nipype.interfaces.ants.segmentation module

Wrappers for segmentation utilities within ANTs.

AntsJointFusion

Link to code

alias of nipype.interfaces.ants.segmentation.JointFusion

Atropos

Link to code

Bases: ANTSCommand

Wrapped executable: Atropos.

A multivariate n-class segmentation algorithm.

A finite mixture modeling (FMM) segmentation approach with possibilities for specifying prior constraints. These prior constraints include the specification of a prior label image, prior probability images (one for each class), and/or an MRF prior to enforce spatial smoothing of the labels. Similar algorithms include FAST and SPM.

Examples

>>> from nipype.interfaces.ants import Atropos
>>> at = Atropos(
...     dimension=3, intensity_images='structural.nii', mask_image='mask.nii',
...     number_of_tissue_classes=2, likelihood_model='Gaussian', save_posteriors=True,
...     mrf_smoothing_factor=0.2, mrf_radius=[1, 1, 1], icm_use_synchronous_update=True,
...     maximum_number_of_icm_terations=1, n_iterations=5, convergence_threshold=0.000001,
...     posterior_formulation='Socrates', use_mixture_model_proportions=True)
>>> at.inputs.initialization = 'Random'
>>> at.cmdline
'Atropos --image-dimensionality 3 --icm [1,1]
--initialization Random[2] --intensity-image structural.nii
--likelihood-model Gaussian --mask-image mask.nii --mrf [0.2,1x1x1] --convergence [5,1e-06]
--output [structural_labeled.nii,POSTERIOR_%02d.nii.gz] --posterior-formulation Socrates[1]
--use-random-seed 1'

>>> at = Atropos(
...     dimension=3, intensity_images='structural.nii', mask_image='mask.nii',
...     number_of_tissue_classes=2, likelihood_model='Gaussian', save_posteriors=True,
...     mrf_smoothing_factor=0.2, mrf_radius=[1, 1, 1], icm_use_synchronous_update=True,
...     maximum_number_of_icm_terations=1, n_iterations=5, convergence_threshold=0.000001,
...     posterior_formulation='Socrates', use_mixture_model_proportions=True)
>>> at.inputs.initialization = 'KMeans'
>>> at.inputs.kmeans_init_centers = [100, 200]
>>> at.cmdline
'Atropos --image-dimensionality 3 --icm [1,1]
--initialization KMeans[2,100,200] --intensity-image structural.nii
--likelihood-model Gaussian --mask-image mask.nii --mrf [0.2,1x1x1] --convergence [5,1e-06]
--output [structural_labeled.nii,POSTERIOR_%02d.nii.gz] --posterior-formulation Socrates[1]
--use-random-seed 1'

>>> at = Atropos(
...     dimension=3, intensity_images='structural.nii', mask_image='mask.nii',
...     number_of_tissue_classes=2, likelihood_model='Gaussian', save_posteriors=True,
...     mrf_smoothing_factor=0.2, mrf_radius=[1, 1, 1], icm_use_synchronous_update=True,
...     maximum_number_of_icm_terations=1, n_iterations=5, convergence_threshold=0.000001,
...     posterior_formulation='Socrates', use_mixture_model_proportions=True)
>>> at.inputs.initialization = 'PriorProbabilityImages'
>>> at.inputs.prior_image = 'BrainSegmentationPrior%02d.nii.gz'
>>> at.inputs.prior_weighting = 0.8
>>> at.inputs.prior_probability_threshold = 0.0000001
>>> at.cmdline
'Atropos --image-dimensionality 3 --icm [1,1]
--initialization PriorProbabilityImages[2,BrainSegmentationPrior%02d.nii.gz,0.8,1e-07]
--intensity-image structural.nii --likelihood-model Gaussian --mask-image mask.nii
--mrf [0.2,1x1x1] --convergence [5,1e-06]
--output [structural_labeled.nii,POSTERIOR_%02d.nii.gz]
--posterior-formulation Socrates[1] --use-random-seed 1'

>>> at = Atropos(
...     dimension=3, intensity_images='structural.nii', mask_image='mask.nii',
...     number_of_tissue_classes=2, likelihood_model='Gaussian', save_posteriors=True,
...     mrf_smoothing_factor=0.2, mrf_radius=[1, 1, 1], icm_use_synchronous_update=True,
...     maximum_number_of_icm_terations=1, n_iterations=5, convergence_threshold=0.000001,
...     posterior_formulation='Socrates', use_mixture_model_proportions=True)
>>> at.inputs.initialization = 'PriorLabelImage'
>>> at.inputs.prior_image = 'segmentation0.nii.gz'
>>> at.inputs.number_of_tissue_classes = 2
>>> at.inputs.prior_weighting = 0.8
>>> at.cmdline
'Atropos --image-dimensionality 3 --icm [1,1]
--initialization PriorLabelImage[2,segmentation0.nii.gz,0.8] --intensity-image structural.nii
--likelihood-model Gaussian --mask-image mask.nii --mrf [0.2,1x1x1] --convergence [5,1e-06]
--output [structural_labeled.nii,POSTERIOR_%02d.nii.gz] --posterior-formulation Socrates[1]
--use-random-seed 1'

initialization : ‘Random’ or ‘Otsu’ or ‘KMeans’ or ‘PriorProbabilityImages’ or ‘PriorLabelImage’

Maps to a command-line argument: %s. Requires inputs: number_of_tissue_classes.

intensity_images : a list of items which are a pathlike object or string representing an existing file

Maps to a command-line argument: --intensity-image %s....

mask_image : a pathlike object or string representing an existing file

Maps to a command-line argument: --mask-image %s.

