Myo-Guide: A Machine Learning-Based Web Application for Neuromuscular Disease Diagnosis With MRI

Jose Verdu-Diaz; Carla Bolano-Díaz; Alejandro Gonzalez-Chamorro; Sam Fitzsimmons; Jodi Warman-Chardon; Goknur Selen Kocak; Debora Mucida-Alvim; Ian C Smith; John Vissing; Nanna Scharff Poulsen; Sushan Luo; Cristina Domínguez-González; Laura Bermejo-Guerrero; David Gomez-Andres; Javier Sotoca; Anna Pichiecchio; Silvia Nicolosi; Mauro Monforte; Claudia Brogna; Eugenio Mercuri; Jorge Alfredo Bevilacqua; Jorge Díaz-Jara; Benjamín Pizarro-Galleguillos; Peter Krkoska; Jorge Alonso-Pérez; Montse Olivé; Erik H Niks; Hermien E Kan; James Lilleker; Mark Roberts; Bianca Buchignani; Jinhong Shin; Florence Esselin; Emmanuelle Le Bars; Anne Marie Childs; Edoardo Malfatti; Anna Sarkozy; Luke Perry; Sniya Sudhakar; Edmar Zanoteli; Filipe Tupinamba Di Pace; Emma Matthews; Shahram Attarian; David Bendahan; Matteo Garibaldi; Laura Fionda; Alicia Alonso-Jiménez; Robert Carlier; Ali Asghar Okhovat; Shahriar Nafissi; Myo‐Guide Consortium

doi:10.1002/jcsm.13815

Myo-Guide: A Machine Learning-Based Web Application for Neuromuscular Disease Diagnosis With MRI

Jose Verdu-Diaz, Carla Bolano-Díaz, Alejandro Gonzalez-Chamorro, Sam Fitzsimmons, Jodi Warman-Chardon, Goknur Selen Kocak, Debora Mucida-Alvim, Ian C Smith, John Vissing, Nanna Scharff Poulsen, Sushan Luo, Cristina Domínguez-González, Laura Bermejo-Guerrero, David Gomez-Andres, Javier Sotoca, Anna Pichiecchio, Silvia Nicolosi, Mauro Monforte, Claudia Brogna, Eugenio MercuriJorge Alfredo Bevilacqua, Jorge Díaz-Jara, Benjamín Pizarro-Galleguillos, Peter Krkoska, Jorge Alonso-Pérez, Montse Olivé, Erik H Niks, Hermien E Kan, James Lilleker, Mark Roberts, Bianca Buchignani, Jinhong Shin, Florence Esselin, Emmanuelle Le Bars, Anne Marie Childs, Edoardo Malfatti, Anna Sarkozy, Luke Perry, Sniya Sudhakar, Edmar Zanoteli, Filipe Tupinamba Di Pace, Emma Matthews, Shahram Attarian, David Bendahan, Matteo Garibaldi, Laura Fionda, Alicia Alonso-Jiménez, Robert Carlier, Ali Asghar Okhovat, Shahriar Nafissi, Myo‐Guide Consortium

Department of Neurology

5 Citations (Scopus)

Abstract

BACKGROUND: Neuromuscular diseases (NMDs) are rare disorders characterized by progressive muscle fibre loss, leading to replacement by fibrotic and fatty tissue, muscle weakness and disability. Early diagnosis is critical for therapeutic decisions, care planning and genetic counselling. Muscle magnetic resonance imaging (MRI) has emerged as a valuable diagnostic tool by identifying characteristic patterns of muscle involvement. However, the increasing complexity of these patterns complicates their interpretation, limiting their clinical utility. Additionally, multi-study data aggregation introduces heterogeneity challenges. This study presents a novel multi-study harmonization pipeline for muscle MRI and an AI-driven diagnostic tool to assist clinicians in identifying disease-specific muscle involvement patterns.

