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Auteurs principaux: Khelfaoui, Issam, Wang, Wenxin, Shehata, Akram Ismael, Meskher, Hicham, El Basuini, Mohammed F, Mohamed, Abdalla M A, Abouelenein, Mohamed F, Degha, Houssem Eddine, Alhoshy, Mayada, Teiba, Islam I, Mahmoud, Omnia, Mahmoud, Seedahmed S
Format: Artículo científico
Langue:en
Publié: Frontiers in microbiology 2026
Accès en ligne:https://pubmed.ncbi.nlm.nih.gov/41960430/
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author Khelfaoui, Issam
Wang, Wenxin
Shehata, Akram Ismael
Meskher, Hicham
El Basuini, Mohammed F
Mohamed, Abdalla M A
Abouelenein, Mohamed F
Degha, Houssem Eddine
Alhoshy, Mayada
Teiba, Islam I
Mahmoud, Omnia
Mahmoud, Seedahmed S
author_facet Khelfaoui, Issam
Wang, Wenxin
Shehata, Akram Ismael
Meskher, Hicham
El Basuini, Mohammed F
Mohamed, Abdalla M A
Abouelenein, Mohamed F
Degha, Houssem Eddine
Alhoshy, Mayada
Teiba, Islam I
Mahmoud, Omnia
Mahmoud, Seedahmed S
Khelfaoui, Issam
Wang, Wenxin
Shehata, Akram Ismael
Meskher, Hicham
El Basuini, Mohammed F
Mohamed, Abdalla M A
Abouelenein, Mohamed F
Degha, Houssem Eddine
Alhoshy, Mayada
Teiba, Islam I
Mahmoud, Omnia
Mahmoud, Seedahmed S
collection PubMed - marine biology
contents STROBE-causal machine learning for the human microbiome: systematic review on methodological innovations and validation frameworks. Khelfaoui, Issam Wang, Wenxin Shehata, Akram Ismael Meskher, Hicham El Basuini, Mohammed F Mohamed, Abdalla M A Abouelenein, Mohamed F Degha, Houssem Eddine Alhoshy, Mayada Teiba, Islam I Mahmoud, Omnia Mahmoud, Seedahmed S The reproducibility crisis in causal microbiome research necessitates robust validation frameworks. Current studies often face inconsistent validation methods, limited interpretability, and a lack of standardized reporting, creating a gap in reliable causal inference. This systematic review evaluates over 60 peer-reviewed studies published between 2015 and 2024 to: (1) establish benchmarking standards leveraging synthetic data and biological plausibility assessments; (2) compare advanced causal machine learning (ML) methodologies, including Double/Debiased ML, Deep Instrumental Variables (Deep IV), and Directed Acyclic Graphs (DAGs), in their application to microbiome-host systems; and (3) propose the STROBE-CML (Strengthening the Reporting of Observational Studies in Epidemiology-Causal Machine Learning) guidelines to standardize reporting practices. We emphasize critical innovations such as federated validation pipelines and time-series causal discovery frameworks that address these gaps by facilitating scalable, privacy-preserving, and reproducible inference across heterogeneous cohorts. A decision support tool is introduced to guide researchers in selecting appropriate causal ML approaches based on data structure, research question, and computational constraints. By synthesizing methodological advances with rigorous validation paradigms, this review provides a roadmap for generating reliable, biologically interpretable, and clinically translatable causal claims in microbiome science.
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publishDate 2026
publisher Frontiers in microbiology
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spellingShingle STROBE-causal machine learning for the human microbiome: systematic review on methodological innovations and validation frameworks.
Khelfaoui, Issam
Wang, Wenxin
Shehata, Akram Ismael
Meskher, Hicham
El Basuini, Mohammed F
Mohamed, Abdalla M A
Abouelenein, Mohamed F
Degha, Houssem Eddine
Alhoshy, Mayada
Teiba, Islam I
Mahmoud, Omnia
Mahmoud, Seedahmed S
STROBE-causal machine learning for the human microbiome: systematic review on methodological innovations and validation frameworks. Khelfaoui, Issam Wang, Wenxin Shehata, Akram Ismael Meskher, Hicham El Basuini, Mohammed F Mohamed, Abdalla M A Abouelenein, Mohamed F Degha, Houssem Eddine Alhoshy, Mayada Teiba, Islam I Mahmoud, Omnia Mahmoud, Seedahmed S The reproducibility crisis in causal microbiome research necessitates robust validation frameworks. Current studies often face inconsistent validation methods, limited interpretability, and a lack of standardized reporting, creating a gap in reliable causal inference. This systematic review evaluates over 60 peer-reviewed studies published between 2015 and 2024 to: (1) establish benchmarking standards leveraging synthetic data and biological plausibility assessments; (2) compare advanced causal machine learning (ML) methodologies, including Double/Debiased ML, Deep Instrumental Variables (Deep IV), and Directed Acyclic Graphs (DAGs), in their application to microbiome-host systems; and (3) propose the STROBE-CML (Strengthening the Reporting of Observational Studies in Epidemiology-Causal Machine Learning) guidelines to standardize reporting practices. We emphasize critical innovations such as federated validation pipelines and time-series causal discovery frameworks that address these gaps by facilitating scalable, privacy-preserving, and reproducible inference across heterogeneous cohorts. A decision support tool is introduced to guide researchers in selecting appropriate causal ML approaches based on data structure, research question, and computational constraints. By synthesizing methodological advances with rigorous validation paradigms, this review provides a roadmap for generating reliable, biologically interpretable, and clinically translatable causal claims in microbiome science.
title STROBE-causal machine learning for the human microbiome: systematic review on methodological innovations and validation frameworks.
url https://pubmed.ncbi.nlm.nih.gov/41960430/