number_of_tissue_classes : an integer (int or long)

args : a unicode string

Additional parameters to the command. Maps to a command-line argument: %s.

convergence_threshold : a float

Requires inputs: n_iterations.

dimension : 3 or 2 or 4

Image dimension (2, 3, or 4). Maps to a command-line argument: --image-dimensionality %d. (Nipype default value: 3)

environ : a dictionary with keys which are a bytes or None or a value of class ‘str’ and with values which are a bytes or None or a value of class ‘str’

Environment variables. (Nipype default value: {})

icm_use_synchronous_update : a boolean

Maps to a command-line argument: %s.

kmeans_init_centers : a list of at least 1 items which are an integer (int or long) or a float likelihood_model : a unicode string

Maps to a command-line argument: --likelihood-model %s.

maximum_number_of_icm_terations : an integer (int or long)

Requires inputs: icm_use_synchronous_update.

mrf_radius : a list of items which are an integer (int or long)

Requires inputs: mrf_smoothing_factor.

mrf_smoothing_factor : a float

Maps to a command-line argument: %s.

n_iterations : an integer (int or long)

Maps to a command-line argument: %s.

num_threads : an integer (int or long)

Number of ITK threads to use. (Nipype default value: 1)

out_classified_image_name : a pathlike object or string representing a file

Maps to a command-line argument: %s.

output_posteriors_name_template : a unicode string

(Nipype default value: POSTERIOR_%02d.nii.gz)

posterior_formulation : a unicode string

Maps to a command-line argument: %s.

prior_image : a pathlike object or string representing an existing file or a unicode string

Either a string pattern (e.g., ‘prior%02d.nii’) or an existing vector-image file.

prior_probability_threshold : a float

Requires inputs: prior_weighting.

prior_weighting : a float save_posteriors : a boolean use_mixture_model_proportions : a boolean

Requires inputs: posterior_formulation.

use_random_seed : a boolean

Use random seed value over constant. Maps to a command-line argument: --use-random-seed %d. (Nipype default value: True)

classified_image : a pathlike object or string representing an existing file posteriors : a list of items which are a pathlike object or string representing a file

BrainExtraction

Link to code

Bases: ANTSCommand

Wrapped executable: antsBrainExtraction.sh.

Atlas-based brain extraction.

Examples

>>> from nipype.interfaces.ants.segmentation import BrainExtraction
>>> brainextraction = BrainExtraction()
>>> brainextraction.inputs.dimension = 3
>>> brainextraction.inputs.anatomical_image ='T1.nii.gz'
>>> brainextraction.inputs.brain_template = 'study_template.nii.gz'
>>> brainextraction.inputs.brain_probability_mask ='ProbabilityMaskOfStudyTemplate.nii.gz'
>>> brainextraction.cmdline
'antsBrainExtraction.sh -a T1.nii.gz -m ProbabilityMaskOfStudyTemplate.nii.gz
-e study_template.nii.gz -d 3 -s nii.gz -o highres001_'

anatomical_image : a pathlike object or string representing an existing file

Structural image, typically T1. If more than one anatomical image is specified, subsequently specified images are used during the segmentation process. However, only the first image is used in the registration of priors. Our suggestion would be to specify the T1 as the first image. Anatomical template created using e.g. LPBA40 data set with buildtemplateparallel.sh in ANTs. Maps to a command-line argument: -a %s.

brain_probability_mask : a pathlike object or string representing an existing file

Brain probability mask created using e.g. LPBA40 data set which have brain masks defined, and warped to anatomical template and averaged resulting in a probability image. Maps to a command-line argument: -m %s.

brain_template : a pathlike object or string representing an existing file

Anatomical template created using e.g. LPBA40 data set with buildtemplateparallel.sh in ANTs. Maps to a command-line argument: -e %s.

args : a unicode string

Additional parameters to the command. Maps to a command-line argument: %s.

debug : a boolean

If > 0, runs a faster version of the script. Only for testing. Implies -u 0. Requires single thread computation for complete reproducibility. Maps to a command-line argument: -z 1.

dimension : 3 or 2

Image dimension (2 or 3). Maps to a command-line argument: -d %d. (Nipype default value: 3)

environ : a dictionary with keys which are a bytes or None or a value of class ‘str’ and with values which are a bytes or None or a value of class ‘str’

Environment variables. (Nipype default value: {})

extraction_registration_mask : a pathlike object or string representing an existing file

Mask (defined in the template space) used during registration for brain extraction. To limit the metric computation to a specific region. Maps to a command-line argument: -f %s.

image_suffix : a unicode string

Any of standard ITK formats, nii.gz is default. Maps to a command-line argument: -s %s. (Nipype default value: nii.gz)

keep_temporary_files : an integer (int or long)

Keep brain extraction/segmentation warps, etc (default = 0). Maps to a command-line argument: -k %d.

num_threads : an integer (int or long)

Number of ITK threads to use. (Nipype default value: 1)

out_prefix : a unicode string

Prefix that is prepended to all output files. Maps to a command-line argument: -o %s. (Nipype default value: highres001_)

use_floatingpoint_precision : 0 or 1

Use floating point precision in registrations (default = 0). Maps to a command-line argument: -q %d.

use_random_seeding : 0 or 1

Use random number generated from system clock in Atropos (default = 1). Maps to a command-line argument: -u %d.

BrainExtractionBrain : a pathlike object or string representing an existing file

Brain extraction image.

BrainExtractionCSF : a pathlike object or string representing an existing file

Segmentation mask with only CSF.