METHODS: We developed a preprocessing pipeline to standardize MRI fat content across datasets, minimizing source bias. An ensemble of XGBoost models was trained to classify patients based on intramuscular fat replacement, age at MRI and sex. The SHapley Additive exPlanations (SHAP) framework was adapted to analyse model predictions and identify disease-specific muscle involvement patterns. To address class imbalance, training and evaluation were conducted using class-balanced metrics. The model's performance was compared against four expert clinicians using 14 previously unseen MRI scans.

RESULTS: Using our harmonization approach, we curated a dataset of 2961 MRI samples from genetically confirmed cases of 20 paediatric and adult NMDs. The model achieved a balanced accuracy of 64.8% ± 3.4%, with a weighted top-3 accuracy of 84.7% ± 1.8% and top-5 accuracy of 90.2% ± 2.4%. It also identified key features relevant for differential diagnosis, aiding clinical decision-making. Compared to four expert clinicians, the model obtained the highest top-3 accuracy (75.0% ± 4.8%). The diagnostic tool has been implemented as a free web platform, providing global access to the medical community.

CONCLUSIONS: The application of AI in muscle MRI for NMD diagnosis remains underexplored due to data scarcity. This study introduces a framework for dataset harmonization, enabling advanced computational techniques. Our findings demonstrate the potential of AI-based approaches to enhance differential diagnosis by identifying disease-specific muscle involvement patterns. The developed tool surpasses expert performance in diagnostic ranking and is accessible to clinicians worldwide via the Myo-Guide online platform.

Original language	English
Article number	e13815
Journal	Journal of Cachexia, Sarcopenia and Muscle
Volume	16
Issue number	3
ISSN	2190-5991
DOIs	https://doi.org/10.1002/jcsm.13815
Publication status	Published - Jun 2025

Keywords

Humans
Magnetic Resonance Imaging/methods
Neuromuscular Diseases/diagnosis
Machine Learning
Male
Female
Internet
Adult
Middle Aged
differential diagnosis
MRI
neuromuscular diseases
machine learning
artificial intelligence

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Verdu-Diaz, J., Bolano-Díaz, C., Gonzalez-Chamorro, A., Fitzsimmons, S., Warman-Chardon, J., Kocak, G. S., Mucida-Alvim, D., Smith, I. C., Vissing, J., Poulsen, N. S., Luo, S., Domínguez-González, C., Bermejo-Guerrero, L., Gomez-Andres, D., Sotoca, J., Pichiecchio, A., Nicolosi, S., Monforte, M., Brogna, C., ... Myo‐Guide Consortium (2025). Myo-Guide: A Machine Learning-Based Web Application for Neuromuscular Disease Diagnosis With MRI. Journal of Cachexia, Sarcopenia and Muscle, 16(3), Article e13815. https://doi.org/10.1002/jcsm.13815

Verdu-Diaz, J, Bolano-Díaz, C, Gonzalez-Chamorro, A, Fitzsimmons, S, Warman-Chardon, J, Kocak, GS, Mucida-Alvim, D, Smith, IC, Vissing, J , Poulsen, NS, Luo, S, Domínguez-González, C, Bermejo-Guerrero, L, Gomez-Andres, D, Sotoca, J, Pichiecchio, A, Nicolosi, S, Monforte, M, Brogna, C, Mercuri, E, Bevilacqua, JA, Díaz-Jara, J, Pizarro-Galleguillos, B, Krkoska, P, Alonso-Pérez, J, Olivé, M, Niks, EH, Kan, HE, Lilleker, J, Roberts, M, Buchignani, B, Shin, J, Esselin, F, Le Bars, E, Childs, AM, Malfatti, E, Sarkozy, A, Perry, L, Sudhakar, S, Zanoteli, E, Di Pace, FT, Matthews, E, Attarian, S, Bendahan, D, Garibaldi, M, Fionda, L, Alonso-Jiménez, A, Carlier, R, Okhovat, AA, Nafissi, S & Myo‐Guide Consortium 2025, 'Myo-Guide: A Machine Learning-Based Web Application for Neuromuscular Disease Diagnosis With MRI', Journal of Cachexia, Sarcopenia and Muscle, vol. 16, no. 3, e13815. https://doi.org/10.1002/jcsm.13815

