ARAMIS - 2017 - Annual activity report

ARAMIS

ARAMIS - 2017

Project-Team Aramis

Personnel

Overall Objectives

Research Program

Application Domains

Highlights of the Year

New Software and Platforms

New Results

Fiberprint: A subject fingerprint based on sparse code pooling for white matter fiber analysis
Individual analysis of molecular brain imaging data through automatic identification of abnormality patterns
Multilevel Modeling with Structured Penalties for Classification from Imaging Genetics data
Towards Fully-reproducible Research on Classification of Alzheimer's Disease
Early Cognitive, Structural, and Microstructural Changes in Presymptomatic C9orf72 Carriers Younger Than 40 Years
Loss of brain inter-frequency hubs in Alzheimer's disease
A statistical model for brain networks inferred from large-scale electrophysiological signals
A Topological Criterion for Filtering Information in Complex Brain Networks
Preclinical Alzheimer’s disease: a systematic review of the cohorts underlying the concept
Free and Cued Selective Reminding Test - accuracy for the differential diagnosis of Alzheimer's and neurodegenerative diseases: A large-scale biomarker-characterized monocenter cohort study (ClinAD)
Parallel transport in shape analysis : a scalable numerical scheme
Statistical learning of spatiotemporal patterns from longitudinal manifold-valued networks
Prediction of the progression of subcortical brain structures in Alzheimer's disease from baseline
Prediction of amyloidosis from neuropsychological and MRI data for cost effective inclusion of pre-symptomatic subjects in clinical trials
Geodesic shape regression with multiple geometries and sparse parameters
A sub-Riemannian modular framework for diffeomorphism based analysis of shape ensembles
A Bayesian Framework for Joint Morphometry of Surface and Curve meshes in Multi-Object Complexes
A Bayesian mixed-effects model to learn trajectories of changes from repeated manifold-valued observations

Bilateral Contracts and Grants with Industry

Partnerships and Cooperations

Dissemination

Bibliography

Publications of the year

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Section: New Results

A Bayesian mixed-effects model to learn trajectories of changes from repeated manifold-valued observations

Participants : Jean-Baptiste Schiratti, Stéphanie Allassonnière, Olivier Colliot, Stanley Durrleman.

We propose a generic Bayesian mixed-effects model to estimate the temporal progression of a biological phenomenon from observations obtained at multiple time points for a group of individuals. The progression is modeled by continuous trajectories in the space of measurements. Individual trajectories of progression result from spatiotemporal transformations of an average trajectory. These transformations allow to quantify the changes in direction and pace at which the trajectories are followed. The framework of Rieman-nian geometry allows the model to be used with any kind of measurements with smooth constraints. A stochastic version of the Expectation-Maximization algorithm is used to produce produce maximum a posteriori estimates of the parameters. We evaluate our method using series of neuropsychological test scores from patients with mild cognitive impairments later diagnosed with Alzheimer's disease, and simulated evolutions of symmetric positive definite matrices. The data-driven model of the impairment of cognitive functions shows the variability in the ordering and timing of the decline of these functions in the population. We show also that the estimated spatiotemporal transformations effectively put into correspondence significant events in the progression of individuals.

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