Exemplo n.º 1
0
def track_ensemble(target_samples,
                   atlas_data_wm_gm_int,
                   parcels,
                   mod_fit,
                   tiss_classifier,
                   sphere,
                   directget,
                   curv_thr_list,
                   step_list,
                   track_type,
                   maxcrossing,
                   max_length,
                   n_seeds_per_iter=200,
                   pft_back_tracking_dist=2,
                   pft_front_tracking_dist=1,
                   particle_count=15,
                   roi_neighborhood_tol=8):
    """
    Perform native-space ensemble tractography, restricted to a vector of ROI masks.

    target_samples : int
        Total number of streamline samples specified to generate streams.
    atlas_data_wm_gm_int : array
        3D int32 numpy array of atlas parcellation intensities from Nifti1Image in T1w-warped native diffusion space,
        restricted to wm-gm interface.
    parcels : list
        List of 3D boolean numpy arrays of atlas parcellation ROI masks from a Nifti1Image in T1w-warped native
        diffusion space.
    mod : obj
        Connectivity reconstruction model.
    tiss_classifier : str
        Tissue classification method.
    sphere : obj
        DiPy object for modeling diffusion directions on a sphere.
    directget : str
        The statistical approach to tracking. Options are: det (deterministic), closest (clos), boot (bootstrapped),
        and prob (probabilistic).
    curv_thr_list : list
        List of integer curvature thresholds used to perform ensemble tracking.
    step_list : list
        List of float step-sizes used to perform ensemble tracking.
    track_type : str
        Tracking algorithm used (e.g. 'local' or 'particle').
    maxcrossing : int
        Maximum number if diffusion directions that can be assumed per voxel while tracking.
    max_length : int
        Maximum fiber length threshold in mm to restrict tracking.
    n_seeds_per_iter : int
        Number of seeds from which to initiate tracking for each unique ensemble combination.
        By default this is set to 200.
    particle_count
        pft_back_tracking_dist : float
        Distance in mm to back track before starting the particle filtering
        tractography. The total particle filtering tractography distance is
        equal to back_tracking_dist + front_tracking_dist. By default this is set to 2 mm.
    pft_front_tracking_dist : float
        Distance in mm to run the particle filtering tractography after the
        the back track distance. The total particle filtering tractography
        distance is equal to back_tracking_dist + front_tracking_dist. By
        default this is set to 1 mm.
    particle_count : int
        Number of particles to use in the particle filter.
    roi_neighborhood_tol : float
        Distance (in the units of the streamlines, usually mm). If any
        coordinate in the streamline is within this distance from the center
        of any voxel in the ROI, the filtering criterion is set to True for
        this streamline, otherwise False. Defaults to the distance between
        the center of each voxel and the corner of the voxel.

    Returns
    -------
    streamlines : ArraySequence
        DiPy list/array-like object of streamline points from tractography.
    """
    from colorama import Fore, Style
    from dipy.tracking import utils
    from dipy.tracking.streamline import Streamlines, select_by_rois
    from dipy.tracking.local import LocalTracking, ParticleFilteringTracking
    from dipy.direction import ProbabilisticDirectionGetter, BootDirectionGetter, ClosestPeakDirectionGetter, DeterministicMaximumDirectionGetter

    # Commence Ensemble Tractography
    parcel_vec = np.ones(len(parcels)).astype('bool')
    streamlines = nib.streamlines.array_sequence.ArraySequence()
    ix = 0
    circuit_ix = 0
    stream_counter = 0
    while int(stream_counter) < int(target_samples):
        for curv_thr in curv_thr_list:
            print("%s%s" % ('Curvature: ', curv_thr))

            # Instantiate DirectionGetter
            if directget == 'prob':
                dg = ProbabilisticDirectionGetter.from_shcoeff(
                    mod_fit, max_angle=float(curv_thr), sphere=sphere)
            elif directget == 'boot':
                dg = BootDirectionGetter.from_shcoeff(
                    mod_fit, max_angle=float(curv_thr), sphere=sphere)
            elif directget == 'clos':
                dg = ClosestPeakDirectionGetter.from_shcoeff(
                    mod_fit, max_angle=float(curv_thr), sphere=sphere)
            elif directget == 'det':
                dg = DeterministicMaximumDirectionGetter.from_shcoeff(
                    mod_fit, max_angle=float(curv_thr), sphere=sphere)
            else:
                raise ValueError(
                    'ERROR: No valid direction getter(s) specified.')

            for step in step_list:
                print("%s%s" % ('Step: ', step))
                # Perform wm-gm interface seeding, using n_seeds at a time
                seeds = utils.random_seeds_from_mask(
                    atlas_data_wm_gm_int > 0,
                    seeds_count=n_seeds_per_iter,
                    seed_count_per_voxel=False,
                    affine=np.eye(4))
                if len(seeds) == 0:
                    raise RuntimeWarning(
                        'Warning: No valid seed points found in wm-gm interface...'
                    )

                print(seeds)
                # Perform tracking
                if track_type == 'local':
                    streamline_generator = LocalTracking(
                        dg,
                        tiss_classifier,
                        seeds,
                        np.eye(4),
                        max_cross=int(maxcrossing),
                        maxlen=int(max_length),
                        step_size=float(step),
                        return_all=True)
                elif track_type == 'particle':
                    streamline_generator = ParticleFilteringTracking(
                        dg,
                        tiss_classifier,
                        seeds,
                        np.eye(4),
                        max_cross=int(maxcrossing),
                        step_size=float(step),
                        maxlen=int(max_length),
                        pft_back_tracking_dist=pft_back_tracking_dist,
                        pft_front_tracking_dist=pft_front_tracking_dist,
                        particle_count=particle_count,
                        return_all=True)
                else:
                    raise ValueError(
                        'ERROR: No valid tracking method(s) specified.')

