2025Activity​​​‌ reportProject-TeamOPIS

4.1.1 Robust few-shot learning​​

Participants:Nora Ouzir and​​​‌ Jean-Christophe Pesquet

We aim‌ to advance the frontiers‌​‌ of few-shot learning by​​ integrating the adaptability of​​​‌ few-shot frameworks with the‌ rigour of classical robust‌​‌ statistical methods. By systematically​​ investigating how quality, volume,​​​‌ and diversity of training‌ data shape model performance,‌​‌ the research seeks to​​ overcome a fundamental bottleneck​​​‌ in AI-driven healthcare: the‌ scarcity of high-quality annotated‌​‌ data. Beyond advancing methodological​​ understanding, the research aspires​​​‌ to transform clinical practice‌ by enabling accurate and‌​‌ reliable AI diagnostics with​​ just minimal labelled data,​​​‌ informing data-efficient strategies for‌ large-scale medical imaging, and‌​‌ ultimately accelerating the adoption​​ of AI technologies to​​​‌ improve patient outcomes across‌ diverse healthcare systems.

4.1.2‌​‌ Design of robust neural​​ networks in safety critical​​​‌ industrial domains

Participants:‌ Jean-Christophe Pesquet , Emilie‌​‌ Chouzenoux

One of the​​ main challenges faced today​​​‌ by companies like Thales‌ or Schneider Electric designing‌​‌ advanced industrial systems, is​​ to ensure the safety​​​‌ of new generations of‌ products based on the‌​‌ use of neural networks.​​ Since 2013, neural networks​​​‌ have been shown to‌ be sensitive to adversarial‌​‌ perturbations. Deep neural networks​​ can thus be fooled,​​​‌ in an intentional (security‌ issue) or in undeliberate‌​‌ manner (safety issue), which​​ raises a major robustness​​​‌ concern for safety-critical systems‌ which need to be‌​‌ certified by an independent​​ certification authority prior to​​​‌ any entry into production/operation.‌ Tech- niques based on‌​‌ mathematical proofs of robustness​​ are generally preferred by​​​‌ industrial safety experts since‌ they enable a safe-by-design‌​‌ approach that is more​​ efficient than a robustness​​​‌ verification activity done a‌ posteriori with a necessarily‌​‌ bounded effort. Among the​​ possible mathematical approaches, we​​​‌ focus on those relying‌ upon the analysis of‌​‌ the Lipschitz properties of​​​‌ neural networks 9.​ Such properties play a​‌ fundamental role in the​​ understanding of the internal​​​‌ mechanisms governing these complex​ nonlinear systems. Besides, they​‌ make few assumptions on​​ the type of non-linearities​​​‌ used and are thus​ valid for a wide​‌ range of networks.

4.1.3​​ Certification of segmentation networks​​​‌

Participants: Othmane Laousy​ , Maria Vakalopoulou (Collaboration:​‌ G. Chassagnon and M.-P.​​ Revel, Paris Cité University​​​‌ ; N. Paragios, Therapanacea​ ; A. Araujo, S.​‌ Garg and F. Khorram,​​ New York University)

The​​​‌ robustness of image segmentation​ has been an important​‌ research topic in the​​ past few years as​​​‌ segmentation models have reached​ production-level accuracy. However, like​‌ classification models, segmentation models​​ can be vulnerable to​​​‌ adversarial perturbations, which hinders​ their use in critical-decision​‌ systems like healthcare or​​ autonomous driving. Recently, randomized​​​‌ smoothing has been proposed​ to certify segmentation predictions​‌ by adding Gaussian noise​​ to the input to​​​‌ obtain theoretical guarantees. However,​ this method exhibits a​‌ trade-off between the amount​​ of added noise and​​​‌ the level of certification​ achieved. In this topic,​‌ we address the problem​​ of certifying segmentation prediction​​​‌ using a combination of​ randomized smoothing and diffusion​‌ models. We challenge our​​ methods in both general​​​‌ computer vision and medical​ imaging dataset.

4.2.1 Realtime flow estimation​​​‌ for interventional doppler ultrafast​ ultrasound

Participants: Nora Ouzir​‌ , Jean-Christophe Pesquet (Collaboration:​​ IRIT laboratory)

Assessing blood​​​‌ flow and vascular structures​ is crucial for treating​‌ various conditions, including brain​​ tumours and cardiovascular disorders.​​​‌ During surgical procedures, the​ successful removal of a​‌ tumour relies on accurately​​ defining the boundary between​​​‌ the tumour and the​ surrounding vital brain tissues.​‌ Traditional methods for separating​​ blood flow from tissues​​​‌ typically employ filtering techniques,​ often utilizing SVD. More​‌ recent approaches, like DRPCA,​​ tackle an inverse problem​​​‌ that incorporates blood sparsity​ along with the low-rank​‌ structure of tissues. In​​ our recent work 24​​​‌, we expanded this​ method to account for​‌ tissue motion, developing an​​ algorithm that jointly estimates​​​‌ blood flow, tissues, and​ their movements. This advancement​‌ results in more accurate​​ blood flow estimations and​​​‌ significantly reduces sensitivity to​ motion. Currently, we are​‌ considering several challenges hindering​​ the clinical applicability of​​​‌ 24, including slow​ execution.

4.2.2 Imaging radiomics​‌ and pathomics to assess​​ response to treatment

4.2.3 Analysis of​​ histopathology images for cancer​​​‌ treatment

Participants: Ségolène‌ Martin , Nora Ouzir‌​‌ , Jean-Christophe Pesquet ,​​ Aymen Sardroui (Collaboration: A.​​​‌ Laurent-Bellue, C. Guettier: APHP,‌ Hôpital du Kremlin-Bicêtre ;‌​‌ A. Beaufrère, K. Mondet,​​ V. Paradis, APHP, Hôpital​​​‌ Beaujon)

The core focus‌ of our research revolves‌​‌ around scrutinizing cancer through​​ the utilization of digital​​​‌ slide images resulting from‌ biopsies or surgical resection.‌​‌ Our exploration stands at​​ the intersection of cutting-edge​​​‌ AI technology and its‌ invaluable potential for advancing‌​‌ precision medicine, and more​​ particularly liver cancer (hepatocellular​​​‌ carcinoma and intrahepatic cholangiocarcinoma)‌ diagnosis and treatment. The‌​‌ challenges to be solved​​ are related to the​​​‌ limited number of available‌ annotated data and the‌​‌ large-size of whole slide​​ images (WSIs).

4.2.4 Vision,​​​‌ machine learning and precision‌ medicine

Participants:Younes Belkouchi‌​‌ , Loïc Le Bescond​​ , Hugues Talbot (Collaboration:​​​‌ N. Lassau, Institut Gustave‌ Roussy)

In March 2020,‌​‌ the PRISM institute of​​ Gustave-Roussy was launched. The​​​‌ aim of this project,‌ funded for 5 years,‌​‌ is to develop targeted​​ treatments that are more​​​‌ likely to work on‌ specific patients.

The mission‌​‌ of this “second-generation” precision​​ medicine centre will be​​​‌ to model cancer on‌ an individual scale by‌​‌ creating numerical avatars of​​ tumours. The aim is​​​‌ to identify patients with‌ the most aggressive cancers‌​‌ very early in the​​ disease, without waiting for​​​‌ relapses, in order to‌ offer them the most‌​‌ appropriate treatment from the​​ start of treatment, using​​​‌ the huge volume of‌ clinical, biological and molecular‌​‌ data and their analysis​​ by artificial intelligence. PRISM​​​‌ will conduct large-scale clinical‌ studies and develop molecular‌​‌ analysis technologies and data​​ analysis methods.

Coordinated by​​​‌ Professor Fabrice André, Research‌ Director of Gustave Roussy,‌​‌ Inserm Research Director and​​ Professor at Paris-Saclay University,​​​‌ Prism aims to revolutionize‌ the understanding of the‌​‌ molecular and biological mechanisms​​ of cancer development and​​​‌ progression through artificial intelligence.‌ Based on increasingly rich‌​‌ data of various types​​ (clinical, genomic, microbiological, imaging,​​​‌ etc.), learning algorithms make‌ it possible to develop‌​‌ finer diagnostic and prognostic​​ tools, and thus to​​​‌ propose therapies that are‌ personalised according to the‌​‌ characteristics of the individual.​​

Funded by the French​​​‌ National Research Agency, PRISM‌ received the IHU label‌​‌ in 2018, followed by​​ the National Center for​​​‌ Precision Medicine label.

4.2.5‌ Physics-informed, generative models for‌​‌ heart left ventricle perfusion​​ analysis

Participants: Raoul​​​‌ Salle de Chou, Hugues‌ Talbot (Collaboration: I. Vignon-Clementel,‌​‌ SIMBIOTX Team Inria ;​​ L. Najman, Université Gustave-Eiffel,​​​‌ L. Papamanolis Stanford university,‌ USA, California)

Coronary arteries‌​‌ feed the heart muscles​​​‌ with nutrients and oxygen.​ As such, they are​‌ some of the most​​ critical blood vessel in​​​‌ the entire body. Coronary​ disease is difficult to​‌ diagnose especially when it​​ affects the smaller branches​​​‌ of these vessels, because​ direct imaging of these​‌ vessels is infeasible with​​ current medical imaging technology.​​​‌ Instead, blood perfusion through​ the myocardium can be​‌ imaged and is correlated​​ with both arterial and​​​‌ myocardium disease. However, perfusion​ imaging is challenging, invasive​‌ and expensive because it​​ relies on radioactive tracers.​​​‌

A previous model was​ developed for myocardial perfusion​‌ simulation for coronary artery​​ disease in [link] to​​​‌ replace the actual exam​ with a numerical twin​‌ and conduct it via​​ simulations. The model aims​​​‌ at reproducing ${[}^{\mathrm{15}}O]H_{\mathrm{2‌}}O$ PET imaging exam​​ using only CT scans​​​‌ as input. The simulation​ is based on :​‌

1. the detection, segmentation and​​ simulation of blood flow​​​‌ through the coronary vessels​ visible on the injected​‌ CT scan;
2. a patient-specific​​ method for generating small​​​‌ 3D vessels consistent with​ the vessels detected. The​‌ rules for the growth​​ of these vessels are​​​‌ based on physiology and​ simulated blood flows;
3. a​‌ perfusion simulation model that​​ considers the myocardium as​​​‌ a porous medium.

For​ this a linear Darcy​‌ model is used to​​ simulate blood flow through​​​‌ the porous medium. However,​ in addition to a​‌ high computational cost, the​​ simulation fails to accurately​​​‌ reproduce some diseases, particularly​ those that affect medium-size​‌ coronary branches.

The main​​ goal of this project​​​‌ is to combine Machine​ Learning (ML) methods with​‌ physical simulations, in order​​ to improve the current​​​‌ simulation pipeline. ML algorithms​ are used to learn​‌ from PET imaging exams​​ while being guided by​​​‌ simulation hypothesis, thereby diminishing​ the dependency on patient​‌ data. To achieve this,​​ each part of the​​​‌ simulation is to be​ replaced by an ML​‌ model. Following successful replication​​ of simulation outcomes, the​​​‌ model will undergoes refinement​ using patient data.

A​‌ finite volume physics informed​​ graph neural network was​​​‌ developed to solve the​ Darcy equations on irregular​‌ shapes serving as a​​ substitute for the myocardium​​​‌ component in perfusion simulation.​ Preliminary results indicate superior​‌ performance of this model​​ in terms of accuracy​​​‌ and generalization compared to​ classical ML approaches. In​‌ XX, we introduced a​​ novel optimization framework for​​​‌ the generation of the​ synthetic small vessels utilizing​‌ the constructed constrained optimization​​ (CCO) method. Our new​​​‌ approach simulated similar 2D​ vascular trees as the​‌ original CCO method in​​ terms of morphometry while​​​‌ producing better optimal solutions​ at lower computational cost.​‌ This new approach is​​ expected to be more​​​‌ readily reproducible using ML​ methods compared to the​‌ original CCO technique.

Additionally,​​ work has been conducted​​​‌ towards the determination of​ the myocardium perfusion regions.​‌ Determining these regions, and​​ their associated vessel is​​​‌ a crucial step in​ current simulation pipeline. However,​‌ the current calculation method​​ is inaccurate and highly​​​‌ sensitive to the resolution​ of segmented vessels. A​‌ more robust and accurate​​ model, employing graph neural​​ networks (GNNs), has been​​​‌ developed for the determination‌ of these regions.

