API

Workflows

fMRIprep base processing workflows

fmriprep.workflows.base.init_fmriprep_wf(anat_only, aroma_melodic_dim, bold2t1w_dof, cifti_output, debug, dummy_scans, echo_idx, err_on_aroma_warn, fmap_bspline, fmap_demean, force_syn, freesurfer, fs_subjects_dir, hires, ignore, layout, longitudinal, low_mem, medial_surface_nan, omp_nthreads, output_dir, output_spaces, regressors_all_comps, regressors_dvars_th, regressors_fd_th, run_uuid, skull_strip_fixed_seed, skull_strip_template, subject_list, t2s_coreg, task_id, use_aroma, use_bbr, use_syn, work_dir)[source]

Build fMRIPrep’s pipeline.

This workflow organizes the execution of FMRIPREP, with a sub-workflow for each subject. If FreeSurfer’s recon-all is to be run, a corresponding folder is created and populated with any needed template subjects under the derivatives folder.

Workflow Graph
../_images/index-1.png

(Source code, png, svg, pdf)

Parameters
  • anat_only (bool) – Disable functional workflows

  • bold2t1w_dof (6, 9 or 12) – Degrees-of-freedom for BOLD-T1w registration

  • cifti_output (bool) – Generate bold CIFTI file in output spaces

  • debug (bool) – Enable debugging outputs

  • dummy_scans (int or None) – Number of volumes to consider as non steady state

  • echo_idx (int or None) – Index of echo to preprocess in multiecho BOLD series, or None to preprocess all

  • err_on_aroma_warn (bool) – Do not fail on ICA-AROMA errors

  • fmap_bspline (bool) – Experimental: Fit B-Spline field using least-squares

  • fmap_demean (bool) – Demean voxel-shift map during unwarp

  • force_syn (bool) – Temporary: Always run SyN-based SDC

  • freesurfer (bool) – Enable FreeSurfer surface reconstruction (may increase runtime)

  • hires (bool) – Enable sub-millimeter preprocessing in FreeSurfer

  • ignore (list) – Preprocessing steps to skip (may include “slicetiming”, “fieldmaps”)

  • layout (BIDSLayout object) – BIDS dataset layout

  • longitudinal (bool) – Treat multiple sessions as longitudinal (may increase runtime) See sub-workflows for specific differences

  • low_mem (bool) – Write uncompressed .nii files in some cases to reduce memory usage

  • medial_surface_nan (bool) – Replace medial wall values with NaNs on functional GIFTI files

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • output_dir (str) – Directory in which to save derivatives

  • output_spaces (OrderedDict) – Ordered dictionary where keys are TemplateFlow ID strings (e.g., MNI152Lin, MNI152NLin6Asym, MNI152NLin2009cAsym, or fsLR) strings designating nonstandard references (e.g., T1w or anat, sbref, run, etc.), or paths pointing to custom templates organized in a TemplateFlow-like structure. Values of the dictionary aggregate modifiers (e.g., the value for the key MNI152Lin could be {'resolution': 2} if one wants the resampling to be done on the 2mm resolution version of the selected template).

  • regressors_all_comps – Return all CompCor component time series instead of the top fraction

  • regressors_dvars_th – Criterion for flagging DVARS outliers

  • regressors_fd_th – Criterion for flagging framewise displacement outliers

  • run_uuid (str) – Unique identifier for execution instance

  • skull_strip_template (tuple) – Name of target template for brain extraction with ANTs’ antsBrainExtraction, and corresponding dictionary of output-space modifiers.

  • skull_strip_fixed_seed (bool) – Do not use a random seed for skull-stripping - will ensure run-to-run replicability when used with –omp-nthreads 1

  • subject_list (list) – List of subject labels

  • t2s_coreg (bool) – For multi-echo EPI, use the calculated T2*-map for T2*-driven coregistration

  • task_id (str or None) – Task ID of BOLD series to preprocess, or None to preprocess all

  • use_aroma (bool) – Perform ICA-AROMA on MNI-resampled functional series

  • use_bbr (bool or None) – Enable/disable boundary-based registration refinement. If None, test BBR result for distortion before accepting.

  • use_syn (bool) – Experimental: Enable ANTs SyN-based susceptibility distortion correction (SDC). If fieldmaps are present and enabled, this is not run, by default.

  • work_dir (str) – Directory in which to store workflow execution state and temporary files

fmriprep.workflows.base.init_single_subject_wf(anat_only, aroma_melodic_dim, bold2t1w_dof, cifti_output, debug, dummy_scans, echo_idx, err_on_aroma_warn, fmap_bspline, fmap_demean, force_syn, freesurfer, hires, ignore, layout, longitudinal, low_mem, medial_surface_nan, name, omp_nthreads, output_dir, output_spaces, reportlets_dir, regressors_all_comps, regressors_dvars_th, regressors_fd_th, skull_strip_fixed_seed, skull_strip_template, subject_id, t2s_coreg, task_id, use_aroma, use_bbr, use_syn)[source]

This workflow organizes the preprocessing pipeline for a single subject.

It collects and reports information about the subject, and prepares sub-workflows to perform anatomical and functional preprocessing. Anatomical preprocessing is performed in a single workflow, regardless of the number of sessions. Functional preprocessing is performed using a separate workflow for each individual BOLD series.

Workflow Graph
../_images/index-2.png

(Source code, png, svg, pdf)

Parameters
  • anat_only (bool) – Disable functional workflows

  • aroma_melodic_dim (int) – Maximum number of components identified by MELODIC within ICA-AROMA (default is -200, i.e., no limitation).

  • bold2t1w_dof (6, 9 or 12) – Degrees-of-freedom for BOLD-T1w registration

  • cifti_output (bool) – Generate bold CIFTI file in output spaces

  • debug (bool) – Enable debugging outputs

  • dummy_scans (int or None) – Number of volumes to consider as non steady state

  • echo_idx (int or None) – Index of echo to preprocess in multiecho BOLD series, or None to preprocess all

  • err_on_aroma_warn (bool) – Do not fail on ICA-AROMA errors

  • fmap_bspline (bool) – Experimental: Fit B-Spline field using least-squares

  • fmap_demean (bool) – Demean voxel-shift map during unwarp

  • force_syn (bool) – Temporary: Always run SyN-based SDC

  • freesurfer (bool) – Enable FreeSurfer surface reconstruction (may increase runtime)

  • hires (bool) – Enable sub-millimeter preprocessing in FreeSurfer

  • ignore (list) – Preprocessing steps to skip (may include “slicetiming”, “fieldmaps”)

  • layout (BIDSLayout object) – BIDS dataset layout

  • longitudinal (bool) – Treat multiple sessions as longitudinal (may increase runtime) See sub-workflows for specific differences

  • low_mem (bool) – Write uncompressed .nii files in some cases to reduce memory usage

  • medial_surface_nan (bool) – Replace medial wall values with NaNs on functional GIFTI files

  • name (str) – Name of workflow

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • output_dir (str) – Directory in which to save derivatives

  • output_spaces (OrderedDict) – Ordered dictionary where keys are TemplateFlow ID strings (e.g., MNI152Lin, MNI152NLin6Asym, MNI152NLin2009cAsym, or fsLR) strings designating nonstandard references (e.g., T1w or anat, sbref, run, etc.), or paths pointing to custom templates organized in a TemplateFlow-like structure. Values of the dictionary aggregate modifiers (e.g., the value for the key MNI152Lin could be {'resolution': 2} if one wants the resampling to be done on the 2mm resolution version of the selected template).

  • reportlets_dir (str) – Directory in which to save reportlets

  • regressors_all_comps – Return all CompCor component time series instead of the top fraction

  • regressors_fd_th – Criterion for flagging framewise displacement outliers

  • regressors_dvars_th – Criterion for flagging DVARS outliers

  • skull_strip_fixed_seed (bool) – Do not use a random seed for skull-stripping - will ensure run-to-run replicability when used with –omp-nthreads 1

  • skull_strip_template (tuple) – Name of target template for brain extraction with ANTs’ antsBrainExtraction, and corresponding dictionary of output-space modifiers.

  • subject_id (str) – List of subject labels

  • t2s_coreg (bool) – For multi-echo EPI, use the calculated T2*-map for T2*-driven coregistration

  • task_id (str or None) – Task ID of BOLD series to preprocess, or None to preprocess all

  • use_aroma (bool) – Perform ICA-AROMA on MNI-resampled functional series

  • use_bbr (bool or None) – Enable/disable boundary-based registration refinement. If None, test BBR result for distortion before accepting.