@article{b1b120d980ef42f4bbc158d02513d643,

title = "Myo-Guide: A Machine Learning-Based Web Application for Neuromuscular Disease Diagnosis With MRI",

abstract = "BACKGROUND: Neuromuscular diseases (NMDs) are rare disorders characterized by progressive muscle fibre loss, leading to replacement by fibrotic and fatty tissue, muscle weakness and disability. Early diagnosis is critical for therapeutic decisions, care planning and genetic counselling. Muscle magnetic resonance imaging (MRI) has emerged as a valuable diagnostic tool by identifying characteristic patterns of muscle involvement. However, the increasing complexity of these patterns complicates their interpretation, limiting their clinical utility. Additionally, multi-study data aggregation introduces heterogeneity challenges. This study presents a novel multi-study harmonization pipeline for muscle MRI and an AI-driven diagnostic tool to assist clinicians in identifying disease-specific muscle involvement patterns.METHODS: We developed a preprocessing pipeline to standardize MRI fat content across datasets, minimizing source bias. An ensemble of XGBoost models was trained to classify patients based on intramuscular fat replacement, age at MRI and sex. The SHapley Additive exPlanations (SHAP) framework was adapted to analyse model predictions and identify disease-specific muscle involvement patterns. To address class imbalance, training and evaluation were conducted using class-balanced metrics. The model's performance was compared against four expert clinicians using 14 previously unseen MRI scans.RESULTS: Using our harmonization approach, we curated a dataset of 2961 MRI samples from genetically confirmed cases of 20 paediatric and adult NMDs. The model achieved a balanced accuracy of 64.8\% ± 3.4\%, with a weighted top-3 accuracy of 84.7\% ± 1.8\% and top-5 accuracy of 90.2\% ± 2.4\%. It also identified key features relevant for differential diagnosis, aiding clinical decision-making. Compared to four expert clinicians, the model obtained the highest top-3 accuracy (75.0\% ± 4.8\%). The diagnostic tool has been implemented as a free web platform, providing global access to the medical community.CONCLUSIONS: The application of AI in muscle MRI for NMD diagnosis remains underexplored due to data scarcity. This study introduces a framework for dataset harmonization, enabling advanced computational techniques. Our findings demonstrate the potential of AI-based approaches to enhance differential diagnosis by identifying disease-specific muscle involvement patterns. The developed tool surpasses expert performance in diagnostic ranking and is accessible to clinicians worldwide via the Myo-Guide online platform.",

keywords = "Humans, Magnetic Resonance Imaging/methods, Neuromuscular Diseases/diagnosis, Machine Learning, Male, Female, Internet, Adult, Middle Aged, differential diagnosis, MRI, neuromuscular diseases, machine learning, artificial intelligence",

author = "Jose Verdu-Diaz and Carla Bolano-D{\'i}az and Alejandro Gonzalez-Chamorro and Sam Fitzsimmons and Jodi Warman-Chardon and Kocak, \{Goknur Selen\} and Debora Mucida-Alvim and Smith, \{Ian C\} and John Vissing and Poulsen, \{Nanna Scharff\} and Sushan Luo and Cristina Dom{\'i}nguez-Gonz{\'a}lez and Laura Bermejo-Guerrero and David Gomez-Andres and Javier Sotoca and Anna Pichiecchio and Silvia Nicolosi and Mauro Monforte and Claudia Brogna and Eugenio Mercuri and Bevilacqua, \{Jorge Alfredo\} and Jorge D{\'i}az-Jara and Benjam{\'i}n Pizarro-Galleguillos and Peter Krkoska and Jorge Alonso-P{\'e}rez and Montse Oliv{\'e} and Niks, \{Erik H\} and Kan, \{Hermien E\} and James Lilleker and Mark Roberts and Bianca Buchignani and Jinhong Shin and Florence Esselin and \{Le Bars\}, Emmanuelle and Childs, \{Anne Marie\} and Edoardo Malfatti and Anna Sarkozy and Luke Perry and Sniya Sudhakar and Edmar Zanoteli and \{Di Pace\}, \{Filipe Tupinamba\} and Emma Matthews and Shahram Attarian and David Bendahan and Matteo Garibaldi and Laura Fionda and Alicia Alonso-Jim{\'e}nez and Robert Carlier and Okhovat, \{Ali Asghar\} and Shahriar Nafissi and \{Myo‐Guide Consortium\}",