BrainExtractionGM : a pathlike object or string representing an existing file

Segmentation mask with only grey matter.

BrainExtractionInitialAffine : a pathlike object or string representing an existing file BrainExtractionInitialAffineFixed : a pathlike object or string representing an existing file BrainExtractionInitialAffineMoving : a pathlike object or string representing an existing file BrainExtractionLaplacian : a pathlike object or string representing an existing file BrainExtractionMask : a pathlike object or string representing an existing file

Brain extraction mask.

BrainExtractionPrior0GenericAffine : a pathlike object or string representing an existing file BrainExtractionPrior1InverseWarp : a pathlike object or string representing an existing file BrainExtractionPrior1Warp : a pathlike object or string representing an existing file BrainExtractionPriorWarped : a pathlike object or string representing an existing file BrainExtractionSegmentation : a pathlike object or string representing an existing file

Segmentation mask with CSF, GM, and WM.

BrainExtractionTemplateLaplacian : a pathlike object or string representing an existing file BrainExtractionTmp : a pathlike object or string representing an existing file BrainExtractionWM : a pathlike object or string representing an existing file

Segmenration mask with only white matter.

N4Corrected0 : a pathlike object or string representing an existing file

N4 bias field corrected image.

N4Truncated0 : a pathlike object or string representing an existing file

CorticalThickness

Link to code

Bases: ANTSCommand

Wrapped executable: antsCorticalThickness.sh.

Examples

>>> from nipype.interfaces.ants.segmentation import CorticalThickness
>>> corticalthickness = CorticalThickness()
>>> corticalthickness.inputs.dimension = 3
>>> corticalthickness.inputs.anatomical_image ='T1.nii.gz'
>>> corticalthickness.inputs.brain_template = 'study_template.nii.gz'
>>> corticalthickness.inputs.brain_probability_mask ='ProbabilityMaskOfStudyTemplate.nii.gz'
>>> corticalthickness.inputs.segmentation_priors = ['BrainSegmentationPrior01.nii.gz',
...                                                 'BrainSegmentationPrior02.nii.gz',
...                                                 'BrainSegmentationPrior03.nii.gz',
...                                                 'BrainSegmentationPrior04.nii.gz']
>>> corticalthickness.inputs.t1_registration_template = 'brain_study_template.nii.gz'
>>> corticalthickness.cmdline
'antsCorticalThickness.sh -a T1.nii.gz -m ProbabilityMaskOfStudyTemplate.nii.gz
-e study_template.nii.gz -d 3 -s nii.gz -o antsCT_
-p nipype_priors/BrainSegmentationPrior%02d.nii.gz -t brain_study_template.nii.gz'

anatomical_image : a pathlike object or string representing an existing file

Structural intensity image, typically T1. If more than one anatomical image is specified, subsequently specified images are used during the segmentation process. However, only the first image is used in the registration of priors. Our suggestion would be to specify the T1 as the first image. Maps to a command-line argument: -a %s.

brain_probability_mask : a pathlike object or string representing an existing file

Brain probability mask in template space. Maps to a command-line argument: -m %s.

brain_template : a pathlike object or string representing an existing file

Anatomical intensity template (possibly created using a population data set with buildtemplateparallel.sh in ANTs). This template is not skull-stripped. Maps to a command-line argument: -e %s.

segmentation_priors : a list of items which are a pathlike object or string representing an existing file

Maps to a command-line argument: -p %s.

t1_registration_template : a pathlike object or string representing an existing file

Anatomical intensity template (assumed to be skull-stripped). A common case would be where this would be the same template as specified in the -e option which is not skull stripped. Maps to a command-line argument: -t %s.

args : a unicode string

Additional parameters to the command. Maps to a command-line argument: %s.

b_spline_smoothing : a boolean

Use B-spline SyN for registrations and B-spline exponential mapping in DiReCT. Maps to a command-line argument: -v.

cortical_label_image : a pathlike object or string representing an existing file

Cortical ROI labels to use as a prior for ATITH.

debug : a boolean

If > 0, runs a faster version of the script. Only for testing. Implies -u 0. Requires single thread computation for complete reproducibility. Maps to a command-line argument: -z 1.

dimension : 3 or 2

Image dimension (2 or 3). Maps to a command-line argument: -d %d. (Nipype default value: 3)

environ : a dictionary with keys which are a bytes or None or a value of class ‘str’ and with values which are a bytes or None or a value of class ‘str’

Environment variables. (Nipype default value: {})

extraction_registration_mask : a pathlike object or string representing an existing file

Mask (defined in the template space) used during registration for brain extraction. Maps to a command-line argument: -f %s.

image_suffix : a unicode string

Any of standard ITK formats, nii.gz is default. Maps to a command-line argument: -s %s. (Nipype default value: nii.gz)

keep_temporary_files : an integer (int or long)

Keep brain extraction/segmentation warps, etc (default = 0). Maps to a command-line argument: -k %d.

label_propagation : a unicode string

Incorporate a distance prior one the posterior formulation. Should be of the form ‘label[lambda,boundaryProbability]’ where label is a value of 1,2,3,… denoting label ID. The label probability for anything outside the current label = boundaryProbability * exp( -lambda * distanceFromBoundary ) Intuitively, smaller lambda values will increase the spatial capture range of the distance prior. To apply to all label values, simply omit specifying the label, i.e. -l [lambda,boundaryProbability]. Maps to a command-line argument: -l %s.

max_iterations : an integer (int or long)

ANTS registration max iterations (default = 100x100x70x20). Maps to a command-line argument: -i %d.

num_threads : an integer (int or long)