  • use_syn (bool) – Experimental: Enable ANTs SyN-based susceptibility distortion correction (SDC). If fieldmaps are present and enabled, this is not run, by default.

Inputs

subjects_dir (str) – FreeSurfer’s $SUBJECTS_DIR.

Anatomical reference preprocessing workflows

fmriprep.workflows.anatomical.init_anat_preproc_wf(bids_root, freesurfer, hires, longitudinal, omp_nthreads, output_dir, output_spaces, num_t1w, reportlets_dir, skull_strip_template, debug=False, name='anat_preproc_wf', skull_strip_fixed_seed=False)[source]

Stage the anatomical preprocessing steps of sMRIPrep.

This includes:

  • T1w reference: realigning and then averaging T1w images.

  • Brain extraction and INU (bias field) correction.

  • Brain tissue segmentation.

  • Spatial normalization to standard spaces.

  • Surface reconstruction with FreeSurfer.

Workflow Graph
../_images/index-3.png

(Source code, png, svg, pdf)

Parameters
  • bids_root (str) – Path of the input BIDS dataset root

  • debug (bool) – Enable debugging outputs

  • freesurfer (bool) – Enable FreeSurfer surface reconstruction (increases runtime by 6h, at the very least)

  • output_spaces (list) – List of spatial normalization targets. Some parts of pipeline will only be instantiated for some output spaces. Valid spaces:

    • Any template identifier from TemplateFlow

    • Path to a template folder organized following TemplateFlow’s conventions

  • hires (bool) – Enable sub-millimeter preprocessing in FreeSurfer

  • longitudinal (bool) – Create unbiased structural template, regardless of number of inputs (may increase runtime)

  • name (str, optional) – Workflow name (default: anat_preproc_wf)

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • output_dir (str) – Directory in which to save derivatives

  • reportlets_dir (str) – Directory in which to save reportlets

  • skull_strip_fixed_seed (bool) – Do not use a random seed for skull-stripping - will ensure run-to-run replicability when used with –omp-nthreads 1 (default: False).

  • skull_strip_template (tuple) – Name of ANTs skull-stripping template and specifications.

Inputs
  • t1w – List of T1-weighted structural images

  • t2w – List of T2-weighted structural images

  • flair – List of FLAIR images

  • subjects_dir – FreeSurfer SUBJECTS_DIR

Outputs
  • t1w_preproc – The T1w reference map, which is calculated as the average of bias-corrected and preprocessed T1w images, defining the anatomical space.

  • t1w_brain – Skull-stripped t1w_preproc

  • t1w_mask – Brain (binary) mask estimated by brain extraction.

  • t1w_dseg – Brain tissue segmentation of the preprocessed structural image, including gray-matter (GM), white-matter (WM) and cerebrospinal fluid (CSF).

  • t1w_tpms – List of tissue probability maps corresponding to t1w_dseg.

  • std_t1w – T1w reference resampled in one or more standard spaces.

  • std_mask – Mask of skull-stripped template, in MNI space

  • std_dseg – Segmentation, resampled into MNI space

  • std_tpms – List of tissue probability maps in MNI space

  • subjects_dir – FreeSurfer SUBJECTS_DIR

  • anat2std_xfm – Nonlinear spatial transform to resample imaging data given in anatomical space into standard space.

  • std2anat_xfm – Inverse transform of the above.

  • subject_id – FreeSurfer subject ID

  • t1w2fsnative_xfm – LTA-style affine matrix translating from T1w to FreeSurfer-conformed subject space

  • fsnative2t1w_xfm – LTA-style affine matrix translating from FreeSurfer-conformed subject space to T1w

  • surfaces – GIFTI surfaces (gray/white boundary, midthickness, pial, inflated)

See also

  • init_brain_extraction_wf()

  • init_surface_recon_wf()

Surface preprocessing

fMRIPrep uses FreeSurfer to reconstruct surfaces from T1w/T2w structural images.

fmriprep.workflows.anatomical.init_surface_recon_wf(omp_nthreads, hires, name='surface_recon_wf')[source]

Reconstruct anatomical surfaces using FreeSurfer’s recon-all.

Reconstruction is performed in three phases. The first phase initializes the subject with T1w and T2w (if available) structural images and performs basic reconstruction (autorecon1) with the exception of skull-stripping. For example, a subject with only one session with T1w and T2w images would be processed by the following command:

$ recon-all -sd <output dir>/freesurfer -subjid sub-<subject_label> \
    -i <bids-root>/sub-<subject_label>/anat/sub-<subject_label>_T1w.nii.gz \
    -T2 <bids-root>/sub-<subject_label>/anat/sub-<subject_label>_T2w.nii.gz \
    -autorecon1 \
    -noskullstrip

The second phase imports an externally computed skull-stripping mask. This workflow refines the external brainmask using the internal mask implicit the the FreeSurfer’s aseg.mgz segmentation, to reconcile ANTs’ and FreeSurfer’s brain masks.

First, the aseg.mgz mask from FreeSurfer is refined in two steps, using binary morphological operations:

  1. With a binary closing operation the sulci are included into the mask. This results in a smoother brain mask that does not exclude deep, wide sulci.

  2. Fill any holes (typically, there could be a hole next to the pineal gland and the corpora quadrigemina if the great cerebral brain is segmented out).

Second, the brain mask is grown, including pixels that have a high likelihood to the GM tissue distribution:

  1. Dilate and substract the brain mask, defining the region to search for candidate pixels that likely belong to cortical GM.

  2. Pixels found in the search region that are labeled as GM by ANTs (during antsBrainExtraction.sh) are directly added to the new mask.

  3. Otherwise, estimate GM tissue parameters locally in patches of ww size, and test the likelihood of the pixel to belong in the GM distribution.

This procedure is inspired on mindboggle’s solution to the problem: https://github.com/nipy/mindboggle/blob/7f91faaa7664d820fe12ccc52ebaf21d679795e2/mindboggle/guts/segment.py#L1660

The final phase resumes reconstruction, using the T2w image to assist in finding the pial surface, if available. See init_autorecon_resume_wf() for details.

Memory annotations for FreeSurfer are based off their documentation. They specify an allocation of 4GB per subject. Here we define 5GB to have a certain margin.

Workflow Graph
../_images/index-4.png

(Source code, png, svg, pdf)

Parameters
  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • hires (bool) – Enable sub-millimeter preprocessing in FreeSurfer

Inputs
  • t1w – List of T1-weighted structural images

  • t2w – List of T2-weighted structural images (only first used)

  • flair – List of FLAIR images

  • skullstripped_t1 – Skull-stripped T1-weighted image (or mask of image)

  • ants_segs – Brain tissue segmentation from ANTS antsBrainExtraction.sh

  • corrected_t1 – INU-corrected, merged T1-weighted image

  • subjects_dir – FreeSurfer SUBJECTS_DIR

  • subject_id – FreeSurfer subject ID

Outputs
  • subjects_dir – FreeSurfer SUBJECTS_DIR

  • subject_id – FreeSurfer subject ID

  • t1w2fsnative_xfm – LTA-style affine matrix translating from T1w to FreeSurfer-conformed subject space

  • fsnative2t1w_xfm – LTA-style affine matrix translating from FreeSurfer-conformed subject space to T1w

  • surfaces – GIFTI surfaces for gray/white matter boundary, pial surface, midthickness (or graymid) surface, and inflated surfaces

  • out_brainmask – Refined brainmask, derived from FreeSurfer’s aseg volume

  • out_aseg – FreeSurfer’s aseg segmentation, in native T1w space

  • out_aparc – FreeSurfer’s aparc+aseg segmentation, in native T1w space

See also

  • init_autorecon_resume_wf()

  • init_gifti_surface_wf()

fmriprep.workflows.anatomical.init_autorecon_resume_wf(omp_nthreads, name='autorecon_resume_wf')[source]

Resume recon-all execution, assuming the -autorecon1 stage has been completed.