4.3.1​​ Sparse signal processing in​​​‌ chemistry

Participants:Emilie Chouzenoux‌ , Mohammad Mehdi Kalla‌​‌ , Jean-Christophe Pesquet (Collaboration:​​ L. Duval, IFPEN, Rueil​​​‌ Malmaison)

Peak-signal retrieval is‌ a core challenge in‌​‌ separative analytical chemistry (AC).​​ For instance, in chromatography,​​​‌ spectrometry, spectroscopy, peak localization,‌ amplitude, width or area‌​‌ provide useful chemical quantitative​​ information. We investigated this​​​‌ problem through the deep‌ unrolling paradigm, in collaboration‌​‌ with Dr. L. Duval,​​ Research Engineer at IFP​​​‌ Energies Nouvelles, France.

4.3.2‌ Image restoration for Multiplex-Coherent‌​‌ Anti-Stokes Raman Scattering (M-CARS)​​ spectroscopy

Participants:Samy Ferrat​​​‌ , Ludovic Trautmann ,‌ Emilie Chouzenoux , Jean-Christophe‌​‌ Pesquet (Collaboration: C. Lefort,​​ XLIM, CNRS, Limoges ;​​​‌ CHU Limoges)

Label-free discrimination‌ between protein families within‌​‌ the same biological environment​​ remains a significant challenge​​​‌ for bioimaging. Through an‌ ongoing collaboration with physicists‌​‌ from XLIM laboratory (CNRS,​​ Limoges, France), and CHU​​​‌ Limoges, funded by PIQ‌ project Khi-MalMa, we investigate‌​‌ advanced mathematical and computational​​ solutions for M-CARS image​​​‌ restoration. In the preliminary‌ work 22, we‌​‌ leverage the intrinsic differences​​ in nonlinear optical responses​​​‌ between proteins to propose‌ a new strategy that‌​‌ allows qualitative label-free imaging​​ and enhances the analytical​​​‌ potential of M-CARS spectroscopy‌ for multifactorial biological studies.‌​‌

4.3.3 Reconstruction approaches in​​ PET imaging

Participants:Emilie​​​‌ Chouzenoux , Alix Chazottes‌ , Ludovic Trautmann ,‌​‌ Jean-Christophe Pesquet (Collaboration: F.​​ Sureau, CEA BioMaps +​​​‌ AAIMME project partners)

Positron‌ emission tomography (PET) is‌​‌ a quantitative functional imaging​​ modality used to track​​​‌ the fate and/or dynamics‌ of a radiotracerpreviously injected‌​‌ into a patient. This​​ technique is particularly used​​​‌ in oncology for diagnosis‌ and therapeutic monitoring, in‌​‌ the study ofneurodegenerative diseases,​​ and in pharmacology. In​​​‌ dynamic PET, the temporal‌ evolution of the spatial‌​‌ distribution of the radiotracerduring​​ the examination is taken​​​‌ into account for the‌ estimation of physiological parameters‌​‌ allowing for a fine​​ characterization of themolecular mechanisms​​​‌ at play (receptor concentration,‌ absorption, dissociation constants, binding‌​‌ potential, etc.). In the​​ PhD thesis of Alix​​​‌ Chazottes , in collaboration‌ between OPIS and CEA,‌​‌ we aim to propose​​ methodological developments in the​​​‌ fields of optimization and‌ learning to address the‌​‌ problem of robust dynamic​​ PET reconstruction. In the​​​‌ PhD thesis of Ludovic‌ Trautmann (ANR AAIMME), we‌​‌ investigate the joint image​​ reconstruction problem and estimation​​​‌ of uncertainties,in the context‌ of PET imaging with‌​‌ innovative time-of-flight detectors.

4.4.1​​​‌ Geometric Graph Neural Networks‌ for molecular and chemical‌​‌ systems

Participants:Fragkiskos Malliaros​​ , Hugues Talbot (Collaboration:​​​‌ A. Duval, Entalpic)

Graph‌ Neural Networks (GNNs) currently‌​‌ constitute state-of-the-art models for​​ solving prediction tasks on​​​‌ graphs. Through the flexible‌ formulation of the message‌​‌ passing mechanism, GNNs can​​ learn informative latent representations​​​‌ of graph entities at‌ different resolution levels (e.g.,‌​‌ node-, edge-, graph-level). In​​ many practical applications in​​​‌ molecular and chemical systems,‌ the nodes of the‌​‌ graph have associated geometric​​ attributes (e.g., coordinates, velocities)​​​‌ related to their position‌ in the 3D space.‌​‌ In this context, geometric​​​‌ graphs represent the interaction​ of atoms in the​‌ 3D space, encapsulating a​​ range of physical symmetries​​​‌ such as rotations and​ translations. Existing GNN models​‌ often overlook this aspect,​​ rendering them ill-suited for​​​‌ prediction tasks on geometric​ graphs. Recently, Geometric GNN​‌ architectures tailored to respect​​ physical symmetries have emerged​​​‌ as flexible models of​ atomic systems. Through an​‌ ongoing collaboration with Entalpic,​​ we study geometric GNN​​​‌ models, focusing both on​ design principles as well​‌ as on practical applications​​ in materials modeling (e.g.,​​​‌ property prediction and molecule​ generation).

4.4.2 Graph machine​‌ learning for spatiotemporal data​​

Participants:Fragkiskos Malliaros (Collaboration:​​​‌ J. Castro-Correa, Mohsen Badiey,​ Univ. of Delaware ;​‌ J. H. Giraldo, Télécom​​ Paris)

Numerous real-world prediction​​​‌ problems involve spatiotemporal data.​ For example, consider sensors​‌ scattered across diverse geographical​​ regions measuring environmental conditions​​​‌ (e.g., temperature, pollution) or​ functional magnetic resonance imaging​‌ (fMRI) data capturing brain​​ activity. Both scenarios generate​​​‌ data inherently rich in​ spatiotemporal structure, benefiting from​‌ the relational inductive bias​​ of graph-based modeling. In​​​‌ an ongoing collaboration with​ the University of Delaware,​‌ Télécom Paris, and La​​ Rochelle Université, we have​​​‌ introduced a methodology that​ leverages graph-based modeling, enabling​‌ time series imputation with​​ GNNs. Major challenges here​​​‌ concern inducing temporal and​ relational smoothness assumptions into​‌ the model as well​​ as inferring the (often​​​‌ unknown) graph structure. Furthermore,​ an intriguing aspect involves​‌ enhancing spatiotemporal graph models​​ with causal properties to​​​‌ capture causal influence effects​ among entities.

4.4.3 Graph​‌ representation learning for computational​​ medicine

Participants:Emilie Chouzenoux​​​‌ , Fragkiskos Malliaros (Collaboration:​ A. Majumdar, IIIT Delhi​‌ ; B. Liu, D.​​ Papadopoulos, G. Tsoumakas, A.​​​‌ Papadopoulos, Aristotle Univ. of​ Thessaloniki )

Following the​‌ Associate International Inria Team​​ COMPASS (ended in 2023),​​​‌ led by Emilie Chouzenoux​ and Dr. A. Majumdar​‌ (IIIT Delhi), we pursue​​ our research to investigate​​​‌ new models and inference​ tools to understand and​‌ predict optimal drug association,​​ so as to tackle​​​‌ real-life problems of computational​ drug discovery. We introduced​‌ graph-based regularization techniques in​​ order to incorporate expert​​​‌ knowledge and metadata in​ matrix completion tasks arising​‌ in the prediction of​​ drug-virus and drug-drug associations.​​​‌ Our recent works apply​ the proposed methodology to​‌ drug repositioning 8.​​

The discovery of drug-target​​​‌ interactions is also explored​ by Fragkiskos Malliaros ,​‌ in collaboration with Aristotle​​ University of Thessaloniki. Accurately​​​‌ identifying reliable interactions among​ drugs and proteins via​‌ computational methods, which typically​​ leverage heterogeneous information retrieved​​​‌ from diverse data sources,​ can boost the development​‌ of effective pharmaceuticals. We​​ have considered multi-layered network​​​‌ modeling to handle diverse​ drug and target similarities,​‌ introducing an optimization framework​​ called Multiple similarity DeepWalk-based​​​‌ Matrix Factorization (MDMF) for​ DTI prediction. Current efforts​‌ in this direction involve​​ leveraging Graph Neural Networks​​​‌ and self-supervised learning tools.​

4.4.4 Graph-based models for​‌ multimodal patient representation learning​​

Participants:Fragkiskos Malliaros ,​​​‌ Daniele Malitesta (Collaboration: N.​ Garcelon, A. Burgun, Institut​‌ Imagine)

Fusing heterogeneous patient​​ data – ranging from​​​‌ demographic data to clinical​ measurements and genetic information​‌ – is a critical​​ step in precision medicine​​ toward characterizing the progression​​​‌ history of a disease‌ and learning predictive models‌​‌ for diagnosis. In the​​ context of the ANR​​​‌ RHU project Innov4-ePiK (2024‌ – 2029) led by‌​‌ the Imagine Institute of​​ Genetic Diseases, we investigate​​​‌ the challenges arising while‌ designing such predictive models‌​‌ in the context of​​ rare and pharmacoresistant epilepsies.​​​‌ Specifically, we investigate how‌ to address current methodological‌​‌ limitations in drug response​​ and polypharmacy effects by​​​‌ leveraging graph-based modeling. We‌ aim to employ GNN‌​‌ models enhanced with (i)​​ self-supervision to address label​​​‌ scarcity, (ii) transfer learning‌ to cope with the‌​‌ small number of patients​​ due to the rare​​​‌ nature of the diseases‌ studied, (iii) and graph‌​‌ explainability to understand model​​ predictions. This will allow​​​‌ us to analyze patient‌ similarity and drug-disease networks‌​‌ towards unraveling hidden relationships​​ among drugs, epilepsies, and​​​‌ patients; and ultimately discovering‌ patient phenotyping clusters for‌​‌ precision medicine to improve​​ therapies' efficacy.

4.4.5 Graph​​​‌ inference for time series‌ analysis in complex dynamical‌​‌ systems

Participants:Emilie Chouzenoux​​ (Collaboration: V. Elvira, Univ.​​​‌ Edinburgh, UK)

Studying the‌ causal inter-dependencies in complex‌​‌ dynamical systems is a​​ critical challenge. We explore​​​‌ sparse graphical models to‌ gain insight through observational‌​‌ causal discovery. We revisit​​ Granger causality under a​​​‌ graphical perspective of state-space‌ models. We investigate differentiable‌​‌ particle filtering coupled with​​ proximal methods in 35​​​‌11 for estimating parameters‌ in the state equation‌​‌ of a polynomial state-space​​ model under sparse priors,​​​‌ emphasizing both causal and‌ correlation relationships among time‌​‌ series samples.

4.5.1 Visual​​​‌ Language Foundation Models for‌ medical image diagnosis

Participants‌​‌: Maria Vakalopoulou

This​​ research axis investigates visual–language​​​‌ foundation models for medical‌ image diagnosis with a‌​‌ strong emphasis on robustness,​​ fairness, and performance. It​​​‌ aims to study and‌ design multimodal models that‌​‌ maintain reliable diagnostic accuracy​​ under data shifts, noise,​​​‌ and limited annotations, while‌ ensuring equitable performance across‌​‌ patient populations, imaging devices,​​ and clinical settings. The​​​‌ axis explores modality biases‌ for state of the‌​‌ art VLMs, uncertainty estimation,​​ and rigorous evaluation protocols​​​‌ to enhance generalization, clinical‌ safety, and trustworthiness, ultimately‌​‌ enabling high-performing and fair​​ AI-assisted diagnostic systems.

4.5.2​​​‌ Independant vector analysis for‌ fMRI data processing

Participants‌​‌: Emilie Chouzenoux ,​​ Clement Cosserat (Collaboration: Univ.​​​‌ Baltimore ; GeorgiaTech)

Analyzing‌ multi-subject functional magnetic resonance‌​‌ imaging (fMRI) data requires​​ methods that can jointly​​​‌ capture shared and individual‌ patterns of brain activity‌​‌ across participants. Through a​​ collaboration with Prof. Tulay​​​‌ Adali (Univ. Baltimore), and‌ medical doctors from GeorgiaTech,‌​‌ we explore joint blind​​ source separation (JBSS) techniques,​​​‌ and in particular, independent‌ vector analysis (IVA), to‌​‌ model dependencies across subjects​​ while identifying distinct functional​​​‌ networks 34.

