Application of machine learning tools and integrated OMICS for screening and diagnosis of inborn errors of metabolism

Ganni Usha Rani; Srilatha Kadali; Banka Kurma Reddy; Dudekula Shaheena; Shaik Mohammad Naushad

doi:10.1007/s11306-023-02013-x

Application of machine learning tools and integrated OMICS for screening and diagnosis of inborn errors of metabolism

Metabolomics. 2023 May 3;19(5):49. doi: 10.1007/s11306-023-02013-x.

Authors

Ganni Usha Rani¹, Srilatha Kadali¹, Banka Kurma Reddy¹, Dudekula Shaheena¹, Shaik Mohammad Naushad²

Affiliations

¹ Department of Biochemical Genetics, YODA Lifeline Diagnostics Pvt. Ltd, Ameerpet, Hyderabad, 500016, India.
² Department of Biochemical Genetics, YODA Lifeline Diagnostics Pvt. Ltd, Ameerpet, Hyderabad, 500016, India. naushadsm@gmail.com.

PMID: 37131043
DOI: 10.1007/s11306-023-02013-x

Abstract

Introduction: Tandem mass spectrometry (TMS) has emerged an important screening tool for various metabolic disorders in newborns. However, there is inherent risk of false positive outcomes. Objective To establish analyte-specific cutoffs in TMS by integrating metabolomics and genomics data to avoid false positivity and false negativity and improve its clinical utility.

Methods: TMS was performed on 572 healthy and 3000 referred newborns. Urine organic acid analysis identified 23 types of inborn errors in 99 referred newborns. Whole exome sequencing was performed in 30 positive cases. The impact of physiological changes such as age, gender, and birthweight on various analytes was explored in healthy newborns. Machine learning tools were used to integrate demographic data with metabolomics and genomics data to establish disease-specific cut-offs; identify primary and secondary markers; build classification and regression trees (CART) for better differential diagnosis; for pathway modeling.

Results: This integration helped in differentiating B12 deficiency from methylmalonic acidemia (MMA) and propionic acidemia (Phi coefficient=0.93); differentiating transient tyrosinemia from tyrosinemia type 1 (Phi coefficient=1.00); getting clues about the possible molecular defect in MMA to initiate appropriate intervention (Phi coefficient=1.00); to link pathogenicity scores with metabolomics profile in tyrosinemia (r2=0.92). CART model helped in establishing differential diagnosis of urea cycle disorders (Phi coefficient=1.00).

Conclusion: Calibrated cut-offs of different analytes in TMS and machine learning-based establishment of disease-specific thresholds of these markers through integrated OMICS have helped in improved differential diagnosis with significant reduction of the false positivity and false negativity rates.

Keywords: Cut-off values; Inborn errors of metabolism; Integrated OMICS; Machine learning; Newborn screening; Tandem mass spectrometry.

MeSH terms

Humans
Infant, Newborn
Machine Learning
Metabolomics
Neonatal Screening / methods
Propionic Acidemia*
Tyrosinemias*

Supplementary concepts

Methylmalonic acidemia