Advances in postmortem interval estimation: A systematic review of machine learning and metabolomics across various tissue types

Abdulkreem Abdullah AlJuhani; Rodan Mahmoud Desoky; Abdulaziz A Binshalhoub; Mohammed Jamaan Alzahrani; Mofareh Shubban Alraythi; Farouq Faisal Alzahrani

doi:10.1007/s12024-025-01026-3

Advances in postmortem interval estimation: A systematic review of machine learning and metabolomics across various tissue types

Forensic Sci Med Pathol. 2025 Sep;21(3):1428-1446. doi: 10.1007/s12024-025-01026-3. Epub 2025 Jul 24.

Authors

Abdulkreem Abdullah AlJuhani¹, Rodan Mahmoud Desoky², Abdulaziz A Binshalhoub³, Mohammed Jamaan Alzahrani⁴, Mofareh Shubban Alraythi⁵, Farouq Faisal Alzahrani⁶

Affiliations

¹ Department of Surgery King, Abdulaziz University Hospital, Riyadh, SA, Saudi Arabia. Kroomx@outlook.com.
² College of Medicine, Alfaisal University, Riyadh, Saudi Arabia.
³ Forensic Medicine Services Administration, Riyadh, Saudi Arabia.
⁴ Faculty of Medicine, King Abdulaziz University, Riyadh, Saudi Arabia.
⁵ Faculty of Medicine, Jazan University Saudi Arabia, Jizan, Saudi Arabia.
⁶ Nayef College for National Security, Riyadh, Saudi Arabia.

PMID: 40702300
DOI: 10.1007/s12024-025-01026-3

Abstract

Background: Traditional postmortem interval (PMI) estimation methods rely on observable changes such as rigor mortis, livor mortis, and algor mortis but are often affected by environmental factors. Metabolomics, combined with techniques like nuclear magnetic resonance (NMR) and mass spectrometry, improves accuracy by identifying biochemical changes postmortem. Machine learning methods such as Principal Component Analysis (PCA), Partial Least Squares (PLS), and Support Vector Machines (SVMs), enhance PMI predictions by analyzing metabolite data. This review aims to summarize advances in using machine learning for PMI estimation and identify the optimal combination of tissue samples and algorithms for accurate predictions.

Methods: We retrieved relevant articles up to September 2024 from PubMed, Scopus, Web of Science, IEEE, and Cochrane Library. Data were extracted from eligible studies by two independent reviewers. This included the number and species of subjects, tissue sample used, PMI range in the study, metabolic profiling technique, machine learning algorithms, potential PMI markers, and model performance.

Results: We compared machine learning models for PMI estimation across various tissues. Zhang et al. (2022) had the best performance with a random forest (RF) model using cardiac blood, achieving a mean absolute error (MAE) of 1.067 h by selecting key metabolites. Wu et al. (2017) followed with an orthogonal signal-corrected PLS model (R² > 0.99, MAE 1.18-2.37 h). Lu et al. (2022) achieved 93% accuracy with a multi-organ stacking model. Other promising models include Zhang et al.'s (2017) nu-SVM on pericardial fluid (RMSE = 2.38 h) and Sato et al.'s (2015) PLS model on cardiac blood (MAE = 5.73 h).

Conclusion: Cardiac blood is best for short PMIs with random forest models, while skeletal muscle and stacking models excel for longer PMIs. Future studies should refine and validate these findings as well as extend the findings to human subjects.

Keywords: AI; Blood; Eye; Machine learning; Metabolomics; Muscle; PMI; Pericardial fluid; Postmortem interval.

Publication types

Systematic Review

MeSH terms

Algorithms
Biomarkers / metabolism
Humans
Least-Squares Analysis
Machine Learning*
Metabolomics*
Muscle, Skeletal / metabolism
Myocardium / metabolism
Postmortem Changes*
Principal Component Analysis
Support Vector Machine

Substances

Biomarkers