In order to utilize resources efficiently, this is broken down into seven sub-stages; after the first stage, the second and third stages may be run simultaneously, and the fifth and sixth stages may be run simultaneously, if resources permit; the fourth stage must be run prior to the fifth and sixth, and the seventh must be run after:

$ recon-all -sd <output dir>/freesurfer -subjid sub-<subject_label> \
    -autorecon2-volonly
$ recon-all -sd <output dir>/freesurfer -subjid sub-<subject_label> \
    -autorecon-hemi lh -T2pial \
    -noparcstats -noparcstats2 -noparcstats3 -nohyporelabel -nobalabels
$ recon-all -sd <output dir>/freesurfer -subjid sub-<subject_label> \
    -autorecon-hemi rh -T2pial \
    -noparcstats -noparcstats2 -noparcstats3 -nohyporelabel -nobalabels
$ recon-all -sd <output dir>/freesurfer -subjid sub-<subject_label> \
    -cortribbon
$ recon-all -sd <output dir>/freesurfer -subjid sub-<subject_label> \
    -autorecon-hemi lh -nohyporelabel
$ recon-all -sd <output dir>/freesurfer -subjid sub-<subject_label> \
    -autorecon-hemi rh -nohyporelabel
$ recon-all -sd <output dir>/freesurfer -subjid sub-<subject_label> \
    -autorecon3

The parcellation statistics steps are excluded from the second and third stages, because they require calculation of the cortical ribbon volume (the fourth stage). Hypointensity relabeling is excluded from hemisphere-specific steps to avoid race conditions, as it is a volumetric operation.

Workflow Graph
../_images/index-5.png

(Source code, png, svg, pdf)

Inputs
  • subjects_dir – FreeSurfer SUBJECTS_DIR

  • subject_id – FreeSurfer subject ID

  • use_T2 – Refine pial surface using T2w image

  • use_FLAIR – Refine pial surface using FLAIR image

Outputs
  • subjects_dir – FreeSurfer SUBJECTS_DIR

  • subject_id – FreeSurfer subject ID

fmriprep.workflows.anatomical.init_gifti_surface_wf(name='gifti_surface_wf')[source]

Prepare GIFTI surfaces from a FreeSurfer subjects directory.

If midthickness (or graymid) surfaces do not exist, they are generated and saved to the subject directory as lh/rh.midthickness. These, along with the gray/white matter boundary (lh/rh.smoothwm), pial sufaces (lh/rh.pial) and inflated surfaces (lh/rh.inflated) are converted to GIFTI files. Additionally, the vertex coordinates are recentered to align with native T1w space.

Workflow Graph
../_images/index-6.png

(Source code, png, svg, pdf)

Inputs
  • subjects_dir – FreeSurfer SUBJECTS_DIR

  • subject_id – FreeSurfer subject ID

  • fsnative2t1w_xfm – LTA formatted affine transform file (inverse)

Outputs

surfaces – GIFTI surfaces for gray/white matter boundary, pial surface, midthickness (or graymid) surface, and inflated surfaces

Pre-processing fMRI - BOLD signal workflows

Orchestrating the BOLD-preprocessing workflow

fmriprep.workflows.bold.base.init_func_preproc_wf(aroma_melodic_dim, bold2t1w_dof, bold_file, cifti_output, debug, dummy_scans, err_on_aroma_warn, fmap_bspline, fmap_demean, force_syn, freesurfer, ignore, low_mem, medial_surface_nan, omp_nthreads, output_dir, output_spaces, regressors_all_comps, regressors_dvars_th, regressors_fd_th, reportlets_dir, t2s_coreg, use_aroma, use_bbr, use_syn, layout=None, num_bold=1)[source]

This workflow controls the functional preprocessing stages of fMRIPrep.

Workflow Graph
../_images/index-7.png

(Source code, png, svg, pdf)

Parameters
  • aroma_melodic_dim (int) – Maximum number of components identified by MELODIC within ICA-AROMA (default is -200, ie. no limitation).

  • bold2t1w_dof (6, 9 or 12) – Degrees-of-freedom for BOLD-T1w registration

  • bold_file (str) – BOLD series NIfTI file

  • cifti_output (bool) – Generate bold CIFTI file in output spaces

  • debug (bool) – Enable debugging outputs

  • dummy_scans (int or None) – Number of volumes to consider as non steady state

  • err_on_aroma_warn (bool) – Do not crash on ICA-AROMA errors

  • fmap_bspline (bool) – Experimental: Fit B-Spline field using least-squares

  • fmap_demean (bool) – Demean voxel-shift map during unwarp

  • force_syn (bool) – Temporary: Always run SyN-based SDC

  • freesurfer (bool) – Enable FreeSurfer functional registration (bbregister) and resampling BOLD series to FreeSurfer surface meshes.

  • ignore (list) – Preprocessing steps to skip (may include “slicetiming”, “fieldmaps”)

  • low_mem (bool) – Write uncompressed .nii files in some cases to reduce memory usage

  • medial_surface_nan (bool) – Replace medial wall values with NaNs on functional GIFTI files

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • output_dir (str) – Directory in which to save derivatives

  • output_spaces (OrderedDict) – Ordered dictionary where keys are TemplateFlow ID strings (e.g. MNI152Lin, MNI152NLin6Asym, MNI152NLin2009cAsym, or fsLR) strings designating nonstandard references (e.g. T1w or anat, sbref, run, etc.), or paths pointing to custom templates organized in a TemplateFlow-like structure. Values of the dictionary aggregate modifiers (e.g. the value for the key MNI152Lin could be {'resolution': 2} if one wants the resampling to be done on the 2mm resolution version of the selected template).

  • regressors_all_comps – Return all CompCor component time series instead of the top fraction

  • regressors_dvars_th – Criterion for flagging DVARS outliers

  • regressors_fd_th – Criterion for flagging framewise displacement outliers

  • reportlets_dir (str) – Absolute path of a directory in which reportlets will be temporarily stored

  • t2s_coreg (bool) – For multiecho EPI, use the calculated T2*-map for T2*-driven coregistration

  • use_aroma (bool) – Perform ICA-AROMA on MNI-resampled functional series

  • use_bbr (bool or None) – Enable/disable boundary-based registration refinement. If None, test BBR result for distortion before accepting. When using t2s_coreg, BBR will be enabled by default unless explicitly specified otherwise.

  • use_syn (bool) – Experimental: Enable ANTs SyN-based susceptibility distortion correction (SDC). If fieldmaps are present and enabled, this is not run, by default.

  • layout (BIDSLayout) – BIDSLayout structure to enable metadata retrieval

  • num_bold (int) – Total number of BOLD files that have been set for preprocessing (default is 1)

Inputs
  • bold_file – BOLD series NIfTI file

  • t1w_preproc – Bias-corrected structural template image

  • t1w_brain – Skull-stripped t1w_preproc

  • t1w_mask – Mask of the skull-stripped template image

  • t1w_dseg – Segmentation of preprocessed structural image, including gray-matter (GM), white-matter (WM) and cerebrospinal fluid (CSF)

  • t1w_asec – Segmentation of structural image, done with FreeSurfer.

  • t1w_aparc – Parcellation of structural image, done with FreeSurfer.

  • t1w_tpms – List of tissue probability maps in T1w space

  • template – Name of the template (parametric)

  • anat2std_xfm – ANTs-compatible affine-and-warp transform file (parametric)

  • std2anat_xfm – ANTs-compatible affine-and-warp transform file (inverse) (parametric)

  • joint_template – List of templates to target

  • joint_anat2std_xfm – List of transform files, collated with templates

  • joint_std2anat_xfm – List of inverse transform files, collated with templates

  • subjects_dir – FreeSurfer SUBJECTS_DIR

  • subject_id – FreeSurfer subject ID

  • t1w2fsnative_xfm – LTA-style affine matrix translating from T1w to FreeSurfer-conformed subject space

  • fsnative2t1w_xfm – LTA-style affine matrix translating from FreeSurfer-conformed subject space to T1w

Outputs
  • bold_t1 – BOLD series, resampled to T1w space

  • bold_mask_t1 – BOLD series mask in T1w space

  • bold_std – BOLD series, resampled to template space

  • bold_mask_std – BOLD series mask in template space

  • confounds – TSV of confounds

  • surfaces – BOLD series, resampled to FreeSurfer surfaces

  • aroma_noise_ics – Noise components identified by ICA-AROMA

  • melodic_mix – FSL MELODIC mixing matrix

  • bold_cifti – BOLD CIFTI image

  • cifti_variant – combination of target spaces for bold_cifti

fmriprep.workflows.bold.base.init_func_derivatives_wf(bids_root, cifti_output, freesurfer, metadata, output_dir, output_spaces, standard_spaces, use_aroma, name='func_derivatives_wf')[source]

Set up a battery of datasinks to store derivatives in the right location.

