), increasing the risk of retinopathy, neuropathy, and nephropathy. Machine learning (artificial intelligence) approaches are being harnessed to incorporate decision support into many medical specialties. Here, we report an algorithm that provides weekly insulin dosage recommendations to adults with T1D using MDI therapy. We employ a unique virtual platform3 to generate over 50,000 glucose observations to train a k-nearest neighbours4 decision support system (KNN-DSS) to identify causes of hyperglycaemia or hypoglycaemia and determine necessary insulin adjustments from a set of 12 potential recommendations. The KNN-DSS algorithm achieves an overall agreement with board-certified endocrinologists of 67.9% when validated on real-world human data, and delivers safe recommendations, per endocrinologist review. A comparison of inter-physician-recommended adjustments to insulin pump therapy indicates full agreement of 41.2% among endocrinologists, which is consistent with previous measures of inter-physician agreement (41-45%)5. In silico3,6 benchmarking using a platform accepted by the United States Food and Drug Administration for evaluation of artificial pancreas technologies indicates substantial improvement in glycaemic outcomes after 12 weeks of KNN-DSS use. Our data indicate that the KNN-DSS allows for early identification of dangerous insulin regimens and may be used to improve glycaemic outcomes and prevent life-threatening complications in people with T1D.
Keyphrases
- type diabetes
- artificial intelligence
- machine learning
- big data
- glycemic control
- deep learning
- blood glucose
- primary care
- cardiovascular disease
- insulin resistance
- healthcare
- emergency department
- endothelial cells
- electronic health record
- oxidative stress
- high throughput
- mesenchymal stem cells
- cell therapy
- metabolic syndrome
- clinical practice
- single cell
- risk factors
- preterm birth
- mass spectrometry
- bone marrow
- neural network
- molecular docking
- blood pressure
- stem cells
- risk assessment
- weight loss
- data analysis