Number of ITK threads to use. (Nipype default value: 1)

out_prefix : a unicode string

Prefix that is prepended to all output files. Maps to a command-line argument: -o %s. (Nipype default value: antsCT_)

posterior_formulation : a unicode string

Atropos posterior formulation and whether or not to use mixture model proportions. e.g ‘Socrates[1]’ (default) or ‘Aristotle[1]’. Choose the latter if you want use the distance priors (see also the -l option for label propagation control). Maps to a command-line argument: -b %s.

prior_segmentation_weight : a float

Atropos spatial prior probability weight for the segmentation. Maps to a command-line argument: -w %f.

quick_registration : a boolean

If = 1, use antsRegistrationSyNQuick.sh as the basis for registration during brain extraction, brain segmentation, and (optional) normalization to a template. Otherwise use antsRegistrationSyN.sh (default = 0). Maps to a command-line argument: -q 1.

segmentation_iterations : an integer (int or long)

N4 -> Atropos -> N4 iterations during segmentation (default = 3). Maps to a command-line argument: -n %d.

use_floatingpoint_precision : 0 or 1

Use floating point precision in registrations (default = 0). Maps to a command-line argument: -j %d.

use_random_seeding : 0 or 1

Use random number generated from system clock in Atropos (default = 1). Maps to a command-line argument: -u %d.

BrainExtractionMask : a pathlike object or string representing an existing file

Brain extraction mask.

BrainSegmentation : a pathlike object or string representing an existing file

Brain segmentaion image.

BrainSegmentationN4 : a pathlike object or string representing an existing file

N4 corrected image.

BrainSegmentationPosteriors : a list of items which are a pathlike object or string representing an existing file

Posterior probability images.

BrainVolumes : a pathlike object or string representing an existing file

Brain volumes as text.

CorticalThickness : a pathlike object or string representing an existing file

Cortical thickness file.

CorticalThicknessNormedToTemplate : a pathlike object or string representing an existing file

Normalized cortical thickness.

ExtractedBrainN4 : a pathlike object or string representing an existing file

Extracted brain from N4 image.

SubjectToTemplate0GenericAffine : a pathlike object or string representing an existing file

Template to subject inverse affine.

SubjectToTemplate1Warp : a pathlike object or string representing an existing file

Template to subject inverse warp.

SubjectToTemplateLogJacobian : a pathlike object or string representing an existing file

Template to subject log jacobian.

TemplateToSubject0Warp : a pathlike object or string representing an existing file

Template to subject warp.

TemplateToSubject1GenericAffine : a pathlike object or string representing an existing file

Template to subject affine.

DenoiseImage

Link to code

Bases: ANTSCommand

Wrapped executable: DenoiseImage.

Examples

>>> import copy
>>> from nipype.interfaces.ants import DenoiseImage
>>> denoise = DenoiseImage()
>>> denoise.inputs.dimension = 3
>>> denoise.inputs.input_image = 'im1.nii'
>>> denoise.cmdline
'DenoiseImage -d 3 -i im1.nii -n Gaussian -o im1_noise_corrected.nii -s 1'

>>> denoise_2 = copy.deepcopy(denoise)
>>> denoise_2.inputs.output_image = 'output_corrected_image.nii.gz'
>>> denoise_2.inputs.noise_model = 'Rician'
>>> denoise_2.inputs.shrink_factor = 2
>>> denoise_2.cmdline
'DenoiseImage -d 3 -i im1.nii -n Rician -o output_corrected_image.nii.gz -s 2'

>>> denoise_3 = DenoiseImage()
>>> denoise_3.inputs.input_image = 'im1.nii'
>>> denoise_3.inputs.save_noise = True
>>> denoise_3.cmdline
'DenoiseImage -i im1.nii -n Gaussian -o [ im1_noise_corrected.nii, im1_noise.nii ] -s 1'

input_image : a pathlike object or string representing an existing file

A scalar image is expected as input for noise correction. Maps to a command-line argument: -i %s.

save_noise : a boolean

True if the estimated noise should be saved to file. Mutually exclusive with inputs: noise_image. (Nipype default value: False)

args : a unicode string

Additional parameters to the command. Maps to a command-line argument: %s.

dimension : 2 or 3 or 4

This option forces the image to be treated as a specified-dimensional image. If not specified, the program tries to infer the dimensionality from the input image. Maps to a command-line argument: -d %d.

environ : a dictionary with keys which are a bytes or None or a value of class ‘str’ and with values which are a bytes or None or a value of class ‘str’

Environment variables. (Nipype default value: {})

noise_image : a pathlike object or string representing a file

Filename for the estimated noise.

noise_model : ‘Gaussian’ or ‘Rician’

Employ a Rician or Gaussian noise model. Maps to a command-line argument: -n %s. (Nipype default value: Gaussian)

num_threads : an integer (int or long)

Number of ITK threads to use. (Nipype default value: 1)

output_image : a pathlike object or string representing a file

The output consists of the noise corrected version of the input image. Maps to a command-line argument: -o %s.

shrink_factor : an integer (int or long)

Running noise correction on large images can be time consuming. To lessen computation time, the input image can be resampled. The shrink factor, specified as a single integer, describes this resampling. Shrink factor = 1 is the default. Maps to a command-line argument: -s %s. (Nipype default value: 1)

verbose : a boolean

Verbose output. Maps to a command-line argument: -v.

noise_image : a pathlike object or string representing a file output_image : a pathlike object or string representing an existing file

JointFusion

Link to code

Bases: ANTSCommand

Wrapped executable: antsJointFusion.

An image fusion algorithm.