Parameters
  • bids_root (str) – Original BIDS dataset path.

  • cifti_output (bool) – Whether the --cifti-output flag was set.

  • freesurfer (bool) – Whether FreeSurfer anatomical processing was run.

  • metadata (dict) – Metadata dictionary associated to the BOLD run.

  • output_dir (str) – Where derivatives should be written out to.

  • output_spaces (OrderedDict) – List of selected --output-spaces.

  • use_aroma (bool) – Whether --use-aroma flag was set.

  • name (str) – This workflow’s identifier (default: func_derivatives_wf).

Utility workflows

fmriprep.workflows.bold.util.init_bold_reference_wf(omp_nthreads, bold_file=None, pre_mask=False, name='bold_reference_wf', gen_report=False)[source]

Build a workflow that generates reference BOLD images for a series.

The raw reference image is the target of HMC, and a contrast-enhanced reference is the subject of distortion correction, as well as boundary-based registration to T1w and template spaces.

Workflow Graph
../_images/index-8.png

(Source code, png, svg, pdf)

Parameters
  • bold_file (str) – BOLD series NIfTI file

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • name (str) – Name of workflow (default: bold_reference_wf)

  • gen_report (bool) – Whether a mask report node should be appended in the end

Inputs
  • bold_file (str) – BOLD series NIfTI file

  • bold_mask (bool) – A tentative brain mask to initialize the workflow (requires pre_mask parameter set True).

  • dummy_scans (int or None) – Number of non-steady-state volumes specified by user at beginning of bold_file

  • sbref_file (str) – single band (as opposed to multi band) reference NIfTI file

Outputs
  • bold_file (str) – Validated BOLD series NIfTI file

  • raw_ref_image (str) – Reference image to which BOLD series is motion corrected

  • skip_vols (int) – Number of non-steady-state volumes selected at beginning of bold_file

  • algo_dummy_scans (int) – Number of non-steady-state volumes agorithmically detected at beginning of bold_file

  • ref_image (str) – Contrast-enhanced reference image

  • ref_image_brain (str) – Skull-stripped reference image

  • bold_mask (str) – Skull-stripping mask of reference image

  • validation_report (str) – HTML reportlet indicating whether bold_file had a valid affine

Subworkflows
  • init_enhance_and_skullstrip_wf()

fmriprep.workflows.bold.util.init_enhance_and_skullstrip_bold_wf(name='enhance_and_skullstrip_bold_wf', pre_mask=False, omp_nthreads=1)[source]

Enhance and run brain extraction on a BOLD EPI image.

This workflow takes in a BOLD fMRI average/summary (e.g., a reference image averaging non-steady-state timepoints), and sharpens the histogram with the application of the N4 algorithm for removing the INU bias field and calculates a signal mask.

Steps of this workflow are:

  1. Calculate a tentative mask by registering (9-parameters) to fMRIPrep’s EPI -boldref template, which is in MNI space. The tentative mask is obtained by resampling the MNI template’s brainmask into boldref-space.

  2. Binary dilation of the tentative mask with a sphere of 3mm diameter.

  3. Run ANTs’ N4BiasFieldCorrection on the input BOLD average, using the mask generated in 1) instead of the internal Otsu thresholding.

  4. Calculate a loose mask using FSL’s bet, with one mathematical morphology dilation of one iteration and a sphere of 6mm as structuring element.

  5. Mask the INU-corrected image with the latest mask calculated in 3), then use AFNI’s 3dUnifize to standardize the T2* contrast distribution.

  6. Calculate a mask using AFNI’s 3dAutomask after the contrast enhancement of 4).

  7. Calculate a final mask as the intersection of 4) and 6).

  8. Apply final mask on the enhanced reference.

Step 1 can be skipped if the pre_mask argument is set to True and a tentative mask is passed in to the workflow throught the pre_mask Nipype input.

Workflow graph
../_images/index-9.png

(Source code, png, svg, pdf)

Parameters
  • name (str) – Name of workflow (default: enhance_and_skullstrip_bold_wf)

  • pre_mask (bool) – Indicates whether the pre_mask input will be set (and thus, step 1 should be skipped).

  • omp_nthreads (int) – number of threads available to parallel nodes

Inputs
  • in_file (str) – BOLD image (single volume)

  • pre_mask (bool) – A tentative brain mask to initialize the workflow (requires pre_mask parameter set True).

Outputs
  • bias_corrected_file (str) – the in_file after N4BiasFieldCorrection

  • skull_stripped_file (str) – the bias_corrected_file after skull-stripping

  • mask_file (str) – mask of the skull-stripped input file

  • out_report (str) – reportlet for the skull-stripping

fmriprep.workflows.bold.util.init_skullstrip_bold_wf(name='skullstrip_bold_wf')[source]

Apply skull-stripping to a BOLD image.

It is intended to be used on an image that has previously been bias-corrected with init_enhance_and_skullstrip_bold_wf()

Workflow Graph
../_images/index-10.png

(Source code, png, svg, pdf)

Inputs

in_file (str) – BOLD image (single volume)

Outputs
  • skull_stripped_file (str) – the in_file after skull-stripping

  • mask_file (str) – mask of the skull-stripped input file

  • out_report (str) – reportlet for the skull-stripping

Head-Motion Estimation and Correction (HMC) of BOLD images

fmriprep.workflows.bold.hmc.init_bold_hmc_wf(mem_gb, omp_nthreads, name='bold_hmc_wf')[source]

Build a workflow to estimate head-motion parameters.

This workflow estimates the motion parameters to perform HMC over the input BOLD image.

Workflow Graph
../_images/index-11.png

(Source code, png, svg, pdf)

Parameters
  • mem_gb (float) – Size of BOLD file in GB

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • name (str) – Name of workflow (default: bold_hmc_wf)

Inputs
  • bold_file – BOLD series NIfTI file

  • raw_ref_image – Reference image to which BOLD series is motion corrected

Outputs
  • xforms – ITKTransform file aligning each volume to ref_image

  • movpar_file – MCFLIRT motion parameters, normalized to SPM format (X, Y, Z, Rx, Ry, Rz)

Slice-Timing Correction (STC) of BOLD images

fmriprep.workflows.bold.stc.init_bold_stc_wf(metadata, name='bold_stc_wf')[source]

Create a workflow for STC.

This workflow performs STC over the input BOLD image.

Workflow Graph
../_images/index-12.png

(Source code, png, svg, pdf)

Parameters
  • metadata (dict) – BIDS metadata for BOLD file

  • name (str) – Name of workflow (default: bold_stc_wf)

Inputs
  • bold_file – BOLD series NIfTI file

  • skip_vols – Number of non-steady-state volumes detected at beginning of bold_file

Outputs

stc_file – Slice-timing corrected BOLD series NIfTI file

Generate T2* map from multi-echo BOLD images

fmriprep.workflows.bold.t2s.init_bold_t2s_wf(echo_times, mem_gb, omp_nthreads, t2s_coreg=False, name='bold_t2s_wf')[source]

Combine multiple echos of ME-EPI.

This workflow wraps the tedana T2* workflow to optimally combine multiple echos and derive a T2* map for optional use as a coregistration target. The following steps are performed:

  1. HMC on individual echo files.

  2. Compute the T2* map

  3. Create an optimally combined ME-EPI time series

Parameters
  • echo_times – list of TEs associated with each echo

  • mem_gb (float) – Size of BOLD file in GB

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • t2s_coreg (bool) – Use the calculated T2*-map for T2*-driven coregistration

  • name (str) – Name of workflow (default: bold_t2s_wf)

Inputs

bold_file – list of individual echo files

Outputs
  • bold – the optimally combined time series for all supplied echos

  • bold_mask – the binarized, skull-stripped adaptive T2* map

  • bold_ref_brain – the adaptive T2* map

Registration workflows

fmriprep.workflows.bold.registration.init_bold_reg_wf(freesurfer, use_bbr, bold2t1w_dof, mem_gb, omp_nthreads, use_compression=True, write_report=True, name='bold_reg_wf')[source]

Build a workflow to run same-subject, BOLD-to-T1w image-registration.

