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Machine Learning Approaches Reveal Metabolic Signatures of Incident Chronic Kidney Disease in Individuals With Prediabetes and Type 2 Diabetes.

Jialing HuangCornelia HuthMarcela CovicMartina TrollJonathan AdamSven ZukunftCornelia PrehnLi WangJana NanoMarkus F ScheererSusanne NeschenGabi KastenmüllerKarsten SuhreMichael LaxyFreimut SchliessChristian GiegerJerzy AdamskiMartin Hrabě de AngelisAnnette PetersRui Wang-Sattler
Published in: Diabetes (2020)
Early and precise identification of individuals with prediabetes and type 2 diabetes (T2D) at risk for progressing to chronic kidney disease (CKD) is essential to prevent complications of diabetes. Here, we identify and evaluate prospective metabolite biomarkers and the best set of predictors of CKD in the longitudinal, population-based Cooperative Health Research in the Region of Augsburg (KORA) cohort by targeted metabolomics and machine learning approaches. Out of 125 targeted metabolites, sphingomyelin C18:1 and phosphatidylcholine diacyl C38:0 were identified as candidate metabolite biomarkers of incident CKD specifically in hyperglycemic individuals followed during 6.5 years. Sets of predictors for incident CKD developed from 125 metabolites and 14 clinical variables showed highly stable performances in all three machine learning approaches and outperformed the currently established clinical algorithm for CKD. The two metabolites in combination with five clinical variables were identified as the best set of predictors, and their predictive performance yielded a mean area value under the receiver operating characteristic curve of 0.857. The inclusion of metabolite variables in the clinical prediction of future CKD may thus improve the risk prediction in people with prediabetes and T2D. The metabolite link with hyperglycemia-related early kidney dysfunction warrants further investigation.
Keyphrases
  • chronic kidney disease
  • machine learning
  • end stage renal disease
  • type diabetes
  • cardiovascular disease
  • ms ms
  • glycemic control
  • genome wide
  • big data
  • skeletal muscle
  • weight loss
  • adipose tissue