Developed by Hongzhi Wang and Paul Yushkevich, and it won segmentation challenges at MICCAI 2012 and MICCAI 2013. The original label fusion framework was extended to accommodate intensities by Brian Avants. This implementation is based on Paul’s original ITK-style implementation and Brian’s ANTsR implementation.

References include 1) H. Wang, J. W. Suh, S. Das, J. Pluta, C. Craige, P. Yushkevich, Multi-atlas segmentation with joint label fusion IEEE Trans. on Pattern Analysis and Machine Intelligence, 35(3), 611-623, 2013. and 2) H. Wang and P. A. Yushkevich, Multi-atlas segmentation with joint label fusion and corrective learning–an open source implementation, Front. Neuroinform., 2013.

Examples

>>> from nipype.interfaces.ants import JointFusion
>>> jf = JointFusion()
>>> jf.inputs.out_label_fusion = 'ants_fusion_label_output.nii'
>>> jf.inputs.atlas_image = [ ['rc1s1.nii','rc1s2.nii'] ]
>>> jf.inputs.atlas_segmentation_image = ['segmentation0.nii.gz']
>>> jf.inputs.target_image = ['im1.nii']
>>> jf.cmdline
"antsJointFusion -a 0.1 -g ['rc1s1.nii', 'rc1s2.nii'] -l segmentation0.nii.gz
-b 2.0 -o ants_fusion_label_output.nii -s 3x3x3 -t ['im1.nii']"

>>> jf.inputs.target_image = [ ['im1.nii', 'im2.nii'] ]
>>> jf.cmdline
"antsJointFusion -a 0.1 -g ['rc1s1.nii', 'rc1s2.nii'] -l segmentation0.nii.gz
-b 2.0 -o ants_fusion_label_output.nii -s 3x3x3 -t ['im1.nii', 'im2.nii']"

>>> jf.inputs.atlas_image = [ ['rc1s1.nii','rc1s2.nii'],
...                                        ['rc2s1.nii','rc2s2.nii'] ]
>>> jf.inputs.atlas_segmentation_image = ['segmentation0.nii.gz',
...                                                    'segmentation1.nii.gz']
>>> jf.cmdline
"antsJointFusion -a 0.1 -g ['rc1s1.nii', 'rc1s2.nii'] -g ['rc2s1.nii', 'rc2s2.nii']
-l segmentation0.nii.gz -l segmentation1.nii.gz -b 2.0 -o ants_fusion_label_output.nii
-s 3x3x3 -t ['im1.nii', 'im2.nii']"

>>> jf.inputs.dimension = 3
>>> jf.inputs.alpha = 0.5
>>> jf.inputs.beta = 1.0
>>> jf.inputs.patch_radius = [3,2,1]
>>> jf.inputs.search_radius = [3]
>>> jf.cmdline
"antsJointFusion -a 0.5 -g ['rc1s1.nii', 'rc1s2.nii'] -g ['rc2s1.nii', 'rc2s2.nii']
-l segmentation0.nii.gz -l segmentation1.nii.gz -b 1.0 -d 3 -o ants_fusion_label_output.nii
-p 3x2x1 -s 3 -t ['im1.nii', 'im2.nii']"

>>> jf.inputs.search_radius = ['mask.nii']
>>> jf.inputs.verbose = True
>>> jf.inputs.exclusion_image = ['roi01.nii', 'roi02.nii']
>>> jf.inputs.exclusion_image_label = ['1','2']
>>> jf.cmdline
"antsJointFusion -a 0.5 -g ['rc1s1.nii', 'rc1s2.nii'] -g ['rc2s1.nii', 'rc2s2.nii']
-l segmentation0.nii.gz -l segmentation1.nii.gz -b 1.0 -d 3 -e 1[roi01.nii] -e 2[roi02.nii]
-o ants_fusion_label_output.nii -p 3x2x1 -s mask.nii -t ['im1.nii', 'im2.nii'] -v"

>>> jf.inputs.out_label_fusion = 'ants_fusion_label_output.nii'
>>> jf.inputs.out_intensity_fusion_name_format = 'ants_joint_fusion_intensity_%d.nii.gz'
>>> jf.inputs.out_label_post_prob_name_format = 'ants_joint_fusion_posterior_%d.nii.gz'
>>> jf.inputs.out_atlas_voting_weight_name_format = 'ants_joint_fusion_voting_weight_%d.nii.gz'
>>> jf.cmdline
"antsJointFusion -a 0.5 -g ['rc1s1.nii', 'rc1s2.nii'] -g ['rc2s1.nii', 'rc2s2.nii']
-l segmentation0.nii.gz -l segmentation1.nii.gz -b 1.0 -d 3 -e 1[roi01.nii] -e 2[roi02.nii]
-o [ants_fusion_label_output.nii, ants_joint_fusion_intensity_%d.nii.gz,
ants_joint_fusion_posterior_%d.nii.gz, ants_joint_fusion_voting_weight_%d.nii.gz]
-p 3x2x1 -s mask.nii -t ['im1.nii', 'im2.nii'] -v"

atlas_image : a list of items which are a list of items which are a pathlike object or string representing an existing file

The atlas image (or multimodal atlas images) assumed to be aligned to a common image domain. Maps to a command-line argument: -g %s....

atlas_segmentation_image : a list of items which are a pathlike object or string representing an existing file

The atlas segmentation images. For performing label fusion the number of specified segmentations should be identical to the number of atlas image sets. Maps to a command-line argument: -l %s....

target_image : a list of items which are a list of items which are a pathlike object or string representing an existing file

The target image (or multimodal target images) assumed to be aligned to a common image domain. Maps to a command-line argument: -t %s.