Calculates the registration between a reference BOLD image and T1w-space using a boundary-based registration (BBR) cost function. If FreeSurfer-based preprocessing is enabled, the bbregister utility is used to align the BOLD images to the reconstructed subject, and the resulting transform is adjusted to target the T1 space. If FreeSurfer-based preprocessing is disabled, FSL FLIRT is used with the BBR cost function to directly target the T1 space.

Workflow Graph
../_images/index-13.png

(Source code, png, svg, pdf)

Parameters
  • freesurfer (bool) – Enable FreeSurfer functional registration (bbregister)

  • use_bbr (bool or None) – Enable/disable boundary-based registration refinement. If None, test BBR result for distortion before accepting.

  • bold2t1w_dof (6, 9 or 12) – Degrees-of-freedom for BOLD-T1w registration

  • mem_gb (float) – Size of BOLD file in GB

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • name (str) – Name of workflow (default: bold_reg_wf)

  • use_compression (bool) – Save registered BOLD series as .nii.gz

  • use_fieldwarp (bool) – Include SDC warp in single-shot transform from BOLD to T1

  • write_report (bool) – Whether a reportlet should be stored

Inputs
  • ref_bold_brain – Reference image to which BOLD series is aligned If fieldwarp == True, ref_bold_brain should be unwarped

  • t1w_brain – Skull-stripped t1w_preproc

  • t1w_dseg – Segmentation of preprocessed structural image, including gray-matter (GM), white-matter (WM) and cerebrospinal fluid (CSF)

  • subjects_dir – FreeSurfer SUBJECTS_DIR

  • subject_id – FreeSurfer subject ID

  • fsnative2t1w_xfm – LTA-style affine matrix translating from FreeSurfer-conformed subject space to T1w

Outputs
  • itk_bold_to_t1 – Affine transform from ref_bold_brain to T1 space (ITK format)

  • itk_t1_to_bold – Affine transform from T1 space to BOLD space (ITK format)

  • fallback – Boolean indicating whether BBR was rejected (mri_coreg registration returned)

fmriprep.workflows.bold.registration.init_bold_t1_trans_wf(freesurfer, mem_gb, omp_nthreads, multiecho=False, use_fieldwarp=False, use_compression=True, name='bold_t1_trans_wf')[source]

Co-register the reference BOLD image to T1w-space.

The workflow uses BBR.

Workflow Graph
../_images/index-14.png

(Source code, png, svg, pdf)

Parameters
  • freesurfer (bool) – Enable FreeSurfer functional registration (bbregister)

  • use_fieldwarp (bool) – Include SDC warp in single-shot transform from BOLD to T1

  • multiecho (bool) – If multiecho data was supplied, HMC already performed

  • mem_gb (float) – Size of BOLD file in GB

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • use_compression (bool) – Save registered BOLD series as .nii.gz

  • name (str) – Name of workflow (default: bold_reg_wf)

Inputs
  • name_source – BOLD series NIfTI file Used to recover original information lost during processing

  • ref_bold_brain – Reference image to which BOLD series is aligned If fieldwarp == True, ref_bold_brain should be unwarped

  • ref_bold_mask – Skull-stripping mask of reference image

  • t1w_brain – Skull-stripped bias-corrected structural template image

  • t1w_mask – Mask of the skull-stripped template image

  • t1w_aseg – FreeSurfer’s aseg.mgz atlas projected into the T1w reference (only if recon-all was run).

  • t1w_aparc – FreeSurfer’s aparc+aseg.mgz atlas projected into the T1w reference (only if recon-all was run).

  • bold_split – Individual 3D BOLD volumes, not motion corrected

  • hmc_xforms – List of affine transforms aligning each volume to ref_image in ITK format

  • itk_bold_to_t1 – Affine transform from ref_bold_brain to T1 space (ITK format)

  • fieldwarp – a DFM in ITK format

Outputs
  • bold_t1 – Motion-corrected BOLD series in T1 space

  • bold_t1_ref – Reference, contrast-enhanced summary of the motion-corrected BOLD series in T1w space

  • bold_mask_t1 – BOLD mask in T1 space

  • bold_aseg_t1 – FreeSurfer’s aseg.mgz atlas, in T1w-space at the BOLD resolution (only if recon-all was run).

  • bold_aparc_t1 – FreeSurfer’s aparc+aseg.mgz atlas, in T1w-space at the BOLD resolution (only if recon-all was run).

fmriprep.workflows.bold.registration.init_bbreg_wf(use_bbr, bold2t1w_dof, omp_nthreads, name='bbreg_wf')[source]

Build a workflow to run FreeSurfer’s bbregister.

This workflow uses FreeSurfer’s bbregister to register a BOLD image to a T1-weighted structural image.

It is a counterpart to init_fsl_bbr_wf(), which performs the same task using FSL’s FLIRT with a BBR cost function. The use_bbr option permits a high degree of control over registration. If False, standard, affine coregistration will be performed using FreeSurfer’s mri_coreg tool. If True, bbregister will be seeded with the initial transform found by mri_coreg (equivalent to running bbregister --init-coreg). If None, after bbregister is run, the resulting affine transform will be compared to the initial transform found by mri_coreg. Excessive deviation will result in rejecting the BBR refinement and accepting the original, affine registration.

Workflow Graph
../_images/index-15.png

(Source code, png, svg, pdf)

Parameters
  • use_bbr (bool or None) – Enable/disable boundary-based registration refinement. If None, test BBR result for distortion before accepting.

  • bold2t1w_dof (6, 9 or 12) – Degrees-of-freedom for BOLD-T1w registration

  • name (str, optional) – Workflow name (default: bbreg_wf)

Inputs
  • in_file – Reference BOLD image to be registered

  • fsnative2t1w_xfm – FSL-style affine matrix translating from FreeSurfer T1.mgz to T1w

  • subjects_dir – FreeSurfer SUBJECTS_DIR

  • subject_id – FreeSurfer subject ID (must have folder in SUBJECTS_DIR)

  • t1w_brain – Unused (see init_fsl_bbr_wf())

  • t1w_dseg – Unused (see init_fsl_bbr_wf())

Outputs
  • itk_bold_to_t1 – Affine transform from ref_bold_brain to T1 space (ITK format)

  • itk_t1_to_bold – Affine transform from T1 space to BOLD space (ITK format)

  • out_report – Reportlet for assessing registration quality

  • fallback – Boolean indicating whether BBR was rejected (mri_coreg registration returned)

fmriprep.workflows.bold.registration.init_fsl_bbr_wf(use_bbr, bold2t1w_dof, name='fsl_bbr_wf')[source]

Build a workflow to run FSL’s flirt.

This workflow uses FSL FLIRT to register a BOLD image to a T1-weighted structural image, using a boundary-based registration (BBR) cost function. It is a counterpart to init_bbreg_wf(), which performs the same task using FreeSurfer’s bbregister.

The use_bbr option permits a high degree of control over registration. If False, standard, rigid coregistration will be performed by FLIRT. If True, FLIRT-BBR will be seeded with the initial transform found by the rigid coregistration. If None, after FLIRT-BBR is run, the resulting affine transform will be compared to the initial transform found by FLIRT. Excessive deviation will result in rejecting the BBR refinement and accepting the original, affine registration.

Workflow Graph
../_images/index-16.png

(Source code, png, svg, pdf)

Parameters
  • use_bbr (bool or None) – Enable/disable boundary-based registration refinement. If None, test BBR result for distortion before accepting.

  • bold2t1w_dof (6, 9 or 12) – Degrees-of-freedom for BOLD-T1w registration

  • name (str, optional) – Workflow name (default: fsl_bbr_wf)

Inputs
  • in_file – Reference BOLD image to be registered

  • t1w_brain – Skull-stripped T1-weighted structural image

  • t1w_dseg – FAST segmentation of t1w_brain

  • fsnative2t1w_xfm – Unused (see init_bbreg_wf())

  • subjects_dir – Unused (see init_bbreg_wf())

  • subject_id – Unused (see init_bbreg_wf())

Outputs
  • itk_bold_to_t1 – Affine transform from ref_bold_brain to T1w space (ITK format)

  • itk_t1_to_bold – Affine transform from T1 space to BOLD space (ITK format)

  • out_report – Reportlet for assessing registration quality

  • fallback – Boolean indicating whether BBR was rejected (rigid FLIRT registration returned)

Resampling workflows

fmriprep.workflows.bold.resampling.init_bold_surf_wf(mem_gb, output_spaces, medial_surface_nan, name='bold_surf_wf')[source]

Sample functional images to FreeSurfer surfaces.