4.5.3‌ Imaging biomarkers and characterization‌​‌ for chronic lung diseases​​

Participants: Othmane Laousy​​​‌ , Maria Vakalopoulou (Collaboration:‌ S. Christodoulidis, G. Chassagnon,‌​‌ M.-P. Revel, APHP ;​​ N. Paragios, Therapanacea)

Diagnosis​​​‌ and staging of lung‌ diseases is a major‌​‌ challenge for both patient​​ care and approval of​​​‌ new treatments. Among imaging‌ techniques, computed tomography (CT)‌​‌ is the gold standard​​​‌ for in vivo morphological​ assessment of lung anatomy​‌ currently offering the highest​​ spatial resolution in lung​​​‌ diseases. Although CT is​ widely used its optimal​‌ use in clinical practice​​ and as an endpoint​​​‌ in clinical trials remains​ controversial. Our goal in​‌ the PhD thesis of​​ Othmane Laousy , is​​​‌ to provide automatic and​ accurate tools that could​‌ help clinicians with their​​ everyday practice.

4.5.4 AI​​​‌ for small bowel obstruction​ diagnosis

Participants:Emilie Chouzenoux​‌ , Maxence Gélard, Jean-Christophe​​ Pesquet , Quentin Vanderbecq​​​‌ (Collaboration:M. Zins, Hôpital Saint​ Joseph ; M. Wagner,​‌ LIB, Sorbonne Univ.)

Small​​ bowel obstruction (SBO) is​​​‌ a common nontraumatic surgical​ emergency. All guidelines recommend​‌ computed tomography (CT) as​​ the first-line imaging technique​​​‌ for patients with suspected​ mechanical SBO with a​‌ four-fold goal: (i) to​​ confirm or refute the​​​‌ diagnosis of SBO and,​ when SBO is present,​‌ (ii) to locate the​​ site of the obstruction,​​​‌ that is, the transition​ zone (iii) to identify​‌ the cause, and (iv)​​ to look for complications​​​‌ such as strangulation or​ perforation. Identifying SBO and​‌ differentiating its causes (e.g.,​​ open-loop and closed-loop mechanisms)​​​‌ is time-consuming and subject​ to inter-observer and intra-observer​‌ variability.

The aim of​​ this collaborative project between​​​‌ Inria Saclay OPIS, Hôpital​ St Joseph, and LIB,​‌ Sorbonne University, is to​​ investigate AI approaches for​​​‌ a guided SBO diagnosis​ from 3D CT scans.​‌

4.5.5 A generative model​​ for heart left ventricle​​​‌ perfusion analysis

Participant:Hugues​ Talbot (Collaboration: L. Najman,​‌ ESIEE Paris ; I.​​ Vignon-Clementel, REO Team leader,​​​‌ Inria ; C. Taylor,​ Heartflow Inc.)

Cardio-vascular diseases​‌ continue to be the​​ leading cause of mortality​​​‌ in the world. Understanding​ these diseases is a​‌ current, challenging and essential​​ research project. The leading​​​‌ cause of heart malfunction​ are stenoses causing ischemia​‌ in the coronary vessels.​​ Current CT and MRI​​​‌ technology can assess coronary​ diseases but are typically​‌ invasive, requiring risky catheterization​​ and renal-toxic contrast agents​​​‌ injection. In collaboration with​ the REO team headed​‌ by Irène Vignon-Clementel, and​​ Heartflow, a US based​​​‌ company, we have in​ the past contributed to​‌ Heartflow's major product, that​​ replaces these physical exams​​​‌ with image-based exams only,​ limiting the use of​‌ contrast agents and in​​ the cases that do​​​‌ not require a stent​ insertion, eliminating catheterisation. Heartflow​‌ is current the market​​ leader in non-invasive coronary​​​‌ exams and the owner​ of most of the​‌ relevant IP in this​​ domain.

Unfortunately, current imaging​​​‌ technology is unable to​ assess coronary disease along​‌ the full length of​​ coronary vessels. CT is​​​‌ limited to a resolution​ of about 1mm, whereas​‌ coronary vessels can be​​ much smaller, down to​​​‌ about 10 micrometers in​ diameter. To assess blood​‌ vessel health down to​​ the smallest sizes, blood​​​‌ perfusion imaging technique throughout​ the heart muscle must​‌ be used instead. Perfusion​​ imaging with PET or​​​‌ a Gamma camera, the​ current gold standard, is​‌ an invasive technology requiring​​ the use of radioactive​​​‌ tracers. To avoid using​ these, a lower quality​‌ estimate of perfusion can​​ be achieved using some​​ ToF or injected gated​​​‌ MRI modalities.

We have‌ investigated patient-specific vessel generation‌​‌ models together with porous​​ model simulations in order​​​‌ to propose a direct‌ model of perfusion imaging,‌​‌ based on the known​​ patient data, computer flow​​​‌ dynamic simulations as well‌ as experimental data consistent‌​‌ with known vessel and​​ heart muscle physiology. The​​​‌ objective of this work‌ is to both to‌​‌ provide a useful, complex​​ forward model of perfusion​​​‌ image generation, and to‌ solve the inverse problem‌​‌ of locating and assessing​​ coronary diseases given a​​​‌ perfusion exam, even though‌ the affected vessels may‌​‌ be too small to​​ be imaged directly.

Continuing​​​‌ on our work from‌ the period 2015-2019, this‌​‌ year we proposed a​​ functional myocardial perfusion model​​​‌ consisting of the CT-derived‌ segmented coronary vessels, a‌​‌ simulated vessel tree consisting​​ of several thousands of​​​‌ terminal vessels, filling the‌ myocardium in a patient-specific‌​‌ way, consistent with physiology​​ data, physics-based and empirically-observed​​​‌ vessel growth rules, and‌ a porous medium. We‌​‌ produced and validated a​​ CFD code capable of​​​‌ simulating blood flow in‌ all three coupled compartments,‌​‌ which allows us to​​ simulate perfusion realistically.

7.1.1​‌ Prox Repository

Web site:​​ Prox Repository

• Software Family:​​​‌ utility
• Audience: universe
• Evolution​ and maintenance: long term​‌ support
• Context/Role of OPIS:​​ This website was created​​​‌ by E. Chouzenoux and​ J.-C. Pesquet from OPIS,​‌ along with P.L. Combettes,​​ North Carolina State University,​​​‌ and G. Chierchia, ESIEE​ Paris. The maintenance is​‌ made by summer interns​​ funded by OPIS, and​​​‌ by the authors of​ the website.
• Duration of​‌ the Development: The website​​ was released in 2016,​​​‌ and is maintained regularly​ since then.
• Proximity operators​‌ have become increasingly important​​ tools as basic building​​​‌ blocks of proximal splitting​ algorithms, a class of​‌ algorithms that decompose complex​​ composite convex optimization methods​​​‌ into simple steps involving​ one of the functions​‌ present in the model.​​ This website provides formulas​​​‌ for efficiently computing the​ proximity operator of various​‌ functions, along with the​​ associated codes in Matlab/Python​​​‌ langages.
• The codes provided​ are distributed under the​‌ licence CeCill-B.

7.1.2 The​​ PINK image library

Web​​​‌ site: PINK

• Software Family:​ utility
• Audience: universe
• Evolution​‌ and maintenance: long term​​ support
• Context/Role of OPIS:​​​‌ H. Talbot is among​ the creators of this​‌ library and is still​​ actively involved in its​​​‌ maintenance.
• Duration of the​ Development: This software has​‌ been developed and maintained​​ since 2011.
• The PINK​​​‌ image library is a​ general-purpose, open-source, portable image​‌ processing library specializing in​​ discrete geometry and mathematical​​​‌ morphology. It is the​ result of several decades​‌ of research in these​​ domains and features state-of-the​​​‌ art algorithmic implementation of​ both classical and leading​‌ edge DG and MM​​ operators. These include nD​​​‌ parallel thinning and skeletonization​ methods and efficient hierarchical​‌ morphological transforms.
• This code​​ is distributed under the​​​‌ CeCILL license.

7.1.3 The​ Vivabrain AngioTK toolkit

Web​‌ site: Vivabrain AngioTK toolkit​​

• Software Family: vehicle
• Audience:​​​‌ partners
• Evolution and maintenance:​ basic
• Context/Role of OPIS:​‌ H. Talbot participated to​​ the programming of this​​​‌ software.
• Duration of the​ Development: This software has​‌ been released in 2018.​​
• AngioTK is a toolkit​​​‌ supported by Kitware (the​ authors of VTK) for​‌ the filtering, segmentation, generation​​ and simulation of blood​​​‌ vessels. It was started​ in the context of​‌ the Vivabrain ANR project​​ in 2012, but continues​​​‌ with the same as​ well as new partners.​‌ Applications are numerous, from​​ the simulation and understanding​​​‌ of perfusion (see associated​ theme) to the simulation​‌ of realistic blood flow​​ MRI images with associated​​​‌ ground truth, via the​ generation of blood vessel​‌ atlases.
• This code is​​ distributed under the Apache​​​‌ License, Version 2.0.

7.1.4​ A scientific image viewer​‌

Web site: imview

• Software​​ Family: vehicle
• Audience: community​​
• Evolution and maintenance: basic​​​‌
• Context/Role of OPIS: H.‌ Talbot is the author‌​‌ of this software.
• Duration​​ of the Development: This​​​‌ software has been released‌ in 2001. His last‌​‌ version has been updated​​ in 2014.
• This general-purpose​​​‌ and cross-platform scientific image‌ viewing tool has been‌​‌ part of the Debian​​ Linux distribution since 2001.​​​‌ This viewer is well‌ adapted to display 2D‌​‌ with high-precision data images​​ (floating-point, etc), as well​​​‌ as 3D and hyper-spectral‌ data. It features an‌​‌ interactive segmentation tool for​​ multispectral data and is​​​‌ scriptable.
• The codes provided‌ are distributed under a‌​‌ GNU General Public License​​ version 2.0 (GPLv2).

7.1.5​​​‌ Scion

Web site: Scion‌

• Software Family: vehicle
• Audience:‌​‌ community
• Evolution and maintenance:​​ basic
• Context/Role of OPIS:​​​‌ This software is developed‌ by Antonio Silveti-Falls ,‌​‌ in the context of​​ a collaboration with EPFL​​​‌ (LIONS/Cevher).
• Duration of the‌ Development: This software was‌​‌ developed during the year​​ 2025.
• This is a​​​‌ Python code allowing to‌ reproduce the results of‌​‌ the papers 40 and​​ 41. It also​​​‌ includes a general PyTorch‌ optimizer that can be‌​‌ used to train neural​​ networks.
• The codes provided​​​‌ are distributed under an‌ MIT License.
• The code‌​‌ also appears in the​​ NVIDA Nemotron codebase.​​​‌

7.1.6 ScanCovIA

Web site:‌ ScanCovIA

• Software Family: vehicle‌​‌
• Audience: community
• Evolution and​​ maintenance: basic
• Context/Role of​​​‌ OPIS: This software is‌ the product of the‌​‌ ScanCovIA collaborative project between​​ OPIS, IGR, CentraleSupélec and​​​‌ the start-up Owkin. Several‌ PhD students of OPIS‌​‌ were involved in the​​ programming of this software.​​​‌
• Duration of the Development:‌ This software was developed‌​‌ during the year 2020.​​
• This is a Python/Pytorch​​​‌ code allowing to reproduce‌ the results of the‌​‌ ScanCovIA project.
• The codes​​ provided are distributed under​​​‌ a GPL v3.0 license.‌

7.1.7 FOSSIL

Web site:‌​‌ FOSSIL

• Software Family: vehicle​​
• Audience: community
• Evolution and​​​‌ maintenance: basic
• Duration of‌ the Development: This software‌​‌ is developed as part​​ of a collaboration with​​​‌ Télécom Paris, in the‌ context of Amadou Siaka‌​‌ Sangare's research project and​​ Nicola Dunou's research internship​​​‌ (co-supervised by F. Malliaros‌ and J. Giraldo).
• This‌​‌ is a Python code​​ allowing to reproduce the​​​‌ results of the paper‌ 26.
• The codes‌​‌ provided are distributed under​​ the licence GNU General​​​‌ Public License v3.0.