alpha : a float

Regularization term added to matrix Mx for calculating the inverse. Default = 0.1. Maps to a command-line argument: -a %s. (Nipype default value: 0.1)

args : a unicode string

Additional parameters to the command. Maps to a command-line argument: %s.

beta : a float

Exponent for mapping intensity difference to the joint error. Default = 2.0. Maps to a command-line argument: -b %s. (Nipype default value: 2.0)

constrain_nonnegative : a boolean

Constrain solution to non-negative weights. Maps to a command-line argument: -c. (Nipype default value: False)

dimension : 3 or 2 or 4

This option forces the image to be treated as a specified-dimensional image. If not specified, the program tries to infer the dimensionality from the input image. Maps to a command-line argument: -d %d.

environ : a dictionary with keys which are a bytes or None or a value of class ‘str’ and with values which are a bytes or None or a value of class ‘str’

Environment variables. (Nipype default value: {})

exclusion_image : a list of items which are a pathlike object or string representing an existing file

Specify an exclusion region for the given label.

exclusion_image_label : a list of items which are a unicode string

Specify a label for the exclusion region. Maps to a command-line argument: -e %s. Requires inputs: exclusion_image.

mask_image : a pathlike object or string representing an existing file

If a mask image is specified, fusion is only performed in the mask region. Maps to a command-line argument: -x %s.

num_threads : an integer (int or long)

Number of ITK threads to use. (Nipype default value: 1)

out_atlas_voting_weight_name_format : a unicode string

Optional atlas voting weight image file name format. Requires inputs: out_label_fusion, out_intensity_fusion_name_format, out_label_post_prob_name_format.

out_intensity_fusion_name_format : a unicode string

Optional intensity fusion image file name format. (e.g. “antsJointFusionIntensity_%d.nii.gz”).

out_label_fusion : a pathlike object or string representing a file

The output label fusion image. Maps to a command-line argument: %s.

out_label_post_prob_name_format : a unicode string

Optional label posterior probability image file name format. Requires inputs: out_label_fusion, out_intensity_fusion_name_format.

patch_metric : ‘PC’ or ‘MSQ’

Metric to be used in determining the most similar neighborhood patch. Options include Pearson’s correlation (PC) and mean squares (MSQ). Default = PC (Pearson correlation). Maps to a command-line argument: -m %s.

patch_radius : a list of items which are a value of class ‘int’

Patch radius for similarity measures. Default: 2x2x2. Maps to a command-line argument: -p %s.

retain_atlas_voting_images : a boolean

Retain atlas voting images. Default = false. Maps to a command-line argument: -f. (Nipype default value: False)

retain_label_posterior_images : a boolean

Retain label posterior probability images. Requires atlas segmentations to be specified. Default = false. Maps to a command-line argument: -r. Requires inputs: atlas_segmentation_image. (Nipype default value: False)

search_radius : a list of from 1 to 3 items which are any value

Search radius for similarity measures. Default = 3x3x3. One can also specify an image where the value at the voxel specifies the isotropic search radius at that voxel. Maps to a command-line argument: -s %s. (Nipype default value: [3, 3, 3])

verbose : a boolean

Verbose output. Maps to a command-line argument: -v.

out_atlas_voting_weight : a list of items which are a pathlike object or string representing an existing file out_intensity_fusion : a list of items which are a pathlike object or string representing an existing file out_label_fusion : a pathlike object or string representing an existing file out_label_post_prob : a list of items which are a pathlike object or string representing an existing file

KellyKapowski

Link to code

Bases: ANTSCommand

Wrapped executable: KellyKapowski.

Nipype Interface to ANTs’ KellyKapowski, also known as DiReCT.

DiReCT is a registration based estimate of cortical thickness. It was published in S. R. Das, B. B. Avants, M. Grossman, and J. C. Gee, Registration based cortical thickness measurement, Neuroimage 2009, 45:867–879.

Examples

>>> from nipype.interfaces.ants.segmentation import KellyKapowski
>>> kk = KellyKapowski()
>>> kk.inputs.dimension = 3
>>> kk.inputs.segmentation_image = "segmentation0.nii.gz"
>>> kk.inputs.convergence = "[45,0.0,10]"
>>> kk.inputs.thickness_prior_estimate = 10
>>> kk.cmdline
'KellyKapowski --convergence "[45,0.0,10]"
--output "[segmentation0_cortical_thickness.nii.gz,segmentation0_warped_white_matter.nii.gz]"
--image-dimensionality 3 --gradient-step 0.025000
--maximum-number-of-invert-displacement-field-iterations 20 --number-of-integration-points 10
--segmentation-image "[segmentation0.nii.gz,2,3]" --smoothing-variance 1.000000
--smoothing-velocity-field-parameter 1.500000 --thickness-prior-estimate 10.000000'

segmentation_image : a pathlike object or string representing an existing file

A segmentation image must be supplied labeling the gray and white matters. Default values = 2 and 3, respectively. Maps to a command-line argument: --segmentation-image "%s".

args : a unicode string

Additional parameters to the command. Maps to a command-line argument: %s.

convergence : a unicode string

Convergence is determined by fitting a line to the normalized energy profile of the last N iterations (where N is specified by the window size) and determining the slope which is then compared with the convergence threshold. Maps to a command-line argument: --convergence "%s". (Nipype default value: [50,0.001,10])

cortical_thickness : a pathlike object or string representing a file

Filename for the cortical thickness. Maps to a command-line argument: --output "%s".