For each vertex, the cortical ribbon is sampled at six points (spaced 20% of thickness apart) and averaged. Outputs are in GIFTI format.

Workflow Graph
../_images/index-17.png

(Source code, png, svg, pdf)

Parameters
  • output_spaces (list) – List of output spaces functional images are to be resampled to Target spaces beginning with fs will be selected for resampling, such as fsaverage or related template spaces If the list contains fsnative, images will be resampled to the individual subject’s native surface

  • medial_surface_nan (bool) – Replace medial wall values with NaNs on functional GIFTI files

Inputs
  • source_file – Motion-corrected BOLD series in T1 space

  • t1w_preproc – Bias-corrected structural template image

  • subjects_dir – FreeSurfer SUBJECTS_DIR

  • subject_id – FreeSurfer subject ID

  • t1w2fsnative_xfm – LTA-style affine matrix translating from T1w to FreeSurfer-conformed subject space

Outputs

surfaces – BOLD series, resampled to FreeSurfer surfaces

fmriprep.workflows.bold.resampling.init_bold_std_trans_wf(freesurfer, mem_gb, omp_nthreads, standard_spaces, name='bold_std_trans_wf', use_compression=True, use_fieldwarp=False)[source]

Sample fMRI into standard space with a single-step resampling of the original BOLD series.

Important

This workflow provides two outputnodes. One output node (with name poutputnode) will be parameterized in a Nipype sense (see Nipype iterables), and a second node (outputnode) will collapse the parameterized outputs into synchronous lists of the output fields listed below.

Workflow Graph
../_images/index-18.png

(Source code, png, svg, pdf)

Parameters
  • freesurfer (bool) – Whether to generate FreeSurfer’s aseg/aparc segmentations on BOLD space.

  • mem_gb (float) – Size of BOLD file in GB

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • standard_spaces (OrderedDict) – Ordered dictionary where keys are TemplateFlow ID strings (e.g., MNI152Lin, MNI152NLin6Asym, MNI152NLin2009cAsym, or fsLR), or paths pointing to custom templates organized in a TemplateFlow-like structure. Values of the dictionary aggregate modifiers (e.g., the value for the key MNI152Lin could be {'resolution': 2} if one wants the resampling to be done on the 2mm resolution version of the selected template).

  • name (str) – Name of workflow (default: bold_std_trans_wf)

  • use_compression (bool) – Save registered BOLD series as .nii.gz

  • use_fieldwarp (bool) – Include SDC warp in single-shot transform from BOLD to MNI

Inputs
  • anat2std_xfm – List of anatomical-to-standard space transforms generated during spatial normalization.

  • bold_aparc – FreeSurfer’s aparc+aseg.mgz atlas projected into the T1w reference (only if recon-all was run).

  • bold_aseg – FreeSurfer’s aseg.mgz atlas projected into the T1w reference (only if recon-all was run).

  • bold_mask – Skull-stripping mask of reference image

  • bold_split – Individual 3D volumes, not motion corrected

  • fieldwarp – a DFM in ITK format

  • hmc_xforms – List of affine transforms aligning each volume to ref_image in ITK format

  • itk_bold_to_t1 – Affine transform from ref_bold_brain to T1 space (ITK format)

  • name_source – BOLD series NIfTI file Used to recover original information lost during processing

  • templates – List of templates that were applied as targets during spatial normalization.

Outputs
  • bold_std – BOLD series, resampled to template space

  • bold_std_ref – Reference, contrast-enhanced summary of the BOLD series, resampled to template space

  • bold_mask_std – BOLD series mask in template space

  • bold_aseg_std – FreeSurfer’s aseg.mgz atlas, in template space at the BOLD resolution (only if recon-all was run)

  • bold_aparc_std – FreeSurfer’s aparc+aseg.mgz atlas, in template space at the BOLD resolution (only if recon-all was run)

  • templates – Template identifiers synchronized correspondingly to previously described outputs.

fmriprep.workflows.bold.resampling.init_bold_preproc_trans_wf(mem_gb, omp_nthreads, name='bold_preproc_trans_wf', use_compression=True, use_fieldwarp=False, split_file=False, interpolation='LanczosWindowedSinc')[source]

Resample in native (original) space.

This workflow resamples the input fMRI in its native (original) space in a “single shot” from the original BOLD series.

Workflow Graph
../_images/index-19.png

(Source code, png, svg, pdf)

Parameters
  • mem_gb (float) – Size of BOLD file in GB

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • name (str) – Name of workflow (default: bold_std_trans_wf)

  • use_compression (bool) – Save registered BOLD series as .nii.gz

  • use_fieldwarp (bool) – Include SDC warp in single-shot transform from BOLD to MNI

  • split_file (bool) – Whether the input file should be splitted (it is a 4D file) or it is a list of 3D files (default False, do not split)

  • interpolation (str) – Interpolation type to be used by ANTs’ applyTransforms (default 'LanczosWindowedSinc')

Inputs
  • bold_file – Individual 3D volumes, not motion corrected

  • bold_mask – Skull-stripping mask of reference image

  • name_source – BOLD series NIfTI file Used to recover original information lost during processing

  • hmc_xforms – List of affine transforms aligning each volume to ref_image in ITK format

  • fieldwarp – a DFM in ITK format

Outputs
  • bold – BOLD series, resampled in native space, including all preprocessing

  • bold_mask – BOLD series mask calculated with the new time-series

  • bold_ref – BOLD reference image: an average-like 3D image of the time-series

  • bold_ref_brain – Same as bold_ref, but once the brain mask has been applied

Calculate BOLD confounds

fmriprep.workflows.bold.confounds.init_bold_confs_wf(mem_gb, metadata, regressors_all_comps, regressors_dvars_th, regressors_fd_th, name='bold_confs_wf')[source]

Build a workflow to generate and write out confounding signals.

This workflow calculates confounds for a BOLD series, and aggregates them into a TSV file, for use as nuisance regressors in a GLM. The following confounds are calculated, with column headings in parentheses:

  1. Region-wise average signal (csf, white_matter, global_signal)

  2. DVARS - original and standardized variants (dvars, std_dvars)

  3. Framewise displacement, based on head-motion parameters (framewise_displacement)

  4. Temporal CompCor (t_comp_cor_XX)

  5. Anatomical CompCor (a_comp_cor_XX)

  6. Cosine basis set for high-pass filtering w/ 0.008 Hz cut-off (cosine_XX)

  7. Non-steady-state volumes (non_steady_state_XX)

  8. Estimated head-motion parameters, in mm and rad (trans_x, trans_y, trans_z, rot_x, rot_y, rot_z)

Prior to estimating aCompCor and tCompCor, non-steady-state volumes are censored and high-pass filtered using a DCT basis. The cosine basis, as well as one regressor per censored volume, are included for convenience.

Workflow Graph
../_images/index-20.png

(Source code, png, svg, pdf)

Parameters
  • mem_gb (float) – Size of BOLD file in GB - please note that this size should be calculated after resamplings that may extend the FoV

  • metadata (dict) – BIDS metadata for BOLD file

  • name (str) – Name of workflow (default: bold_confs_wf)

  • regressors_all_comps (bool) – Indicates whether CompCor decompositions should return all components instead of the minimal number of components necessary to explain 50 percent of the variance in the decomposition mask.

  • regressors_dvars_th – Criterion for flagging DVARS outliers

  • regressors_fd_th – Criterion for flagging framewise displacement outliers

Inputs
  • bold – BOLD image, after the prescribed corrections (STC, HMC and SDC) when available.

  • bold_mask – BOLD series mask

  • movpar_file – SPM-formatted motion parameters file

  • skip_vols – number of non steady state volumes

  • t1w_mask – Mask of the skull-stripped template image

  • t1w_tpms – List of tissue probability maps in T1w space

  • t1_bold_xform – Affine matrix that maps the T1w space into alignment with the native BOLD space

Outputs
  • confounds_file – TSV of all aggregated confounds

  • rois_report – Reportlet visualizing white-matter/CSF mask used for aCompCor, the ROI for tCompCor and the BOLD brain mask.