7.1.8‌ PieCoN

Web site: PieCoN‌​‌

• Software Family: vehicle
• Audience:​​ community
• Evolution and maintenance:​​​‌ basic
• Duration of the‌ Development: This software is‌​‌ developed in the context​​ of Vahan Martirosyan's PhD​​​‌ work (co-supervised by F.‌ Malliaros, H. Talbot, and‌​‌ J. Giraldo).
• This is​​ a Python code allowing​​​‌ to reproduce the results‌ of the paper 21‌​‌.
• The codes provided​​ are distributed under the​​​‌ licence GNU General Public‌ License v3.0.

7.1.9 Cometh‌​‌

Web site: Cometh

• Software​​ Family: vehicle
• Audience: community​​​‌
• Evolution and maintenance: basic‌
• Duration of the Development:‌​‌ This software is initially​​ developed in the context​​​‌ of Antoine Siraudin's research‌ internship. It continued during‌​‌ his ongoing PhD at​​ RWTH Aachen University in​​​‌ collaboration with Christopher Morris‌ (RWTH Aachen University).
• This‌​‌ is a Python code​​​‌ allowing to reproduce the​ results of the paper​‌ 27.
• The codes​​ provided are distributed under​​​‌ the licence GNU General​ Public License v3.0.

7.1.10​‌ Gratin

Web site: Gratin​​

• Software Family: vehicle
• Audience:​​​‌ community
• Evolution and maintenance:​ basic
• Duration of the​‌ Development: This software is​​ developed in the context​​​‌ of Yassine Abbahaddou's PhD​ work (co-supervised by F.​‌ Malliaros, J. Lutzeyer, and​​ M. Vazirgiannis, École Polytechnique),​​​‌ in collaboration with Mohamed​ Aboussalah (NYU).
• This is​‌ a Python code allowing​​ to reproduce the results​​​‌ of the paper 29​.
• The codes provided​‌ are distributed under the​​ licence GNU General Public​​​‌ License v3.0.

7.1.11 FairDiffRec​

Web site: FairDiffRec

• Software​‌ Family: vehicle
• Audience: community​​
• Evolution and maintenance: basic​​​‌
• Duration of the Development:​ This software is developed​‌ in the context of​​ the postdoctoral position of​​​‌ D. Malitesta, in collaboration​ with G. Medda, M.​‌ Marras, L. Boratto (University​​ of Cagliari, Italy) and​​​‌ E. Purificato (JRC, Italy).​
• This is a Python​‌ code allowing to reproduce​​ the results of the​​​‌ paper 38.
• The​ codes provided are distributed​‌ under the licence GNU​​ General Public License v3.0.​​​‌

7.1.12 ADMP-GNN

Web site:​ ADMP-GNN

• Software Family: vehicle​‌
• Audience: community
• Evolution and​​ maintenance: basic
• Duration of​​​‌ the Development: This software​ is developed in the​‌ context of Yassine Abbahaddou's​​ PhD work (co-supervised by​​​‌ F. Malliaros, J. Lutzeyer,​ and M. Vazirgiannis, École​‌ Polytechnique).
• This is a​​ Python code allowing to​​​‌ reproduce the results of​ the paper 30.​‌
• The codes provided are​​ distributed under the licence​​​‌ GNU General Public License​ v3.0.

7.1.13 TRIGON

Web​‌ site: TRIGON

• Software Family:​​ vehicle
• Audience: community
• Evolution​​​‌ and maintenance: basic
• Duration​ of the Development: This​‌ software is developed as​​ part of a collaboration​​​‌ with Université Sorbonne Paris​ Nord (H. Attali, T.​‌ Papastergiou, and N. Pernelle).​​
• This is a Python​​​‌ code allowing to reproduce​ the results of the​‌ paper 32.
• The​​ codes provided are distributed​​​‌ under the licence GNU​ General Public License v3.0.​‌

7.1.14 COSIMO

Web site:​​ COSIMO

• Software Family: vehicle​​​‌
• Audience: community
• Evolution and​ maintenance: basic
• Duration of​‌ the Development: This software​​ is developed as part​​​‌ of a collaboration with​ Télécom Paris, in the​‌ context of the postdoctoral​​ position of A. Einizade​​​‌ (co-supervised by F. Malliaros​ and J. Giraldo), in​‌ collaboration with D. Thanou​​ (EPFL).
• This is a​​​‌ Python code allowing to​ reproduce the results of​‌ the paper 36.​​
• The codes provided are​​​‌ distributed under the licence​ GNU General Public License​‌ v3.0.

10.1.1 STIC/MATH/CLIMAT AmSud projects​

10.2.1 Visits of‌​‌ international scientists

10.2.2‌ Visits to international teams‌​‌

10.3.1 Horizon Europe

10.3.2 H2020 projects​​

10.4.1 ANR​​

• Program: ANR (appel générique​​​‌ CE45)
  • Project acronym: AAIMME‌
  • Project title: Apprentissage Automatique‌​‌ pour l'Imagerie Moléculaire et​​ la MEdecine du futur​​​‌
  • Duration: 2025-2028
  • Coordinator: Geoffrey‌ Daniel (DM2S, IRFU), local‌​‌ coordinator: Emilie Chouzenoux ,​​ participants: Jean-Christophe Pesquet ,​​​‌ Ludovic Trautmann

• Program: ANR‌ (appel générique)
  • Project acronym:‌​‌ Delta
  • From DEep Learning​​ to clinical Tissue Anisotropy:​​​‌ proof of concept infarct‌ lesion characterisation with 3D‌​‌ ultrasound
  • Duration: 2025-2029
  • Coordinator:​​ François Varray (Insa Lyon),​​​‌ local coordinator: Nora Ouzir‌

• Program: FHU
  • Project acronym:‌​‌ Mosaic 2
  • Multiscale Optimised​​ Strategy for Artificial intelligence-based​​​‌ Imaging biomarkers in digestive‌ Cancer
  • Duration: 2025-2029
  • Coordinator:‌​‌ Valerie Paradis (Hôpital Beaujon,​​ APHP), local coordinator: Nora​​​‌ Ouzir

• Program: FHU
  • Project‌ acronym: Transvir
  • Innovative strategies‌​‌ to treat chronic viral​​ infections after hematopoietic stem​​​‌ cell and solid organ‌ transplantation
  • Duration: 2025-2029
  • Coordinator:‌​‌ Le Goff Jérôme (Hôpital​​ Saint-Louis, APHP), local coordinator:​​​‌ Nora Ouzir

• Program: ANR‌ RHU
  • Project acronym: Innov4-ePiK‌​‌
  • Project title: Innovative diagnostic​​ and therapeutic approaches in​​​‌ epileptic and developmental encephalopathies‌ linked to potassium channel‌​‌ genes using the 4P​​ framework for medicine.
  • Duration:​​​‌ 2024-2028
  • Coordinator: Rima Nabbout,‌ Université Paris Cité /‌​‌ AP-HP, local: Fragkiskos Malliaros​​ , participant: Nora Ouzir​​​‌

• Program: ANR JCJC
  • Project‌ acronym: Hagnodice
  • Project title:‌​‌ Holistic explainable artificial intelligence​​ schemes for lung cancer​​​‌ prognosis
  • Duration: 2022-2026
  • Coordinator:‌ Maria Vakalopoulou

• Program: ANR‌​‌ JCJC
  • Project acronym: GraphIA​​
  • Project title: Scalable and​​​‌ robust representation learning on‌ graphs
  • Duration: 2021-2025
  • Coordinator:‌​‌ Fragkiskos Malliaros

• Program: ANR​​ JCJC
  • Project acronym: SIMPLES​​​‌
  • Project title: New Methods‌ for Nonsmooth Stochastic Bilevel‌​‌ Optimization
  • Duration: 2025-2029
  • Coordinator:​​ Antonio Silveti-Falls

10.4.2 PIQ​​​‌

• Program: PIQ Inria
  • Project‌ acronym: KhiMalMa
  • Project title:‌​‌ Towards non-invasive screening for​​ muscle diseases using novel​​​‌ non-linear optics combined with‌ advanced data processing methods‌​‌
  • Duration: 2025-2027
  • Coordinator: Claire​​ Lefort (XLIM, CNRS), local:​​​‌ Emilie Chouzenoux , participants:‌ Jean-Christophe Pesquet , Samy‌​‌ Ferrat

10.4.3 Others

11.1.1 Scientific​​ events: organisation

11.1.2 Scientific​​ events: selection

11.1.3 Journal

11.1.4 Invited‌ talks

• Emilie Chouzenoux :‌​‌ Plenary speaker, SIAM Annual​​ Meeting, Montreal, Canada, July​​​‌ 2025
• Emilie Chouzenoux :‌ Invited speaker, Séminaire Imagerie‌​‌ en santé, méthodologies et​​ problèmes ouverts, GS Santé​​​‌ publique, Villejuif, Nov. 2025‌
• Emilie Chouzenoux : Invited‌​‌ speaker, Electrical and Electronic​​ Engineering Department, Imperial College​​​‌ London, UK, Oct. 2025‌
• Emilie Chouzenoux : Invited‌​‌ speaker, Numerical Analysis Seminar,​​ Univ. Oxford, UK, Oct.​​​‌ 2025
• Emilie Chouzenoux :‌ Invited speaker, GDR IASIS‌​‌ workshop on Unrolling and​​ un/self/*/supervised learning for inverse​​​‌ problems, Paris, May 2025‌
• Emilie Chouzenoux : Invited‌​‌ speaker, Journées Franco-Chiliennes Optimisation,​​ Rouen, May 2025
• Fragkiskos​​​‌ Malliaros : Invited speaker,‌ Bellairs Workshop on Machine‌​‌ Learning and Statistical Signal​​ Processing, McGill University, Barbados,​​​‌ 2025.
• Fragkiskos Malliaros :‌ Kenote speaker, International Workshop‌​‌ on Graph-Based Representations in​​ Pattern Recognitions, Caen, France,​​​‌ 2025.
• Fragkiskos Malliaros :‌ Invited speaker, Machine Learning‌​‌ on Graphs Working Group,​​ Normandie Université, France, 2025.​​​‌ (Online).
• Jean-Christophe Pesquet :‌ Invited speaker at BASP‌​‌ Frontiers Workshop, Villars-sur-Ollon, Switzerland,​​ Jan. 2025.
• Jean-Christophe Pesquet​​​‌ : Tutorial speaker at‌ 33rd European Signal Processing‌​‌ Conference (EUSIPCO 2025), Isola​​ delle Femmine, Sicily, Italy,​​​‌ Sep. 2025.
• Hugues Talbot‌ : Invited speaker, SPRING‌​‌ Saclay, May 21st 2025.​​​‌
• Hugues Talbot : Keynote​ speaker, inauguration of MesoSPIM​‌ Paris-Saclay, June 6th 2025.​​
• Hugues Talbot : Invited​​​‌ speaker, Instituto de phisica​ de Canarias, Las Palmas,​‌ June 26 2025.
• Maria​​ Vakalopoulou : Invited speaker,​​​‌ AMLD, EPFL, Feb. 2025.​
• Maria Vakalopoulou : Invited​‌ speaker, 57th ESPGHAN Annual​​ Meeting, Helsinski, Finland, May​​​‌ 2025.
• Maria Vakalopoulou :​ Invited speaker, AI4EO symposium,​‌ Rennes, France, Sep. 2025.​​
• Maria Vakalopoulou : Invited​​​‌ speaker, Machine Intelligence for​ iNverse imaging, Observation Analysis​‌ and Sensing (MINOAS) Workshop,​​ Heraklion, Greece, Sep. 2025.​​​‌
• Maria Vakalopoulou : Invited​ speaker, 1st International Workshop​‌ on Biomedical Image and​​ Signal Computing for Unbiasedness,​​​‌ Interpretability and Trustworthiness, ICCV'2025,​ Honolulu, Hawai'i, Oct. 2025.​‌

11.1.5 Leadership within the​​ scientific community

• Emilie Chouzenoux​​​‌ : IEEE Senior Member,​ since September 2020.
• Emilie​‌ Chouzenoux : Associate member​​ of the EURASIP Technical​​​‌ Area Committee (TAC) on​ Signal and Data Analytics​‌ for Machine Learning (SiG-DML).​​
• Mounir Kaaniche : Elected​​​‌ member of the EURASIP​ Technical Area Committee (TAC)​‌ on Signal and Data​​ Analytics for Machine Learning​​​‌ (SiG-DML), since January 2025.​
• Mounir Kaaniche : IEEE​‌ Senior Member, since September​​ 2020.
• Nora Ouzir :​​​‌ Elected member of the​ EURASIP Technical Area Committee​‌ (TAC) on Biomedical Image​​ and Signals Analytics.
• Jean-Christophe​​​‌ Pesquet : Senior honorary​ member of the Institut​‌ Universitaire de France and​​ Fellow of IEEE and​​​‌ EURASIP.