dimension : 3 or 2

Image dimension (2 or 3). Maps to a command-line argument: --image-dimensionality %d. (Nipype default value: 3)

environ : a dictionary with keys which are a bytes or None or a value of class ‘str’ and with values which are a bytes or None or a value of class ‘str’

Environment variables. (Nipype default value: {})

gradient_step : a float

Gradient step size for the optimization. Maps to a command-line argument: --gradient-step %f. (Nipype default value: 0.025)

gray_matter_label : an integer (int or long)

The label value for the gray matter label in the segmentation_image. (Nipype default value: 2)

gray_matter_prob_image : a pathlike object or string representing an existing file

In addition to the segmentation image, a gray matter probability image can be used. If no such image is supplied, one is created using the segmentation image and a variance of 1.0 mm. Maps to a command-line argument: --gray-matter-probability-image "%s".

max_invert_displacement_field_iters : an integer (int or long)

Maximum number of iterations for estimating the invertdisplacement field. Maps to a command-line argument: --maximum-number-of-invert-displacement-field-iterations %d. (Nipype default value: 20)

num_threads : an integer (int or long)

Number of ITK threads to use. (Nipype default value: 1)

number_integration_points : an integer (int or long)

Number of compositions of the diffeomorphism per iteration. Maps to a command-line argument: --number-of-integration-points %d. (Nipype default value: 10)

smoothing_variance : a float

Defines the Gaussian smoothing of the hit and total images. Maps to a command-line argument: --smoothing-variance %f. (Nipype default value: 1.0)

smoothing_velocity_field : a float

Defines the Gaussian smoothing of the velocity field (default = 1.5). If the b-spline smoothing option is chosen, then this defines the isotropic mesh spacing for the smoothing spline (default = 15). Maps to a command-line argument: --smoothing-velocity-field-parameter %f. (Nipype default value: 1.5)

thickness_prior_estimate : a float

Provides a prior constraint on the final thickness measurement in mm. Maps to a command-line argument: --thickness-prior-estimate %f. (Nipype default value: 10)

thickness_prior_image : a pathlike object or string representing an existing file

An image containing spatially varying prior thickness values. Maps to a command-line argument: --thickness-prior-image "%s".

use_bspline_smoothing : a boolean

Sets the option for B-spline smoothing of the velocity field. Maps to a command-line argument: --use-bspline-smoothing 1.

warped_white_matter : a pathlike object or string representing a file

Filename for the warped white matter file.

white_matter_label : an integer (int or long)

The label value for the white matter label in the segmentation_image. (Nipype default value: 3)

white_matter_prob_image : a pathlike object or string representing an existing file

In addition to the segmentation image, a white matter probability image can be used. If no such image is supplied, one is created using the segmentation image and a variance of 1.0 mm. Maps to a command-line argument: --white-matter-probability-image "%s".

cortical_thickness : a pathlike object or string representing a file

A thickness map defined in the segmented gray matter.

warped_white_matter : a pathlike object or string representing a file

A warped white matter image.

KellyKapowski.references_ = [{'entry': None, 'description': 'The details on the implementation of DiReCT.', 'tags': ['implementation']}]

LaplacianThickness

Link to code

Bases: ANTSCommand

Wrapped executable: LaplacianThickness.

Calculates the cortical thickness from an anatomical image

Examples

>>> from nipype.interfaces.ants import LaplacianThickness
>>> cort_thick = LaplacianThickness()
>>> cort_thick.inputs.input_wm = 'white_matter.nii.gz'
>>> cort_thick.inputs.input_gm = 'gray_matter.nii.gz'
>>> cort_thick.cmdline
'LaplacianThickness white_matter.nii.gz gray_matter.nii.gz white_matter_thickness.nii.gz'

>>> cort_thick.inputs.output_image = 'output_thickness.nii.gz'
>>> cort_thick.cmdline
'LaplacianThickness white_matter.nii.gz gray_matter.nii.gz output_thickness.nii.gz'

input_gm : a pathlike object or string representing a file

Gray matter segmentation image. Maps to a command-line argument: %s (position: 2).

input_wm : a pathlike object or string representing a file

White matter segmentation image. Maps to a command-line argument: %s (position: 1).

args : a unicode string

Additional parameters to the command. Maps to a command-line argument: %s.

dT : a float

Time delta used during integration (defaults to 0.01). Maps to a command-line argument: %s (position: 6). Requires inputs: prior_thickness.

environ : a dictionary with keys which are a bytes or None or a value of class ‘str’ and with values which are a bytes or None or a value of class ‘str’

Environment variables. (Nipype default value: {})

num_threads : an integer (int or long)

Number of ITK threads to use. (Nipype default value: 1)

output_image : a pathlike object or string representing a file

Name of output file. Maps to a command-line argument: %s (position: 3).

prior_thickness : a float

Prior thickness (defaults to 500). Maps to a command-line argument: %s (position: 5). Requires inputs: smooth_param.

smooth_param : a float

Sigma of the Laplacian Recursive Image Filter (defaults to 1). Maps to a command-line argument: %s (position: 4).

sulcus_prior : a float

Positive floating point number for sulcus prior. Authors said that 0.15 might be a reasonable value. Maps to a command-line argument: %s (position: 7). Requires inputs: dT.

tolerance : a float

Tolerance to reach during optimization (defaults to 0.001). Maps to a command-line argument: %s (position: 8). Requires inputs: sulcus_prior.

output_image : a pathlike object or string representing an existing file

Cortical thickness.

N4BiasFieldCorrection

Link to code

Bases: ANTSCommand, CopyHeaderInterface

Wrapped executable: N4BiasFieldCorrection.

Bias field correction.

