Method of characterizing molecular diffusion within a body from a set of diffusion-weighted magnetic resonance signals and apparatus for carrying out such a method

The invention claimed is: 1. A diffusion-weighted magnetic resonance apparatus comprising: at least a magnet for generating a static magnetic field, called longitudinal magnetic field, uniform within a volume of interest; at least a magnetic field gradient generator, for generating magnetic field gradients along a plurality of directions within said volume of interest; at least a radio-frequency pulse generator for emitting radio-frequency pulses within said volume of interest; at least a radio-frequency receiver for acquiring magnetic-resonance signals emitted by a body inside said volume of interest; at least one processor; one or more computers and/or electronic circuits comprising the at least one processor; and a non-transitory computer-implemented program embodied on a computer readable medium configured to be executed on the at least one processor such that: the at least one processor is configured for controlling said or each said magnetic field gradient generator, radio-frequency pulse generator and radio-frequency receiver and for processing said magnetic-resonance signals; the at least one processor is configured to control said or each said magnetic field gradient generator, radio-frequency pulse generator and radio-frequency receiver to expose a body situated within said volume of interest to a magnetic resonance imaging process, wherein a plurality of magnetic gradients are applied to said body and, for each said magnetic gradient, acquiring a plurality of diffusion-weighted magnetic resonance signals for a plurality of voxels; the at least one processor is configured to fit a plurality of nested multi-compartment diffusion models with an increasing number of compartments to said magnetic resonance signals, each said model being associated to a respective diffusion profile; the at least one processor is configured to compute a weight, representative of a performance criterion, for each of said models; the at least one processor is configured to convert said models into respective extended models having a same number of compartments by replicating each compartment of each model a predetermined number of times; the at least one processor is configured to determine an averaged model by computing said weighted average of said extended models using the corresponding computed weights; the at least one processor is configured to fit a plurality of nested multi-compartment diffusion models with an increasing number of compartments to said signals, each said model being associated to a respective diffusion profile; the at least one processor is configured to compute a weight, representative of a performance criterion, for each of said models; the at least one processor is configured to convert said models into respective extended models having a same number of compartments by replicating each compartment of each model a predetermined number of times; the at least one processor is configured to determine an averaged model by computing said weighted average of said extended models using corresponding computed weights; and the at least one processor is configured to determine a voxel-dependent water diffusion profile within the biological tissue from the weighted average of a plurality of multi-compartment diffusion models. 2. A non-transitory computer-implemented program embodied on a computer readable medium configured to be executed on at least one processor to perform a method of characterizing water diffusion within biological tissue from a set of diffusion-weighted magnetic resonance signals, the method comprising: a preliminary step of exposing a body to a magnetic resonance imaging process, wherein a plurality of magnetic gradients from at least a magnetic field gradient generator are applied to said body and, for each said magnetic gradient, a set of diffusion-weighted magnetic resonance signals is acquired for a plurality of voxels; computing with at least one processor a weighted average of a plurality of multi-compartment diffusion models comprising a same number of compartments, fitted to the set of diffusion-weighted magnetic resonance signals, said weighted average being computed with the at least one processor using weights representative of a performance criterion of each of said models; the method further comprising: a) fitting with the at least one processor a plurality of nested multi-compartment diffusion models with an increasing number of compartments to said signals, each said model being associated to a respective diffusion profile; b) computing with the at least one processor a weight, representative of a performance criterion, for each of said models; c) converting with the at least one processor said models into respective extended models having a same number of compartments by replicating each compartment of each model a predetermined number of times; and d) determining with the at least one processor an averaged model by computing said weighted average of said extended models using the corresponding weights computed at step b), and determining with the at least one processor a voxel-dependent water diffusion profile within the biological tissue from the weighted average of a plurality of multi-compartment diffusion models, wherein each of said multi-compartment diffusion models comprises a different number of subsets of compartments. 3. The non-transitory computer-implemented program of claim 2 , wherein said step a) comprises fitting L+1 nested multi-compartment diffusion models having n l compartments respectively, l∈[0, L] being a model index, with n i <n j for i<j. 4. The non-transitory computer-implemented program of claim 3 wherein, for each l∈[0, L], n i =l. 5. The non-transitory computer-implemented program of claim 4 wherein each said extended model has exactly L! compartments identified by labels k∈[0, L!] given by: k = ( m - 1 ) ⁢ L ! ( l - 1 ) ! + ( j - 1 ) ⁢ L ! l ! + p with p ∈ [ 1 , L ! l ! ]