11.1.6 Scientific expertise​

The members of the​‌ team participated to numerous​​ PhD Thesis Committees, PhD​​​‌ “comité de suivi individuel”,​ HdR Committees, recruiting Committees,​‌ and served as Grant​​ Reviewers.

• Emilie Chouzenoux :​​​‌ member of the scientific​ committee of PIQ program​‌ of Inria
• Emilie Chouzenoux​​ : member of the​​​‌ executive committee of DataIA​ institute of University Paris​‌ Saclay (until aug. 2025)​​
• Emilie Chouzenoux : member​​​‌ of the scientific committee​ of the programme Mathématiques​‌ du Calcul Scientifique et​​ de l'Ingénierie of the​​​‌ Labex Mathématiques Hadamard (Maths​ CSI LMH)
• Nora Ouzir​‌ : elected member of​​ CCUPS, Consultative Commission of​​​‌ Paris-Saclay University
• Nora Ouzir​ : member of the​‌ scientific committee of the​​ Programme Doctoral SCAI, Cluster​​​‌ IA de Sorbonne Université​
• Maria Vakalopoulou : Monitor-expert​‌ for EU research grants.​​
• Alix Chazottes : Jury​​​‌ member of the ANR​ Compétences & Métiers d'Avenir​‌, plan de relance​​ France2030.

11.1.7 Research administration​​​‌

• Jean-Christophe Pesquet is the​ head of the laboratoire​‌ Centre pour la Vision​​ Numérique (CVN), CentraleSupélec

11.1.8​​​‌ Teaching administration

• Emilie Chouzenoux​ : attached professor in​‌ AI in CentraleSupélec, since​​ sep. 2022.
• Nora Ouzir​​​‌ : Co-coordinator of the​ Bachelor in Artificial Intelligence,​‌ Data and Management Sciences,​​ AIDAMS, with ESSEC Business​​​‌ School and CentraleSupélec.
• Nora​ Ouzir : Co-coordinator of​‌ the Thematic Sequence 2​​ (ST2) Viral Propagation, 1st​​​‌ year of CentraleSupélec.
• Nora​ Ouzir : Head for​‌ the Machine Learning Elective​​ course in 2nd year​​​‌ of CentraleSupélec (210 students).​
• Fragkiskos Malliaros : co-director​‌ of the Master in​​ Data Sciences and Business​​​‌ Analytics (DSBA).
• Fragkiskos Malliaros​ : head of the​‌ Data and Information Sciences​​ (SDI) specialization at CentraleSupélec.​​​‌
• Fragkiskos Malliaros : academic​ responsible of CentraleSupélec's Summer​‌ School on AI.
• Jean-Christophe​​ Pesquet : local head​​ for the Optimization M.Sc.​​​‌ at CentraleSupélec.
• Jean-Christophe Pesquet‌ : head for the‌​‌ main Optimization course in​​ 2nd year of CentraleSupélec​​​‌ (600 students).
• Hugues Talbot‌ : head of the‌​‌ Mastère Specialisé in "Trustworthy​​ AI". It was in​​​‌ development since 2022 with‌ IRT SystemX and CentraleSupelec‌​‌ Exed. This Master is​​ designed for professionals who​​​‌ want to retrain in‌ AI and focuses on‌​‌ the explainability and trustworthiness​​ of models. It represents​​​‌ 400h of teaching and‌ opened its first batch‌​‌ this year.
• Hugues Talbot​​ : local head for​​​‌ CentraleSupélec the Mathematiques, Vision‌ Apprentissage (MVA) Master of‌​‌ Ecole Normale Supérieure Paris-Saclay​​

11.2.1‌​‌ Teaching

Several permanent members​​ of OPIS were involved​​​‌ as lecturer (lec.) or‌ lab instructors (lab), in‌​‌ the following courses.

• Master:​​ Emilie Chouzenoux . Foundations​​​‌ of Distributed and Large‌ Scale Computing, 26h (lec.),‌​‌ 3rd year CentraleSupélec and​​ M.Sc. MVA Paris Saclay.​​​‌
• Master: Emilie Chouzenoux .‌ Advanced Machine Learning, 18h‌​‌ (lec.), 3rd year CentraleSupélec.​​
• Bachelor: Emilie Chouzenoux .​​​‌ Optimization, 24h (lec.), 1st‌ year Bachelor AIDAMS, Univ.‌​‌ Paris Saclay.
• Master/PhD: Emilie​​ Chouzenoux . Introduction to​​​‌ theory and numerics of‌ large scale optimization, 12h‌​‌ (lec. + labs), CIMPA​​ School on Optimal Transport,​​​‌ PDEs and Optimization, Essaouira,‌ Marocco, May 2025
• Master:‌​‌ Nora Ouzir . Machine​​ Learning, 30h (lec.), 2nd​​​‌ year course, CentraleSupélec, EN‌
• Master: Nora Ouzir .‌​‌ Advanced Machine Learning, 24h​​ (lec.), Msc DSBA, CentraleSupélec/ESSEC.​​​‌
• Master: Nora Ouzir .‌ Optimization, 15h (lab.), 2nd‌​‌ year course, CentraleSupélec.
• Bachelor:​​ Nora Ouzir . Signal​​​‌ Procesing, 10h (lab.), 1st‌ year course, CentraleSupélec.
• Master:‌​‌ Nora Ouzir . Medical​​ Image Processing 3h (lec.),​​​‌ AI and Global Health‌ program of the European‌​‌ University Alliance for Global​​ Health (EUGLOH).
• Master: Fragkiskos​​​‌ Malliaros . Machine Learning‌ in Network Science, 27h‌​‌ (lec.), Master in Data​​ Sciences and Business Analytics,​​​‌ CentraleSupélec and ESSEC Business‌ School, M.Sc. in Artificial‌​‌ Intelligence, CentraleSupélec, 3rd year​​ data science mention, CentraleSupélec.​​​‌
• Master: Fragkiskos Malliaros .‌ Foundations of Machine Learning,‌​‌ 48h (lec.), Master in​​ Data Sciences and Business​​​‌ Analytics, CentraleSupélec and ESSEC‌ Business School.
• Master: Jean-Christophe‌​‌ Pesquet . Introductory course​​ on Optimization, 33h (lec.),​​​‌ 2nd year CentraleSupélec.
• Master:‌ Jean-Christophe Pesquet . Introduction‌​‌ to Optimization, 6h (lec.),​​ M.Sc. MVA Paris Saclay.​​​‌
• Master: Jean-Christophe Pesquet .‌ Advanced course on Optimization,‌​‌ 10h (lec.), M.Sc. in​​ Signal Processing and Automatic​​​‌ Control, Univ. Paris-Saclay.
• Master:‌ Jean-Christophe Pesquet . Convex‌​‌ Optimization Algorithms, 15h (lec.),​​ M.Sc. in Optimization, Univ.​​​‌ Paris-Saclay.
• Master: Antonio Silveti-Falls‌ . Convergence, Integration, and‌​‌ Probability, 18h (lec.) +​​ 18h (lab), 1st year​​​‌ course, CentraleSupélec.
• Master: Antonio‌ Silveti-Falls . Optimization for‌​‌ Computer Vision, 21h (lec.​​ + lab), 3rd year​​​‌ course, CentraleSupélec.
• Master: Antonio‌ Silveti-Falls . Partial Differential‌​‌ Equations, 13.5h (lab), 1st​​ year course, CentraleSupélec.
• Master:​​​‌ Antonio Silveti-Falls . Optimization,‌ 12.5h (lab), 2nd year‌​‌ course, CentraleSupélec.
• Bachelor: Antonio​​ Silveti-Falls . Analysis I,​​​‌ 18h (lab), First year‌ Bachelors of Global Engineering‌​‌ students, Univ. Paris Saclay.​​
• Bachelor: Antonio Silveti-Falls .​​​‌ Analysis II, 18h (lab),‌ First year Bachelors of‌​‌ Global Engineering students, Univ.​​​‌ Paris Saclay.
• Bachelor: Antonio​ Silveti-Falls . Analysis III,​‌ 18h (lab), First year​​ Bachelors of Global Engineering​​​‌ students, Univ. Paris Saclay.​
• Bachelor: Antonio Silveti-Falls .​‌ Probability, 18h (lab), First​​ year Bachelors of Global​​​‌ Engineering students, Univ. Paris​ Saclay.
• Bachelor: Antonio Silveti-Falls​‌ . Topology and Functional​​ Analysis, 18h (lab), Second​​​‌ year Bachelors of Global​ Engineering students, Univ. Paris​‌ Saclay.
• Master: Hugues Talbot​​ . Convergence Integration Probabilité,​​​‌ 18h (lab), 1st year​ course, CentraleSupélec.
• Master: Hugues​‌ Talbot . High-performance computing,​​ 12h (lab), 2nd year​​​‌ CentraleSupélec.
• Master: Hugues Talbot​ . Introduction à la​‌ morphologie mathématique: 12h (lab),​​ 3rd year CentraleSupélec.
• Master:​​​‌ Hugues Talbot . Modern​ mathematical morphology (20h lec.​‌ + 8h lab), 3rd​​ Year CentraleSupélec and MVA​​​‌ (ENS Paris-Saclay).
• Master: Hugues​ Talbot . Optimisation for​‌ AI, (20h lec +​​ 8h lab) M.Sc in​​​‌ AI, CentraleSupélec.
• Master: Hugues​ Talbot . Introduction to​‌ Machine Learning, MS Management​​ of Technogy, 30h (lec.).​​​‌
• Master: Maria Vakalopoulou .​ Introduction to Visual Computing,​‌ CentraleSupélec, 25h (lec).
• Master:​​ Maria Vakalopoulou . Introduction​​​‌ to Deep Learning, M.Sc.​ in Data Sciences and​‌ Business Analytics, CentraleSupélec and​​ ESSEC Business School, 24h​​​‌ (lec).
• Master: Maria Vakalopoulou​ . Introduction to Deep​‌ Learning, M.Sc. in Artificial​​ Intelligence, CentraleSupélec, 24h (lec).​​​‌
• Master: Maria Vakalopoulou .​ Deep Learning, M.Sc. in​‌ Vision and Machine Learning,​​ ENS Paris-Saclay, 25h (lec).​​​‌
• Master: Maria Vakalopoulou .​ Deep Learning in Medical​‌ Imaging, M.Sc. in Vision​​ and Machine Learning, ENS​​​‌ Paris-Saclay, 25h (lec).
• Master:​ Maria Vakalopoulou . Introduction​‌ to Deep Learning, M.Sc.​​ in Artificial Intelligence, CentraleSupélec,​​​‌ FR, 24 h (lec).​

Several students members of​‌ OPIS have teaching assistant​​ activities, in the following​​​‌ cursus of the Univ.​ Paris Saclay campus:

• Bachelor​‌ AIDAMS, CentraleSupélec and ESSEC​​
• ENSTA ParisTech
• CentraleSupélec
• M.Sc.​​​‌ DSBA, CentraleSupélec and ESSEC​
• M.Sc. MVA, Univ. Paris​‌ Saclay