N4 is a variant of the popular N3 (nonparameteric nonuniform normalization) retrospective bias correction algorithm. Based on the assumption that the corruption of the low frequency bias field can be modeled as a convolution of the intensity histogram by a Gaussian, the basic algorithmic protocol is to iterate between deconvolving the intensity histogram by a Gaussian, remapping the intensities, and then spatially smoothing this result by a B-spline modeling of the bias field itself. The modifications from and improvements obtained over the original N3 algorithm are described in [Tustison2010].

[Tustison2010]

N. Tustison et al., N4ITK: Improved N3 Bias Correction, IEEE Transactions on Medical Imaging, 29(6):1310-1320, June 2010.

Examples

>>> import copy
>>> from nipype.interfaces.ants import N4BiasFieldCorrection
>>> n4 = N4BiasFieldCorrection()
>>> n4.inputs.dimension = 3
>>> n4.inputs.input_image = 'structural.nii'
>>> n4.inputs.bspline_fitting_distance = 300
>>> n4.inputs.shrink_factor = 3
>>> n4.inputs.n_iterations = [50,50,30,20]
>>> n4.cmdline
'N4BiasFieldCorrection --bspline-fitting [ 300 ]
-d 3 --input-image structural.nii
--convergence [ 50x50x30x20 ] --output structural_corrected.nii
--shrink-factor 3'

>>> n4_2 = copy.deepcopy(n4)
>>> n4_2.inputs.convergence_threshold = 1e-6
>>> n4_2.cmdline
'N4BiasFieldCorrection --bspline-fitting [ 300 ]
-d 3 --input-image structural.nii
--convergence [ 50x50x30x20, 1e-06 ] --output structural_corrected.nii
--shrink-factor 3'

>>> n4_3 = copy.deepcopy(n4_2)
>>> n4_3.inputs.bspline_order = 5
>>> n4_3.cmdline
'N4BiasFieldCorrection --bspline-fitting [ 300, 5 ]
-d 3 --input-image structural.nii
--convergence [ 50x50x30x20, 1e-06 ] --output structural_corrected.nii
--shrink-factor 3'

>>> n4_4 = N4BiasFieldCorrection()
>>> n4_4.inputs.input_image = 'structural.nii'
>>> n4_4.inputs.save_bias = True
>>> n4_4.inputs.dimension = 3
>>> n4_4.cmdline
'N4BiasFieldCorrection -d 3 --input-image structural.nii
--output [ structural_corrected.nii, structural_bias.nii ]'

>>> n4_5 = N4BiasFieldCorrection()
>>> n4_5.inputs.input_image = 'structural.nii'
>>> n4_5.inputs.dimension = 3
>>> n4_5.inputs.histogram_sharpening = (0.12, 0.02, 200)
>>> n4_5.cmdline
'N4BiasFieldCorrection -d 3  --histogram-sharpening [0.12,0.02,200]
--input-image structural.nii --output structural_corrected.nii'

copy_header : a boolean

Copy headers of the original image into the output (corrected) file. (Nipype default value: False)

input_image : a pathlike object or string representing a file

Input for bias correction. Negative values or values close to zero should be processed prior to correction. Maps to a command-line argument: --input-image %s.

save_bias : a boolean

True if the estimated bias should be saved to file. Mutually exclusive with inputs: bias_image. (Nipype default value: False)

args : a unicode string

Additional parameters to the command. Maps to a command-line argument: %s.

bias_image : a pathlike object or string representing a file

Filename for the estimated bias.

bspline_fitting_distance : a float

Maps to a command-line argument: --bspline-fitting %s.

bspline_order : an integer (int or long)

Requires inputs: bspline_fitting_distance.

convergence_threshold : a float

Requires inputs: n_iterations.

dimension : 3 or 2 or 4

Image dimension (2, 3 or 4). Maps to a command-line argument: -d %d. (Nipype default value: 3)

environ : a dictionary with keys which are a bytes or None or a value of class ‘str’ and with values which are a bytes or None or a value of class ‘str’

Environment variables. (Nipype default value: {})

histogram_sharpening : a tuple of the form: (a float, a float, an integer (int or long))

Three-values tuple of histogram sharpening parameters (FWHM, wienerNose, numberOfHistogramBins). These options describe the histogram sharpening parameters, i.e. the deconvolution step parameters described in the original N3 algorithm. The default values have been shown to work fairly well. Maps to a command-line argument: --histogram-sharpening [%g,%g,%d].

mask_image : a pathlike object or string representing a file

Image to specify region to perform final bias correction in. Maps to a command-line argument: --mask-image %s.

n_iterations : a list of items which are an integer (int or long)

Maps to a command-line argument: --convergence %s.

num_threads : an integer (int or long)

Number of ITK threads to use. (Nipype default value: 1)

output_image : a unicode string

Output file name. Maps to a command-line argument: --output %s.

rescale_intensities : a boolean

[NOTE: Only ANTs>=2.1.0] At each iteration, a new intensity mapping is calculated and applied but there is nothing which constrains the new intensity range to be within certain values. The result is that the range can “drift” from the original at each iteration. This option rescales to the [min,max] range of the original image intensities within the user-specified mask. Maps to a command-line argument: -r. (Nipype default value: False)

shrink_factor : an integer (int or long)

Maps to a command-line argument: --shrink-factor %d.

weight_image : a pathlike object or string representing a file

Image for relative weighting (e.g. probability map of the white matter) of voxels during the B-spline fitting. . Maps to a command-line argument: --weight-image %s.

bias_image : a pathlike object or string representing an existing file

Estimated bias.

output_image : a pathlike object or string representing an existing file

Warped image.