                # Filter resulting streamlines by roi-intersection characteristics
                roi_proximal_streamlines = Streamlines(
                    select_by_rois(streamline_generator,
                                   parcels,
                                   parcel_vec,
                                   mode='any',
                                   affine=np.eye(4),
                                   tol=roi_neighborhood_tol))

                # Repeat process until target samples condition is met
                ix = ix + 1
                for s in roi_proximal_streamlines:
                    stream_counter = stream_counter + len(s)
                    streamlines.append(s)
                    if int(stream_counter) >= int(target_samples):
                        break
                    else:
                        continue

        circuit_ix = circuit_ix + 1
        print(
            "%s%s%s%s%s" %
            ('Completed hyperparameter circuit: ', circuit_ix,
             '...\nCumulative Streamline Count: ', Fore.CYAN, stream_counter))
        print(Style.RESET_ALL)

    print('\n')
    return streamlines
Exemplo n.º 2
0
def track_ensemble(target_samples, atlas_data_wm_gm_int, parcels, parcel_vec, mod_fit,
                   tiss_classifier, sphere, directget, curv_thr_list, step_list, track_type, maxcrossing, max_length,
                   n_seeds_per_iter=200):
    from colorama import Fore, Style
    from dipy.tracking import utils
    from dipy.tracking.streamline import Streamlines, select_by_rois
    from dipy.tracking.local import LocalTracking, ParticleFilteringTracking
    from dipy.direction import ProbabilisticDirectionGetter, BootDirectionGetter, ClosestPeakDirectionGetter, DeterministicMaximumDirectionGetter

    # Commence Ensemble Tractography
    streamlines = nib.streamlines.array_sequence.ArraySequence()
    ix = 0
    circuit_ix = 0
    stream_counter = 0
    while int(stream_counter) < int(target_samples):
        for curv_thr in curv_thr_list:
            print("%s%s" % ('Curvature: ', curv_thr))

            # Instantiate DirectionGetter
            if directget == 'prob':
                dg = ProbabilisticDirectionGetter.from_shcoeff(mod_fit, max_angle=float(curv_thr),
                                                               sphere=sphere)
            elif directget == 'boot':
                dg = BootDirectionGetter.from_shcoeff(mod_fit, max_angle=float(curv_thr),
                                                      sphere=sphere)
            elif directget == 'closest':
                dg = ClosestPeakDirectionGetter.from_shcoeff(mod_fit, max_angle=float(curv_thr),
                                                             sphere=sphere)
            elif directget == 'det':
                dg = DeterministicMaximumDirectionGetter.from_shcoeff(mod_fit, max_angle=float(curv_thr),
                                                                      sphere=sphere)
            else:
                raise ValueError('ERROR: No valid direction getter(s) specified.')

            for step in step_list:
                print("%s%s" % ('Step: ', step))
                # Perform wm-gm interface seeding, using n_seeds at a time
                seeds = utils.random_seeds_from_mask(atlas_data_wm_gm_int > 0, seeds_count=n_seeds_per_iter,
                                                     seed_count_per_voxel=False, affine=np.eye(4))
                if len(seeds) == 0:
                    raise RuntimeWarning('Warning: No valid seed points found in wm-gm interface...')

                print(seeds)
                # Perform tracking
                if track_type == 'local':
                    streamline_generator = LocalTracking(dg, tiss_classifier, seeds, np.eye(4),
                                                         max_cross=int(maxcrossing), maxlen=int(max_length),
                                                         step_size=float(step), return_all=True)
                elif track_type == 'particle':
                    streamline_generator = ParticleFilteringTracking(dg, tiss_classifier, seeds, np.eye(4),
                                                                     max_cross=int(maxcrossing),
                                                                     step_size=float(step),
                                                                     maxlen=int(max_length),
                                                                     pft_back_tracking_dist=2,
                                                                     pft_front_tracking_dist=1,
                                                                     particle_count=15, return_all=True)
                else:
                    raise ValueError('ERROR: No valid tracking method(s) specified.')

                # Filter resulting streamlines by roi-intersection characteristics
                streamlines_more = Streamlines(select_by_rois(streamline_generator, parcels, parcel_vec.astype('bool'),
                                                              mode='any', affine=np.eye(4), tol=8))

                # Repeat process until target samples condition is met
                ix = ix + 1
                for s in streamlines_more:
                    stream_counter = stream_counter + len(s)
                    streamlines.append(s)
                    if int(stream_counter) >= int(target_samples):
                        break
                    else:
                        continue

        circuit_ix = circuit_ix + 1
        print("%s%s%s%s%s" % ('Completed hyperparameter circuit: ', circuit_ix, '...\nCumulative Streamline Count: ',
                              Fore.CYAN, stream_counter))
        print(Style.RESET_ALL)

    print('\n')
    return streamlines