11.2.2 PhD supervision​​

• PhD (completed): Loïc Le​​​‌ Bescond . Precision medicine,​ Histology and Deep learning,​‌ 2021-2024, supervised by F.​​ André (IGR) and Hugues​​​‌ Talbot .
• PhD (completed):​ Thomas Guilmeau . Algorithmes​‌ stochastiques pour l'optimisation non​​ convexe, 2021-2024, supervised by​​​‌ Emilie Chouzenoux and V.​ Elvira (Univ. Edinburgh).
• PhD​‌ (in progress): Andrea Persici.​​ Semantic Analysis of Deep-Sky​​​‌ Images using Machine Learning​ and Structural Approaches, 2025-2027,​‌ supervised by Benjamin Perret​​ (UGE) et Hugues Talbot​​​‌ .
• PhD (in progress):​ Raaja El Hamdani .​‌ Robust graph representation learning​​ and applications in misinformation​​​‌ detection, 2021-2024, supervised by​ Fragkiskos Malliaros and T.​‌ Bonald (Télécom-Paris).
• PhD (in​​ progress): Clement Cosserat .​​​‌ Algorithmes de majoration-minimisation pour​ le traitement du signal​‌ statistique, 2022-2025, supervised by​​ Emilie Chouzenoux and T.​​​‌ Adali (Univ. Baltimore, USA).​
• PhD (in progress): Alix​‌ Chazottes . Algorithmes d’optimisation​​ dépliés pour la reconstruction​​​‌ d’images à partir de​ données TEP dynamique, 2023-2026,​‌ supervised by Emilie Chouzenoux​​ and F. Sureau (CEA,​​​‌ Biomaps).
• PhD (in progress):​ Aymen Sardroui . Histopathological​‌ image analysis, 2022-2025, supervised​​ by Mounir Kaaniche and​​​‌ Jean-Christophe Pesquet .
• PhD​ (in progress): Arsene Amoya.​‌ Neural networks-based stereo image​​ retrieval, 2023-2026, supervised by​​​‌ Mounir Kaaniche and A.​ Benazza-Benyahia (SUP'COM-Tunis).
• PhD (in​‌ progress): Nabil Mouadden. Deep​​ Learning methods for lung​​ applications, 2023-2026, supervised by​​​‌ Maria Vakalopoulou and G.‌ Chassagnon (Hôpital Cochin).
• PhD‌​‌ (in progress): Jinqwei Zhang.​​ Deep Learning methods on​​​‌ Digital Pathology, 2020-2024, supervised‌ by Maria Vakalopoulou ,‌​‌ and D. Samaras (Stony​​ Brook University).
• PhD (in​​​‌ progress): Yassine Abbahaddou .‌ Topics in Geometric Deep‌​‌ Learning, 2022-2025, supervised by​​ Fragkiskos Malliaros , J.​​​‌ Lutzeyer, and M. Vazirgiannis‌ (École Polytechnique).
• PhD (in‌​‌ progress): Vahan Martirosyan .​​ Deep Graph Neural Networks​​​‌ (GNNs) and Applications in‌ Biomedicine, 2023-2026, supervised by‌​‌ Fragkiskos Malliaros , Hugues​​ Talbot , and J.​​​‌ Giraldo (Télécom Paris).
• PhD‌ (in progress): Nicolas Salvy‌​‌ . Génération d'images cérébrales​​ fonctionnelles à grande échelle​​​‌ poru améliorer la cartographie‌ cérébrale, 2023-2026, supervised by‌​‌ Hugues Talbot , and​​ Bertrand Thirion (Inria Saclay,​​​‌ MIND).
• PhD (in progress):‌ Hafsa El Herichi .‌​‌ Extraction du tissage 3D​​ des pièces composites de​​​‌ grandes dimensions à partir‌ d’images tomographiques, 2023-2026, supervised‌​‌ by Hugues Talbot ,​​ and Stéphane Roux (Laboratoire​​​‌ de Mécanique de Paris-Saclay,‌ ENS Paris-Saclay).
• PhD (in‌​‌ progress): David Restrepo. Bias​​ Analysis on vision and​​​‌ language models 2024-2027, supervised‌ by Maria Vakalopoulou ,‌​‌ Stergios Christodoulidis, Enzo Ferrante​​ and Gilles Fay, MICS,​​​‌ CentraleSupélec.
• PhD (in progress):‌ Adam Ghalem. Graph Neural‌​‌ Networks for Causal Inference​​ for Wireless Network Management,​​​‌ 2024-2027, supervised by Fragkiskos‌ Malliaros .
• PhD (in‌​‌ progress): Vuk Ignjatovic .​​ Generative Models for Motion​​​‌ Correction in Computed Tomography,‌ 2024-2027, supervised by Nora‌​‌ Ouzir , Jean-Christophe Pesquet​​ , and Cyril Riddell​​​‌ (GE Healthcare).
• PhD (in‌ progress): Raoul Sallé de‌​‌ Chou, Machine-learning based Prediction​​ of heart perfusion maps,​​​‌ 2021-2025, supervised by Laurent‌ Najman (UGE), Hugues Talbot‌​‌ , Irene Vignon-Clémentel (Inria​​ SimbotX)
• PhD (in progress):​​​‌ Francesco Songia. Reduced order‌ modelling of hemodynamics for‌​‌ liver surgery procedure, 2025-2028,​​ supervised by Nicolas Golse​​​‌ (APHP), Irene Vignon-Clementel (Inria‌ SimbiotX), Hugues Talbot .‌​‌
• PhD (in progress): Imed​​ Moussa . Vibratory and​​​‌ acoustic source separation using‌ generative models for the‌​‌ aerospace industry, 2025-2027, supervised​​ by Emilie Chouzenoux and​​​‌ Maxime Leiber (SafranTech).
• PhD‌ (in progress): Paul Delage‌​‌ . Generation of BIM​​ models based on two-dimensional​​​‌ architectural drawings, 2025-2027, supervised‌ by Emilie Chouzenoux and‌​‌ Gottried Jacquet (SOCOTEC).
• PhD​​ (in progress): Ludovic Trautmann​​​‌ . Uncertainty Quantification for‌ PET reconstructed images with‌​‌ AI, supervised by Emilie​​ Chouzenoux and Florent Sureau​​​‌ (BioMaps).
• PhD (in progress):‌ Shuai Mao . Robust‌​‌ Few-shot Learning for Medical​​ Imaging, 2025-2028, supervised by​​​‌ Nora Ouzir and Jean-Christophe‌ Pesquet .
• PhD (in‌​‌ progress): Eve Delegue .​​ Novel AI Methods for​​​‌ Liver Cancer Histopathology Image‌ Analysis, 2025-2028, supervised by‌​‌ Nora Ouzir , Jean-Christophe​​ Pesquet , and Astrid​​​‌ Laurent-Bellue (Bicêtre Hospital)

11.2.3‌ Intern/Engineers/Apprentices supervision

• Maxence Adly‌​‌ , Sep. 2024-Feb. 2025,​​ supervised by Emilie Chouzenoux​​​‌ (intern)
• Idriss Benkirane ,‌ Sep. 2024-Feb. 2025, supervised‌​‌ by Hugues Talbot (intern)​​
• Benjamin Clene , Nov.​​​‌ 2024-Jan. 2025, supervised by‌ Hugues Talbot (intern)
• Bilal‌​‌ Zidna , Mar. 2025-Aug.​​ 2025, supervised by Emilie​​​‌ Chouzenoux (intern)
• Matthieu Merigot–Lombard‌ , May 2025 -‌​‌ Sep. 2025, supervised by​​ Emilie Chouzenoux (intern)
• Bruno​​​‌ Amorim De Araujo ,‌ April 2025 - Sep.‌​‌ 2025, supervised by Emilie​​​‌ Chouzenoux (intern)
• Yassine Elammari​ , Jun. 2025-Dec. 2025,​‌ supervised by Nora Ouzir​​ (intern)
• Eve Delegue ,​​​‌ Apr. 2025-Aug. 2025, supervised​ by Nora Ouzir (intern)​‌
• Luis Evrard , Apr.​​ 2025- Nov.2025, supervised by​​​‌ Nora Ouzir (intern)
• Alexandre​ Bertot , Sept. 2025-​‌ Jan. 2026, supervised by​​ Nora Ouzir (intern)
• Ludovic​​​‌ Trautmann , Dec. 2024​ - Aug. 2025, supervised​‌ by Emilie Chouzenoux (engineer)​​
• Mohammad Mehdi Kalla ,​​​‌ Sep. 2024-Aug. 2026, supervised​ by Emilie Chouzenoux (engineer​‌ apprentice)
• Samy Ferrat ,​​ Oct. 2025-Sep. 2027, supervised​​​‌ by Emilie Chouzenoux (engineer)​
• Mohamed Salim Ben Omrane​‌ , April - Sept.​​ 2025, supervised by Mounir​​​‌ Kaaniche and Jean-Christophe Pesquet​ (intern)

11.2.4 Juries

The​‌ faculty members of the​​ team serve regularly as​​​‌ a jury Member to​ Final Engineering Internship and​‌ the Research Innovation Project​​ for students of CentraleSupélec,​​​‌ and to Research Internship​ for students of Ms.C.​‌ MVA, ENS Paris Saclay.​​

11.2.5 Educational and pedagogical​​​‌ outreach

• Alix Chazottes :​ Participation at outreach animation​‌ events for high school​​ students, through La Recherche​​​‌ en Basket
• Alix Chazottes​ : Presentation to ENS​‌ Paris Saclay L3 students,​​ through `Panorama recherche' vulgarization​​​‌ event organized by Prof.​ L. Oudre.

11.3.1 Productions (articles, videos,​​ podcasts, serious games, ...)​​​‌

• Emilie Chouzenoux : Participation​ to the dissemination paper​‌ “Les maths à la​​ rescousse de l’intelligence artificielle”​​​‌ [link], Le Monde​ Cahier Sciences, 27 Oct.​‌ 2025

11.3.2 Participation in​​ Live events

• Nora Ouzir​​​‌ , Aymen Sardroui ,​ Emilie Chouzenoux : Scientific​‌ Days AI Action Summit​​ 2025
• Emilie Chouzenoux :​​​‌ Premières Rencontres du Programme​ Inria Quadrant, June 2025​‌