  • confounds_metadata – Confounds metadata dictionary.

fmriprep.workflows.bold.confounds.init_ica_aroma_wf(metadata, mem_gb, omp_nthreads, name='ica_aroma_wf', susan_fwhm=6.0, err_on_aroma_warn=False, aroma_melodic_dim=-200, use_fieldwarp=True)[source]

Build a workflow that runs ICA-AROMA.

This workflow wraps ICA-AROMA to identify and remove motion-related independent components from a BOLD time series.

The following steps are performed:

  1. Remove non-steady state volumes from the bold series.

  2. Smooth data using FSL susan, with a kernel width FWHM=6.0mm.

  3. Run FSL melodic outside of ICA-AROMA to generate the report

  4. Run ICA-AROMA

  5. Aggregate identified motion components (aggressive) to TSV

  6. Return classified_motion_ICs and melodic_mix for user to complete non-aggressive denoising in T1w space

  7. Calculate ICA-AROMA-identified noise components (columns named AROMAAggrCompXX)

Additionally, non-aggressive denoising is performed on the BOLD series resampled into MNI space.

There is a current discussion on whether other confounds should be extracted before or after denoising here.

Workflow Graph
../_images/index-21.png

(Source code, png, svg, pdf)

Parameters
  • standard_spaces (str) – Spatial normalization template used as target when that registration step was previously calculated with init_bold_reg_wf(). The template must be one of the MNI templates (fMRIPrep uses MNI152NLin2009cAsym by default).

  • metadata (dict) – BIDS metadata for BOLD file

  • mem_gb (float) – Size of BOLD file in GB

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • name (str) – Name of workflow (default: bold_tpl_trans_wf)

  • susan_fwhm (float) – Kernel width (FWHM in mm) for the smoothing step with FSL susan (default: 6.0mm)

  • use_fieldwarp (bool) – Include SDC warp in single-shot transform from BOLD to MNI

  • err_on_aroma_warn (bool) – Do not fail on ICA-AROMA errors

  • aroma_melodic_dim (int) – Set the dimensionality of the MELODIC ICA decomposition. Negative numbers set a maximum on automatic dimensionality estimation. Positive numbers set an exact number of components to extract. (default: -200, i.e., estimate <=200 components)

Inputs
  • itk_bold_to_t1 – Affine transform from ref_bold_brain to T1 space (ITK format)

  • anat2std_xfm – ANTs-compatible affine-and-warp transform file

  • name_source – BOLD series NIfTI file Used to recover original information lost during processing

  • skip_vols – number of non steady state volumes

  • bold_split – Individual 3D BOLD volumes, not motion corrected

  • bold_mask – BOLD series mask in template space

  • hmc_xforms – List of affine transforms aligning each volume to ref_image in ITK format

  • fieldwarp – a DFM in ITK format

  • movpar_file – SPM-formatted motion parameters file

Outputs
  • aroma_confounds – TSV of confounds identified as noise by ICA-AROMA

  • aroma_noise_ics – CSV of noise components identified by ICA-AROMA

  • melodic_mix – FSL MELODIC mixing matrix

  • nonaggr_denoised_file – BOLD series with non-aggressive ICA-AROMA denoising applied

Fieldmap estimation and unwarping workflows

Automatic selection of the appropriate SDC method

If the dataset metadata indicate tha more than one field map acquisition is IntendedFor (see BIDS Specification section 8.9) the following priority will be used:

Table of behavior (fieldmap use-cases):

Fieldmaps found

use_syn

force_syn

Action

True

True

Fieldmaps + SyN

True

False

Fieldmaps

False

True

SyN

False

True

False

SyN

False

False

False

HMC only

fmriprep.workflows.fieldmap.base.init_sdc_estimate_wf(fmaps, epi_meta, omp_nthreads=1, debug=False)[source]

Build a SDC workflow.

This workflow implements the heuristics to choose an estimation methodology for SDC. When no field map information is present within the BIDS inputs, the EXPERIMENTAL “fieldmap-less SyN” can be performed, using the --use-syn argument. When --force-syn is specified, then the “fieldmap-less SyN” is always executed and reported despite of other fieldmaps available with higher priority. In the latter case (some sort of fieldmap(s) is available and --force-syn is requested), then the SDC method applied is that with the highest priority.

Parameters
  • fmaps (list of pybids dicts) – A list of dictionaries with the available fieldmaps (and their metadata using the key 'metadata' for the case of PEPOLAR fieldmaps).

  • epi_meta (dict) – BIDS metadata dictionary corresponding to the EPI run (i.e., suffix bold, sbref, or dwi) for which the fieldmap is being estimated.

  • omp_nthreads (int) – Maximum number of threads an individual process may use

  • debug (bool) – Enable debugging outputs

Inputs
  • epi_file – A reference image calculated at a previous stage

  • epi_brain – Same as above, but brain-masked

  • epi_mask – Brain mask for the run

  • t1w_brain – T1w image, brain-masked, for the fieldmap-less SyN method

  • std2anat_xfm – Standard-to-T1w transform generated during spatial normalization (only for the fieldmap-less SyN method).

Outputs
  • epi_corrected – The EPI scan reference after unwarping.

  • epi_mask – The corresponding new mask after unwarping

  • epi_brain – Brain-extracted, unwarped EPI scan reference

  • out_warp – The deformation field to unwarp the susceptibility distortions

  • syn_ref – If --force-syn, an unwarped EPI scan reference with this method (for reporting purposes)

  • method (str) – Short description of the estimation method that was run.

Direct B0 mapping sequences

When the fieldmap is directly measured with a prescribed sequence (such as SE), we only need to calculate the corresponding B-Spline coefficients to adapt the fieldmap to the TOPUP tool. This procedure is described with more detail here.

This corresponds to the section 8.9.3 –fieldmap image (and one magnitude image)– of the BIDS specification.

fmriprep.workflows.fieldmap.fmap.init_fmap_wf(omp_nthreads, fmap_bspline, name='fmap_wf')[source]

Estimate the fieldmap based on a field-mapping MRI acquisition.

When we have a sequence that directly measures the fieldmap, we just need to mask it (using the corresponding magnitude image) to remove the noise in the surrounding air region, and ensure that units are Hz.

Workflow Graph
../_images/index-22.png

(Source code, png, svg, pdf)

Parameters
  • omp_nthreads (int) – Maximum number of threads an individual process may use.

  • fmap_bspline (bool) – Whether the fieldmap estimate will be smoothed using BSpline basis.

  • name (str) – Unique name of this workflow.

Inputs
  • magnitude (str) – Path to the corresponding magnitude image for anatomical reference.

  • fieldmap (str) – Path to the fieldmap acquisition (*_fieldmap.nii[.gz] of BIDS).

Outputs
  • fmap (str) – Path to the estimated fieldmap.

  • fmap_ref (str) – Path to a preprocessed magnitude image reference.

  • fmap_mask (str) – Path to a binary brain mask corresponding to the fmap and fmap_ref pair.

Phase-difference B0 estimation

The field inhomogeneity inside the scanner (fieldmap) is proportional to the phase drift between two subsequent GRE sequence.

Fieldmap preprocessing workflow for fieldmap data structure 8.9.1 in BIDS 1.0.0: one phase diff and at least one magnitude image

fmriprep.workflows.fieldmap.phdiff.init_phdiff_wf(omp_nthreads, name='phdiff_wf')[source]

Distortion correction of EPI sequences using phase-difference maps.

Estimates the fieldmap using a phase-difference image and one or more magnitude images corresponding to two or more GRE acquisitions. The most delicate bit of this workflow is the phase-unwrapping process: phase maps are clipped in the range \([0 \dotsb 2\pi )\). To find the integer number of offsets that make a region continously smooth with its neighbour, FSL PRELUDE is run [Jenkinson2003]. FSL PRELUDE takes wrapped maps in the range 0 to 6.28, as per the user guide. For the phase-difference maps, recentering back to \([-\pi \dotsb \pi )\) is necessary. After some massaging and the application of the effective echo spacing parameter, the phase-difference maps can be converted into a B0 field map in Hz units. The original code was taken from nipype.

Workflow Graph
../_images/index-23.png

(Source code, png, svg, pdf)

Parameters

omp_nthreads (int) – Maximum number of threads an individual process may use

Inputs
  • magnitude (list of os.pathlike) – List of path(s) the GRE magnitude maps.