note = "{\textcopyright} 2025 The Author(s). Journal of Cachexia, Sarcopenia and Muscle published by Wiley Periodicals LLC.",

year = "2025",

month = jun,

doi = "10.1002/jcsm.13815",

language = "English",

volume = "16",

journal = "Journal of Cachexia, Sarcopenia and Muscle",

issn = "2190-5991",

publisher = "Wiley-Blackwell",

number = "3",

}

TY - JOUR

T1 - Myo-Guide

T2 - A Machine Learning-Based Web Application for Neuromuscular Disease Diagnosis With MRI

AU - Verdu-Diaz, Jose

AU - Bolano-Díaz, Carla

AU - Gonzalez-Chamorro, Alejandro

AU - Fitzsimmons, Sam

AU - Warman-Chardon, Jodi

AU - Kocak, Goknur Selen

AU - Mucida-Alvim, Debora

AU - Smith, Ian C

AU - Vissing, John

AU - Poulsen, Nanna Scharff

AU - Luo, Sushan

AU - Domínguez-González, Cristina

AU - Bermejo-Guerrero, Laura

AU - Gomez-Andres, David

AU - Sotoca, Javier

AU - Pichiecchio, Anna

AU - Nicolosi, Silvia

AU - Monforte, Mauro

AU - Brogna, Claudia

AU - Mercuri, Eugenio

AU - Bevilacqua, Jorge Alfredo

AU - Díaz-Jara, Jorge

AU - Pizarro-Galleguillos, Benjamín

AU - Krkoska, Peter

AU - Alonso-Pérez, Jorge

AU - Olivé, Montse

AU - Niks, Erik H

AU - Kan, Hermien E

AU - Lilleker, James

AU - Roberts, Mark

AU - Buchignani, Bianca

AU - Shin, Jinhong

AU - Esselin, Florence

AU - Le Bars, Emmanuelle

AU - Childs, Anne Marie

AU - Malfatti, Edoardo

AU - Sarkozy, Anna

AU - Perry, Luke

AU - Sudhakar, Sniya

AU - Zanoteli, Edmar

AU - Di Pace, Filipe Tupinamba

AU - Matthews, Emma

AU - Attarian, Shahram

AU - Bendahan, David

AU - Garibaldi, Matteo

AU - Fionda, Laura

AU - Alonso-Jiménez, Alicia

AU - Carlier, Robert

AU - Okhovat, Ali Asghar

AU - Nafissi, Shahriar

AU - Myo‐Guide Consortium

PY - 2025/6

Y1 - 2025/6

N2 - BACKGROUND: Neuromuscular diseases (NMDs) are rare disorders characterized by progressive muscle fibre loss, leading to replacement by fibrotic and fatty tissue, muscle weakness and disability. Early diagnosis is critical for therapeutic decisions, care planning and genetic counselling. Muscle magnetic resonance imaging (MRI) has emerged as a valuable diagnostic tool by identifying characteristic patterns of muscle involvement. However, the increasing complexity of these patterns complicates their interpretation, limiting their clinical utility. Additionally, multi-study data aggregation introduces heterogeneity challenges. This study presents a novel multi-study harmonization pipeline for muscle MRI and an AI-driven diagnostic tool to assist clinicians in identifying disease-specific muscle involvement patterns.METHODS: We developed a preprocessing pipeline to standardize MRI fat content across datasets, minimizing source bias. An ensemble of XGBoost models was trained to classify patients based on intramuscular fat replacement, age at MRI and sex. The SHapley Additive exPlanations (SHAP) framework was adapted to analyse model predictions and identify disease-specific muscle involvement patterns. To address class imbalance, training and evaluation were conducted using class-balanced metrics. The model's performance was compared against four expert clinicians using 14 previously unseen MRI scans.RESULTS: Using our harmonization approach, we curated a dataset of 2961 MRI samples from genetically confirmed cases of 20 paediatric and adult NMDs. The model achieved a balanced accuracy of 64.8% ± 3.4%, with a weighted top-3 accuracy of 84.7% ± 1.8% and top-5 accuracy of 90.2% ± 2.4%. It also identified key features relevant for differential diagnosis, aiding clinical decision-making. Compared to four expert clinicians, the model obtained the highest top-3 accuracy (75.0% ± 4.8%). The diagnostic tool has been implemented as a free web platform, providing global access to the medical community.CONCLUSIONS: The application of AI in muscle MRI for NMD diagnosis remains underexplored due to data scarcity. This study introduces a framework for dataset harmonization, enabling advanced computational techniques. Our findings demonstrate the potential of AI-based approaches to enhance differential diagnosis by identifying disease-specific muscle involvement patterns. The developed tool surpasses expert performance in diagnostic ranking and is accessible to clinicians worldwide via the Myo-Guide online platform.