International journals

• 4​​ articleS.Samy Ammari​​​‌, A.Arnaud Quillent‌, V.Víctor Elvira‌​‌, F.François Bidault​​, G.Gabriel Garcia​​​‌, D.Dana Hartl‌, C.Corinne Balleyguier‌​‌, N.Nathalie Lassau​​ and É.Émilie Chouzenoux​​​‌. Using Machine Learning‌ on MRI Radiomics to‌​‌ Diagnose Parotid Tumours Before​​ Comparing Performance with Radiologists:​​​‌ A Pilot Study.‌Journal of Imaging Informatics‌​‌ in Medicine383​​June 2025, 1496-1508​​​‌HALDOIback to‌ text
• 5 articleY.‌​‌Younes Belkouchi, J.-C.​​Jean-Christophe Pesquet, A.​​​‌Audrey Repetti and H.‌Hugues Talbot. Learning‌​‌ truly monotone operators with​​ applications to nonlinear inverse​​​‌ problems: Learning truly monotone‌ operators.SIAM Journal‌​‌ on Imaging Sciences18​​12025, 735-764​​​‌HALback to text‌
• 6 articleH.Hakim‌​‌ Benkirane, M.Maria​​ Vakalopoulou, D.David​​​‌ Planchard, J.Julien‌ Adam, K.Ken‌​‌ Olaussen, S.Stefan​​ Michiels and P.-H.Paul-Henry​​​‌ Cournède. Multimodal CustOmics:‌ A unified and interpretable‌​‌ multi-task deep learning framework​​ for multimodal integrative data​​​‌ analysis in oncology.‌PLoS Computational Biology21‌​‌6June 2025,​​ e1013012HALDOI
• 7​​​‌ articleJ.Jhon Castro-Correa‌, M.Mohsen Badiey‌​‌, J.Jhony Giraldo​​ and F.Fragkiskos Malliaros​​​‌. Semi-supervised graph learning‌ for underwater source localization‌​‌ using ship-of-opportunity spectrograms.​​Journal of the Acoustical​​​‌ Society of America158‌3September 2025,‌​‌ 1836-1848HALDOI
• 8​​ articleS.Sayantika Chatterjee​​​‌, S.Stuti Jain‌, K.Kriti Kumar‌​‌, E.Emilie Chouzenoux​​ and A.Angshul Majumdar​​​‌. Deep Probabilistic Matrix‌ Factorization on Graphs: Application‌​‌ to Drug Repositioning in​​ Antimicrobial Resistance.IEEE/ACM​​​‌ Transactions on Computational Biology‌ and Bioinformatics2025.‌​‌ In press. HALDOI​​back to textback​​​‌ to text
• 9 article‌E.Emilie Chouzenoux,‌​‌ C.Cecile Della Valle​​​‌ and J.-C.Jean-Christophe Pesquet​. Stability Bounds for​‌ the Unfolded Forward-Backward Algorithm​​.Journal of Mathematical​​​‌ Imaging and Vision67​482025HALDOI​‌back to textback​​ to text
• 10 article​​​‌C.Clément Cosserat,​ B.Ben Gabrielson,​‌ E.Emilie Chouzenoux,​​ J.-C.Jean-Christophe Pesquet and​​​‌ T.Tülay Adali.​ An Effective Iterative Solution​‌ for Independent Vector Analysis​​ with Convergence Guarantees.​​​‌IEEE Transactions on Signal​ Processing732025,​‌ 4718 - 4733HAL​​DOIback to text​​​‌back to text
• 11​ articleB.Benjamin Cox​‌, E.Emilie Chouzenoux​​ and V.Víctor Elvira​​​‌. GraphGrad: Efficient Estimation​ of Sparse Polynomial Representations​‌ for General State-Space Models​​.IEEE Transactions on​​​‌ Signal Processing73March​ 2025, 1562-1576HAL​‌DOIback to text​​back to text
• 12​​​‌ articleT.Tassnim Dardouri​, M.Mounir Kaaniche​‌, A.Amel Benazza-Benyahia​​ and G.Gabriel Dauphin​​​‌. Multi-Task Convolution Neural​ Network-Based Lifting Scheme for​‌ Image Compression.Pattern​​ Recognition Letters2025HAL​​​‌back to text
• 13​ articleR.Roland Eid​‌, A.Anthony Tarabay​​, P.Pierre Decazes​​​‌, C.Clémence David​, F.Fouad Kerbage​‌, J.Jean Zeghondy​​, L.Leony Antoun​​​‌, C.Cristina Smolenschi​, A.Alina Fuerea​‌, M.Marine Valery​​, V.Valerie Boige​​​‌, M.Maximiliano Gelli​, L.Lambros Tselikas​‌, J.Jerome Durand-Labrunie​​, Y.Younes Belkouchi​​​‌, L.Lawrance Littisha​, S.Samy Ammari​‌, M.Michel Ducreux​​, N.Nathalie Lassau​​​‌ and A.Antoine Hollebecque​. Predictive factors of​‌ FOLFIRINOX chemotherapy toxicity in​​ pancreatic adenocarcinoma patients.​​​‌Future Oncology216​February 2025, 691-697​‌HALDOI
• 14 article​​V.Víctor Elvira,​​​‌ E.Emilie Chouzenoux and​ O.O Deniz Akyildiz​‌. A Proximal Newton​​ Adaptive Importance Sampler.​​​‌IEEE Signal Processing Letters​322025, 1545-1549​‌HALback to text​​
• 15 articleJ.-B.Jean-Baptiste​​​‌ Fest, A.Audrey​ Repetti and E.Emilie​‌ Chouzenoux. A stochastic​​ use of the Kurdyka-Lojasiewicz​​​‌ property: Investigation of optimization​ algorithms behaviours in a​‌ non-convex differentiable framework.​​Foundations of Data Science​​​‌2025. In press.​ HALback to text​‌
• 16 articleT.Thomas​​ Guilmeau, E.Emilie​​​‌ Chouzenoux and V.Víctor​ Elvira. Regularized Rényi​‌ divergence minimization through Bregman​​ proximal gradient algorithms.​​​‌Journal of Machine Learning​ Research261572025​‌, 1−56HALback​​ to text
• 17 article​​​‌M.Martinez Leonard,​ F.François Andrieu,​‌ F.Frédéric Schmidt,​​ H.Hugues Talbot and​​​‌ B.Bentley Mark.​ Robust automatic crater detection​‌ at all latitudes on​​ Mars with Deep-learning.​​​‌Planetary and Space Science​260June 2025HAL​‌DOIback to text​​
• 18 articleH.Huan​​​‌ Li, X.Xinpeng​ Huang, Y.Yilei​‌ Chen, C.Chao​​ Yang, M.Mounir​​​‌ Kaaniche, Q.Qiuwen​ Zhang and P.Ping​‌ An. Low-bitrate Light​​ Field Video Compression Through​​​‌ Key Sequences Encoding and​ Joint Reconstruction Network.​‌IEEE Transactions on Circuits​​ and Systems for Video​​ Technology2025, 1-1​​​‌In press. HALDOI‌
• 19 articleJ.Jingtao‌​‌ Li, Z.Zhixuan​​ Zhou, X.Xintong​​​‌ Zhao, M.Mounir‌ Kaaniche, C.Congcong‌​‌ Wang and D.Ding​​ Liu. SU3plus: An​​​‌ Enhanced Swin-UNet for Synthesizing‌ Vertically Integrated Liquid from‌​‌ Multiple Meteorological Satellite Data​​.IEEE Transactions on​​​‌ Geoscience and Remote Sensing‌2025, 1-1HAL‌​‌DOI
• 20 articleS.​​Ségolène Martin, J.-C.​​​‌Jean-Christophe Pesquet, G.‌Gabriele Steidl and I.‌​‌ B.Ismail Ben Ayed​​. Variable Bregman majorization-minimization​​​‌ algorithm and its application‌ to Dirichlet maximum likelihood‌​‌ estimation.Journal of​​ Applied and Numerical Optimization​​​‌732025HAL‌DOIback to text‌​‌
• 21 articleV.Vahan​​ Martirosyan, J. H.​​​‌Jhony H Giraldo and‌ F. D.Fragkiskos D‌​‌ Malliaros. Piecewise Constant​​ Spectral Graph Neural Network​​​‌.Transactions on Machine‌ Learning Research JournalApril‌​‌ 2025HALback to​​ textback to text​​​‌
• 22 articleM.Malik‌ Nafa, L.Ludovic‌​‌ Trautmann, U.Ugo​​ Arles Bottega, T.​​​‌Tigran Mansuryan, A.‌Alessandro Tonello, L.‌​‌Lionel Rechignat, M.​​Marc Fabert, L.​​​‌Laetitia Magnol, V.‌Véronique Blanquet, F.‌​‌Fabienne Baraige, V.​​Vincent Couderc, C.​​​‌Claire Carrion, J.-R.‌Jean-René Duclère and C.‌​‌Claire Lefort. Label-free​​ discrimination of muscle proteins​​​‌ based on nonresonant background‌ signature of Multiplex-Coherent Anti-Stokes‌​‌ Raman Scattering imaging.​​Journal of Physics D:​​​‌ Applied Physics2025.‌ In press. HALDOI‌​‌back to text
• 23​​ articleJ.Joeri Nicolaes​​​‌, E.Evi Tselenti‌, T.Theodore Aouad‌​‌, C.Clementina López-Medina​​, A.Antoine Feydy​​​‌, H.Hugues Talbot‌, B.Bengt Hoepken‌​‌, N.Natasha de​​ Peyrecave and M.Maxime​​​‌ Dougados. Performance analysis‌ of a deep-learning algorithm‌​‌ to detect the presence​​ of inflammation in MRI​​​‌ of sacroiliac joints in‌ patients with axial spondyloarthritis‌​‌.Annals of the​​ Rheumatic DiseasesJanuary 2025​​​‌HALDOIback to‌ text
• 24 articleN.‌​‌Nora Ouzir, V.​​Vassili Pustovalov, D.-H.​​​‌Duong-Hung Pham, D.‌Denis Kouamé and J.-C.‌​‌Jean-Christophe Pesquet. A​​ Proximal Algorithm for Joint​​​‌ Blood Flow Computation and‌ Tissue Motion Compensation in‌​‌ Doppler Ultrafast Ultrasound Imaging​​.Ultrasonics2025.​​​‌ In press. HALback‌ to textback to‌​‌ textback to text​​
• 25 articleB.Barbara​​​‌ Pistilli, F.Fernanda‌ Mosele, N.Noemie‌​‌ Corcos, L.Livia​​ Pierotti, Y.Yoann​​​‌ Pradat, L.Loïc‌ Le Bescond, M.‌​‌Magali Lacroix-Triki, G.​​Ghada Nachabeh, A.​​​‌Alexia Alfaro, C.‌Cyril Catelain, B.‌​‌Bastien Job, F.​​Fathia Mami-Chouaib, S.​​​‌Severine Badel, F.‌Françoise Farace, M.‌​‌Marianne Oulhen, P.​​Patricia Kannouche, D.​​​‌ T.Diep T N‌ Tran, N.Nathalie‌​‌ Droin, C.Cecile​​ Vicier, J. S.​​​‌Jean Sebastien Frenel,‌ V.Veronique D’hondt,‌​‌ F.Florence Dalenc,​​ T.Thomas Bachelot,​​​‌ A.Agnes Ducoulombier,‌ M. A.Marc Antoine‌​‌ Benderra, D.Delphine​​​‌ Loirat, D.Didier​ Mayeur, E.Elise​‌ Deluche, J.Jacqueline​​ Deneuve, R.Rasha​​​‌ Cheikh-Hussin, P.Pierre​ Guyader, N.Nicolas​‌ Signolle, K.Karine​​ Godefroy, H.Hugues​​​‌ Talbot, M.Maria​ Vakalopoulou, S.Stergios​‌ Christodoulidis, E.Elsa​​ Bernard, Y.Yves​​​‌ Koudou, A.Andrea​ Sporchia, F.Fumitaka​‌ Suto, L.Lie​​ Li, D. W.​​​‌David W Sternberg,​ S.Stefan Michiels,​‌ F.Fabrice André,​​ D.Dalila Sellami and​​​‌ G.Guillaume Montagnac.​ Patritumab deruxtecan in HR+HER2−​‌ advanced breast cancer: a​​ phase 2 trial.​​​‌Nature MedicineSeptember 2025​, Online ahead of​‌ printHALDOIback​​ to text
• 26 article​​​‌A. S.Amadou S.​ Sangare, N.Nicolas​‌ Dunou, J. H.​​Jhony H. Giraldo and​​​‌ F. D.Fragkiskos D.​ Malliaros. A Fused​‌ Gromov-Wasserstein Approach to Subgraph​​ Contrastive Learning.Transactions​​​‌ on Machine Learning Research​ JournalFebruary 2025HAL​‌back to textback​​ to text
• 27 article​​​‌A.Antoine Siraudin,​ F.Fragkiskos Malliaros and​‌ C.Christopher Morris.​​ Cometh: A continuous-time discrete-state​​​‌ graph diffusion model.​Transactions of Machine Learning​‌ ResearchApril 2025HAL​​back to textback​​​‌ to text
• 28 article​M.Mathieu Vu,​‌ E.Emilie Chouzenoux,​​ I. B.Ismail Ben​​​‌ Ayed and J.-C.Jean-Christophe​ Pesquet. Aggregated f​‌ -average Neural Network applied​​ to Few-Shot Class Incremental​​​‌ Learning.Signal Processing​January 2025HALback​‌ to text