  • phasediff (list of tuple(os.pathlike, dict)) – List containing one GRE phase-difference map with its corresponding metadata (requires EchoTime1 and EchoTime2), or the phase maps for the two subsequent echoes, with their metadata (requires EchoTime).

Outputs
  • fmap_ref (pathlike) – The average magnitude image, skull-stripped

  • fmap_mask (pathlike) – The brain mask applied to the fieldmap

  • fmap (pathlike) – The estimated fieldmap in Hz

References

Jenkinson2003

Jenkinson, M. (2003) Fast, automated, N-dimensional phase-unwrapping algorithm. MRM 49(1):193-197. doi:10.1002/mrm.10354.

Phase Encoding POLARity (PEPOLAR) techniques

fmriprep.workflows.fieldmap.pepolar.init_pepolar_unwarp_wf(omp_nthreads=1, matched_pe=False, name='pepolar_unwarp_wf')[source]

Create the PE-Polar field estimation workflow.

This workflow takes in a set of EPI files with opposite phase encoding direction than the target file and calculates a displacements field (in other words, an ANTs-compatible warp file).

This procedure works if there is only one _epi file is present (as long as it has the opposite phase encoding direction to the target file). The target file will be used to estimate the field distortion. However, if there is another _epi file present with a matching phase encoding direction to the target it will be used instead.

Currently, different phase encoding directions in the target file and the _epi file(s) (for example, i and j) is not supported.

The warp field correcting for the distortions is estimated using AFNI’s 3dQwarp, with displacement estimation limited to the target file phase encoding direction.

It also calculates a new mask for the input dataset that takes into account the distortions.

Workflow Graph
../_images/index-24.png

(Source code, png, svg, pdf)

Parameters
  • matched_pe (bool) – Whether the input fmaps_epi will contain images with matched PE blips or not. Please use sdcflows.workflows.pepolar.check_pes() to determine whether they exist or not.

  • name (str) – Name for this workflow

  • omp_nthreads (int) – Parallelize internal tasks across the number of CPUs given by this option.

Inputs
  • fmaps_epi (list of tuple(pathlike, str)) – The list of EPI images that will be used in PE-Polar correction, and their corresponding PhaseEncodingDirection metadata. The workflow will use the epi_pe_dir input to separate out those EPI acquisitions with opposed PE blips and those with matched PE blips (the latter could be none, and in_reference_brain would then be used). The workflow raises a ValueError when no images with opposed PE blips are found.

  • epi_pe_dir (str) – The baseline PE direction.

  • in_reference (pathlike) – The baseline reference image (must correspond to epi_pe_dir).

  • in_reference_brain (pathlike) – The reference image above, but skullstripped.

  • in_mask (pathlike) – Not used, present only for consistency across fieldmap estimation workflows.

Outputs
  • out_reference (pathlike) – The in_reference after unwarping

  • out_reference_brain (pathlike) – The in_reference after unwarping and skullstripping

  • out_warp (pathlike) – The corresponding DFM compatible with ANTs.

  • out_mask (pathlike) – Mask of the unwarped input file

fmriprep.workflows.fieldmap.pepolar.init_prepare_epi_wf(omp_nthreads, matched_pe=False, name='prepare_epi_wf')[source]

Prepare opposed-PE EPI images for PE-POLAR SDC.

This workflow takes in a set of EPI files and returns two 3D volumes with matching and opposed PE directions, ready to be used in field distortion estimation.

The procedure involves: estimating a robust template using FreeSurfer’s mri_robust_template, bias field correction using ANTs N4BiasFieldCorrection and AFNI 3dUnifize, skullstripping using FSL BET and AFNI 3dAutomask, and rigid coregistration to the reference using ANTs.

Workflow Graph
../_images/index-25.png

(Source code, png, svg, pdf)

Parameters
  • matched_pe (bool) – Whether the input fmaps_epi will contain images with matched PE blips or not. Please use sdcflows.workflows.pepolar.check_pes() to determine whether they exist or not.

  • name (str) – Name for this workflow

  • omp_nthreads (int) – Parallelize internal tasks across the number of CPUs given by this option.

Inputs
  • epi_pe (str) – Phase-encoding direction of the EPI image to be corrected.

  • maps_pe (list of tuple(pathlike, str)) – list of 3D or 4D NIfTI images

  • ref_brain – coregistration reference (skullstripped and bias field corrected)

Outputs
  • opposed_pe (pathlike) – single 3D NIfTI file

  • matched_pe (pathlike) – single 3D NIfTI file

Fieldmap-less estimation (experimental)

In the absence of direct measurements of fieldmap data, we provide an (experimental) option to estimate the susceptibility distortion based on the ANTs symmetric normalization (SyN) technique. This feature may be enabled, using the --use-syn-sdc flag, and will only be applied if fieldmaps are unavailable.

During the evaluation phase, the --force-syn flag will cause this estimation to be performed in addition to fieldmap-based estimation, to permit the direct comparison of the results of each technique. Note that, even if --force-syn is given, the functional outputs of FMRIPREP will be corrected using the fieldmap-based estimates.

Feedback will be enthusiastically received.

fmriprep.workflows.fieldmap.syn.init_syn_sdc_wf(omp_nthreads, epi_pe=None, atlas_threshold=3, name='syn_sdc_wf')[source]

Build the fieldmap-less susceptibility-distortion estimation workflow.

This workflow takes a skull-stripped T1w image and reference BOLD image and estimates a susceptibility distortion correction warp, using ANTs symmetric normalization (SyN) and the average fieldmap atlas described in [Treiber2016].

SyN deformation is restricted to the phase-encoding (PE) direction. If no PE direction is specified, anterior-posterior PE is assumed.

SyN deformation is also restricted to regions that are expected to have a >3mm (approximately 1 voxel) warp, based on the fieldmap atlas.

This technique is a variation on those developed in [Huntenburg2014] and [Wang2017].

Workflow Graph
../_images/index-26.png

(Source code, png, svg, pdf)

Inputs
  • in_reference – reference image

  • in_reference_brain – skull-stripped reference image

  • t1w_brain – skull-stripped, bias-corrected structural image

  • std2anat_xfm – inverse registration transform of T1w image to MNI template

Outputs
  • out_reference – the in_reference image after unwarping

  • out_reference_brain – the in_reference_brain image after unwarping

  • out_warp – the corresponding DFM compatible with ANTs

  • out_mask – mask of the unwarped input file

References

Treiber2016

Treiber, J. M. et al. (2016) Characterization and Correction of Geometric Distortions in 814 Diffusion Weighted Images, PLoS ONE 11(3): e0152472. doi:10.1371/journal.pone.0152472.

Wang2017

Wang S, et al. (2017) Evaluation of Field Map and Nonlinear Registration Methods for Correction of Susceptibility Artifacts in Diffusion MRI. Front. Neuroinform. 11:17. doi:10.3389/fninf.2017.00017.

Huntenburg2014

Huntenburg, J. M. (2014) Evaluating Nonlinear Coregistration of BOLD EPI and T1w Images. Berlin: Master Thesis, Freie Universität. PDF.

Unwarping

Abbreviations

fmap

fieldmap

VSM

voxel-shift map – a 3D nifti where displacements are in pixels (not mm)

DFM

displacements field map – a nifti warp file compatible with ANTs (mm)

fmriprep.workflows.fieldmap.unwarp.init_sdc_unwarp_wf(omp_nthreads, debug, name='sdc_unwarp_wf')[source]

Apply the warping given by a displacements fieldmap.

This workflow takes in a displacements field through which the input reference can be corrected for susceptibility-derived distortion.

It also calculates a new mask for the input dataset, after the distortions have been accounted for.

../_images/index-27.png

(Source code, png, svg, pdf)

Parameters
  • omp_nthreads (int) – Maximum number of threads an individual process may use.

  • debug (bool) – Run fast configurations of registrations.

  • name (str) – Unique name of this workflow.

Inputs
  • in_warp (os.pathlike) – The DFM that corrects for susceptibility-derived distortions estimated elsewhere.

  • in_reference (os.pathlike) – the reference image to be unwarped.

  • in_reference_mask (os.pathlike) – the reference image mask to be unwarped

Outputs
  • out_reference (str) – the in_reference after unwarping

  • out_reference_brain (str) – the in_reference after unwarping and skullstripping

  • out_warp (str) – the in_warp field is forwarded for compatibility

  • out_mask (str) – mask of the unwarped input file