AB - BACKGROUND: Neuromuscular diseases (NMDs) are rare disorders characterized by progressive muscle fibre loss, leading to replacement by fibrotic and fatty tissue, muscle weakness and disability. Early diagnosis is critical for therapeutic decisions, care planning and genetic counselling. Muscle magnetic resonance imaging (MRI) has emerged as a valuable diagnostic tool by identifying characteristic patterns of muscle involvement. However, the increasing complexity of these patterns complicates their interpretation, limiting their clinical utility. Additionally, multi-study data aggregation introduces heterogeneity challenges. This study presents a novel multi-study harmonization pipeline for muscle MRI and an AI-driven diagnostic tool to assist clinicians in identifying disease-specific muscle involvement patterns.METHODS: We developed a preprocessing pipeline to standardize MRI fat content across datasets, minimizing source bias. An ensemble of XGBoost models was trained to classify patients based on intramuscular fat replacement, age at MRI and sex. The SHapley Additive exPlanations (SHAP) framework was adapted to analyse model predictions and identify disease-specific muscle involvement patterns. To address class imbalance, training and evaluation were conducted using class-balanced metrics. The model's performance was compared against four expert clinicians using 14 previously unseen MRI scans.RESULTS: Using our harmonization approach, we curated a dataset of 2961 MRI samples from genetically confirmed cases of 20 paediatric and adult NMDs. The model achieved a balanced accuracy of 64.8% ± 3.4%, with a weighted top-3 accuracy of 84.7% ± 1.8% and top-5 accuracy of 90.2% ± 2.4%. It also identified key features relevant for differential diagnosis, aiding clinical decision-making. Compared to four expert clinicians, the model obtained the highest top-3 accuracy (75.0% ± 4.8%). The diagnostic tool has been implemented as a free web platform, providing global access to the medical community.CONCLUSIONS: The application of AI in muscle MRI for NMD diagnosis remains underexplored due to data scarcity. This study introduces a framework for dataset harmonization, enabling advanced computational techniques. Our findings demonstrate the potential of AI-based approaches to enhance differential diagnosis by identifying disease-specific muscle involvement patterns. The developed tool surpasses expert performance in diagnostic ranking and is accessible to clinicians worldwide via the Myo-Guide online platform.

KW - Humans

KW - Magnetic Resonance Imaging/methods

KW - Neuromuscular Diseases/diagnosis

KW - Machine Learning

KW - Male

KW - Female

KW - Internet

KW - Adult

KW - Middle Aged

KW - differential diagnosis

KW - MRI

KW - neuromuscular diseases

KW - machine learning

KW - artificial intelligence

UR - https://www.scopus.com/pages/publications/105003684401

U2 - 10.1002/jcsm.13815

DO - 10.1002/jcsm.13815

M3 - Journal article

C2 - 40275674

SN - 2190-5991

VL - 16

JO - Journal of Cachexia, Sarcopenia and Muscle

JF - Journal of Cachexia, Sarcopenia and Muscle

IS - 3

M1 - e13815

ER -

Myo-Guide: A Machine Learning-Based Web Application for Neuromuscular Disease Diagnosis With MRI

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