International peer-reviewed​​ conferences

• 29 inproceedingsY.​​​‌Yassine Abbahaddou, F.​ D.Fragkiskos D. Malliaros​‌, J. F.Johannes​​ F. Lutzeyer, A.​​​‌ M.Amine Mohamed Aboussalah​ and M.Michalis Vazirgiannis​‌. Graph Neural Network​​ Generalization with Gaussian Mixture​​​‌ Model Based Augmentation.​Proceedings of the 42​‌ nd International Conference on​​ Machine Learning, Vancouver, Canada.​​​‌ PMLR 267, 2025.ICML​ 2025 - 42nd International​‌ Conference on Machine Learning​​Vancoucer, Canada2025HAL​​​‌back to textback​ to text
• 30 inproceedings​‌Y.Yassine Abbahaddou,​​ F. D.Fragkiskos D.​​​‌ Malliaros, J. F.​Johannes F. Lutzeyer and​‌ M.Michalis Vazirgiannis.​​ ADMP-GNN: Adaptive Depth Message​​​‌ Passing GNN.CIKM​ 2025 - ACM International​‌ Conference on Information and​​ Knowledge ManagementSeoul, South​​​‌ Korea2025, 4​ - 13HALDOI​‌back to textback​​ to text
• 31 inproceedings​​​‌M.Miguel Amorim,​ J.-C.Jean-Christophe Pesquet,​‌ T.Tristan Portugues,​​ A.Antonio Silveti-Falls and​​​‌ H.Hugues Talbot.​ Numerical Implementation of Variational​‌ Morphological Operators on Graphs​​.DGMM 2025 -​​​‌ 4th International Conference on​ Discrete Geometry and Mathematical​‌ MorphologyGroningen, Netherlands, Netherlands​​November 2025HALback​​​‌ to text
• 32 inproceedings​H.Hugo Attali,​‌ T.Thomas Papastergiou,​​ N.Nathalie Pernelle and​​​‌ F. D.Fragkiskos D​ Malliaros. Dynamic Triangulation-Based​‌ Graph Rewiring for Graph​​ Neural Networks.CIKM​​​‌ 2025 - ACM International​ Conference on Information and​‌ Knowledge ManagementSeoul, South​​ KoreaAugust 2025,​​​‌ 87-97HALDOIback​ to textback to​‌ text
• 33 inproceedingsG.​​Gaspard Blaise, C.​​Clément Cosserat, E.​​​‌Emilie Chouzenoux, J.-C.‌Jean-Christophe Pesquet and T.‌​‌Tülay Adali. Deep​​ Unrolled Architecture for Fast​​​‌ and Accurate Gaussian Independent‌ Vector Analysis.SSP‌​‌ 2025 - IEEE Statistical​​ Signal Processing WorkshopEdimbourg​​​‌ (Ecosse), United KingdomJune‌ 2025HALback to‌​‌ text
• 34 inproceedingsC.​​Clément Cosserat, L.​​​‌Lucas Gois, E.‌Emilie Chouzenoux, V.‌​‌Vince Calhoun and T.​​Tülay Adali. How​​​‌ important are inter-dataset interactions‌ for large scale analysis‌​‌ of fMRI data: A​​ multi-dimensional comparison.Proceedings​​​‌ of IEEE International Symposium‌ on Biomedical ImagingISBI‌​‌ 2026 - IEEE International​​ Symposium on Biomedical Imaging​​​‌London, United KingdomApril‌ 2026HALback to‌​‌ textback to text​​
• 35 inproceedingsB.Benjamin​​​‌ Cox, E.Emilie‌ Chouzenoux and V.Víctor‌​‌ Elvira. Learning a​​ sparse polynomial approximation to​​​‌ the transition function of‌ general state-space models.‌​‌Proceedings of the IEEE​​ International Conference on Acoustics,​​​‌ Speech and Signal Processing‌ (ICASSP 2025)ICASSP 2025‌​‌ - IEEE International Conference​​ on Acoustics, Speech and​​​‌ Signal ProcessingHyderabad, India‌April 2025HALback‌​‌ to textback to​​ text
• 36 inproceedingsA.​​​‌Aref Einizade, D.‌Dorina Thanou, F.‌​‌ D.Fragkiskos D Malliaros​​ and J. H.Jhony​​​‌ Heriberto Giraldo Zuluaga.‌ Continuous Simplicial Neural Networks‌​‌.NeurIPS 2025 -​​ 39th Annual Conference on​​​‌ Neural Information Processing Systems‌San Diego, United States‌​‌December 2025HALback​​ to textback to​​​‌ text
• 37 inproceedingsH.‌Hafsa El Herichi,‌​‌ A.Arturo Mendoza,​​ Y.Yanneck Wielhorski,​​​‌ H.Hugues Talbot and‌ S.Stéphane Roux.‌​‌ Analyse de forme a​​ priori pour la segmentation​​​‌ des torons dans les‌ images tomographiques.Journées‌​‌ Nationales sur les Composites​​ 2025Gif-sur-Yvette, FranceJune​​​‌ 2025HALback to‌ text
• 38 inproceedings D.‌​‌Daniele Malitesta, G.​​Giacomo Medda, E.​​​‌Erasmo Purificato, M.‌Mirko Marras, F.‌​‌ D.Fragkiskos D. Malliaros​​ and L.Ludovico Boratto​​​‌. How Fair is‌ Your Diffusion Recommender Model?‌​‌ RecSys '25: Proceedings of​​ the Nineteenth ACM Conference​​​‌ on Recommender Systems RecSys‌ 2025 - 19th ACM‌​‌ Conference on Recommender Systems​​ Prague, Czech Republic September​​​‌ 2025 HAL back to‌ text back to text‌​‌
• 39 inproceedingsN.Nabil​​ Mouadden, O.Othmane​​​‌ Laousy, R.Rafael‌ Marini, V.Valentin‌​‌ Ong, M.-P.Marie-Pierre​​ Revel, G.Guillaume​​​‌ Chassagnon, S.Stergios‌ Christodoulidis and M.Maria‌​‌ Vakalopoulou. Conditional Latent​​ Diffusion Models for Irregularly​​​‌ Spaced Longitudinal Radiological Data‌.Medical Image Computing‌​‌ and Computer Assisted Intervention​​ – MICCAI 202515974​​​‌Lecture Notes in Computer‌ ScienceLNCS-15974Daejeon, South‌​‌ KoreaSpringer Nature Switzerland​​September 2026, 106-115​​​‌HALDOIback to‌ text
• 40 inproceedingsT.‌​‌Thomas Pethick, W.​​Wanyun Xie, K.​​​‌Kimon Antonakopoulos, Z.‌Zhenyu Zhu, A.‌​‌Antonio Silveti-Falls and V.​​Volkan Cevher. Training​​​‌ Deep Learning Models with‌ Norm-Constrained LMOs.42nd‌​‌ International Conference on Machine​​ LearningVancouver, CanadaJuly​​​‌ 2025HALback to‌ textback to text‌​‌back to text
• 41​​​‌ inproceedingsT.Thomas Pethick​, W.Wanyun Xie​‌, M.Mete Erdogan​​, K.Kimon Antonakopoulos​​​‌, T.Tony Silveti-Falls​ and V.Volkan Cevher​‌. Generalized Gradient Norm​​ Clipping & Non-Euclidean (L​​​‌ 0 , L 1​ )-Smoothness.NeurIPS 2025​‌ - 39th Conference on​​ Neural Information Processing Systems​​​‌San Diego (CA), United​ StatesDecember 2025HAL​‌back to textback​​ to textback to​​​‌ text
• 42 inproceedingsD.​David Restrepo, I.​‌Ira Ktena, M.​​Maria Vakalopoulou, S.​​​‌Stergios Christodoulidis and E.​Enzo Ferrante. On​‌ the Risk of Misleading​​ Reports: Diagnosing Textual Biases​​​‌ in Multimodal Clinical AI​.AI for Clinical​‌ Applications. Agentic AI16147​​Lecture Notes in Computer​​​‌ ScienceDaejean, South Korea​Springer Nature SwitzerlandSeptember​‌ 2026, 320-330HAL​​DOIback to text​​​‌
• 43 inproceedingsT.Théo​ Sourget, D.David​‌ Restrepo, C.Céline​​ Hudelot, E.Enzo​​​‌ Ferrante, S.Stergios​ Christodoulidis and M.Maria​‌ Vakalopoulou. Fairness and​​ Robustness of CLIP-Based Models​​​‌ for Chest X-Rays.​Fairness of AI in​‌ Medical Imaging. FAIMI 2025​​15976Lecture Notes in​​​‌ Computer ScienceDaejean, South​ KoreaSpringer Nature Switzerland​‌September 2026, 11-21​​HALDOIback to​​​‌ textback to text​
• 44 inproceedingsM.Mingbo​‌ Su, Y.Yi​​ Zhang, M.Mounir​​​‌ Kaaniche, C.Congcong​ Wang and M.Meng​‌ Zhao. SR-MedTS: A​​ Semantically-Robust Synergistic Framework for​​​‌ multi-modal Medical Image Translation​ and Segmentation.BIBM​‌ 2025 - International Conference​​ on Bioinformatics and Biomedicine​​​‌Wuhan, ChinaDecember 2025​HAL
• 45 inproceedingsK.​‌Kazuki Suehara, Y.​​Yi Gu, Y.​​​‌Yoshito Otake, K.​Keisuke Uemura, M.​‌Masashi Okamoto, K.​​Kunihiko Tokunaga, H.​​​‌Hugues Talbot and Y.​Yoshinobu Sato. Estimating​‌ Bone Mineral Density and​​ Muscle Mass from EOS​​​‌ Low Dose X-Ray Imaging​ System.Lecture Notes​‌ in Computer Science (LNCS,​​ volume 15970)Medical Image​​​‌ Computing and Computer Assisted​ Intervention (MICCAI)15970Lecture​‌ Notes in Computer Science​​Daejong, South KoreaSpringer​​​‌ Nature SwitzerlandSeptember 2026​, 168-177HALDOI​‌back to text
• 46​​ inproceedingsL.Long Zhou​​​‌, F.Fereshteh Shakeri​, A.Aymen Sadraoui​‌, M.Mounir Kaaniche​​, J.-C.Jean-Christophe Pesquet​​​‌ and I. B.Ismail​ Ben Ayed. UNEM:​‌ UNrolled Generalized EM for​​ Transductive Few-Shot Learning.​​​‌CVPR 2025 - Computer​ Vision and Pattern Recognition​‌ ConferenceNashville (Tenessee), United​​ StatesJune 2025HAL​​​‌back to text

Conferences​ without proceedings

• 47 inproceedings​‌M.Malik Nafa,​​ L.Ludovic Trautmann,​​​‌ U.Ugo Arles Bottega​, T.Tigran Mansuryan​‌, A.Alessandro Tonello​​, L.Lionel Rechignat​​​‌, M.Marc Fabert​, L.Laetitia Magnol​‌, V.Véronique Blanquet​​, F.Fabienne Baraige​​​‌, V.Vincent Couderc​, C.Claire Carrion​‌, J.-R.Jean-René Duclère​​ and C.Claire Lefort​​​‌. Imagerie CARS multiplexée​ pour la discrimination sans​‌ marquage des protéines musculaires​​.IMOTOP 2025 -​​​‌ Imagerie et résolution ultime​Villneuve d'Ascq, FranceOctober​‌ 2025HAL

Reports &​​ preprints

• 48 miscA.​​Abbas Khademi and A.​​​‌Antonio Silveti-Falls. Adaptive‌ Conditional Gradient Descent.‌​‌October 2025HAL
• 49​​ miscL.Loïc Le​​​‌ Bescond, M.Marvin‌ Lerousseau, F.Fabrice‌​‌ Andre and H.Hugues​​ Talbot. SparseXMIL: Leveraging​​​‌ sparse convolutions for context-aware‌ and memory-efficient classification of‌​‌ whole slide images in​​ digital pathology.January​​​‌ 2025HALback to‌ text
• 50 miscS.‌​‌Solal Martin, E.​​Emilie Chouzenoux and V.​​​‌Víctor Elvira. A‌ novel sequential method for‌​‌ building upper and lower​​ bounds of moments of​​​‌ distributions.December 2025‌, 41 p.HAL‌​‌
• 51 miscT.Thomas​​ Pethick, K.Kimon​​​‌ Antonakopoulos, A.Antonio‌ Silveti-Falls, L. C.‌​‌Leena Chennuru Vankadara and​​ V.Volkan Cevher.​​​‌ Training Neural Networks at‌ Any Scale.December‌​‌ 2025HALback to​​ text
• 52 miscN.​​​‌Nicolas Salvy, H.‌Hugues Talbot and B.‌​‌Bertrand Thirion. Enhanced​​ generative model evaluation with​​​‌ Clipped Density and Coverage‌.July 2025HAL‌​‌back to text
• 53​​ miscF.Francesco Songia​​​‌, R.Raoul Sallé‌ de Chou, H.‌​‌Hugues Talbot and I.​​Irene Vignon-Clementel. Multi-fidelity​​​‌ graph-based neural networks architectures‌ to learn Navier-Stokes solutions‌​‌ on non-parametrized 2D domains​​.December 2025HAL​​​‌