Usage

Instruction Video

Example

  • PyRadiomics example code and data is available in the Github repository
  • The sample data is provided in pyradiomics/data
  • Use jupyter to run the helloRadiomics example, located in pyradiomics/examples/Notebooks
  • Jupyter can also be used to run the example notebook as shown in the instruction video
    • The example notebook can be found in pyradiomics/examples/Notebooks
    • The parameter file used in the instruction video is available in pyradiomics/examples/exampleSettings
  • If jupyter is not installed, run the python script alternatives contained in the folder (pyradiomics/examples):
    • python helloRadiomics.py (segment-based extraction)
    • python helloVoxel.py (voxel-based extraction)

Voxel-based extraction

As of version 2.0, pyradiomics also implements a voxel-based extraction. It is both available from the command line and in the interactive use. See below for details.

Important to know here is that this extraction takes longer (features have to be calculated for each voxel), and that the output is a SimpleITK image of the parameter map instead of a float value for each feature.

Command Line Use

PyRadiomics can be used directly from the commandline via the entry point pyradiomics. Depending on the input provided, PyRadiomics is run in either single-extraction or batch-extraction mode. All options available on the commandline can be listed by running:

pyradiomics -h

Single image/mask

To extract features from a single image and segmentation run:

pyradiomics <path/to/image> <path/to/segmentation>

Batch Mode

To extract features from a batch run:

pyradiomics <path/to/input>

The input file for batch processing is a CSV file where the first row is contains headers and each subsequent row represents one combination of an image and a segmentation and contains at least 2 elements: 1) path/to/image, 2) path/to/mask. The headers specify the column names and must be “Image” and “Mask” for image and mask location, respectively (capital sensitive). Additional columns may also be specified, all columns are copied to the output in the same order (with calculated features appended after last column). To specify custom values for label in each combination, a column “Label” can optionally be added, which specifies the desired extraction label for each combination. Values specified in this column take precedence over label values specified in the parameter file or on the commandline. If a row contains no value, the default (or globally customized) value is used instead. Similarly, an optional value for the label_channel setting can be provided in a column “Label_channel”.

Note

All headers should be unique and different from headers provided by PyRadiomics (<filter>_<class>_<feature>). In case of conflict, values are overwritten by the PyRadiomics values.

Note

In batch processing, it is possible to speed up the process by applying multiprocessing. This is done on the case-level (i.e. each thread processes a single case). You can enable this by adding the --jobs parameter, specifying how many parallel threads you want to use.

Customization

Extraction can be customized by specifying a parameter file in the --param argument and/or by specifying override settings (only type 3 customization) in the --setting argument. Multiple overrides can be used by specifying --setting multiple times.

Output

By default, results are printed out to the console window. To store the results in a CSV-structured text file, add the -o <PATH> and -f csv arguments, where <PATH> specifies the filepath where the results should be stored. e.g.:

pyradiomics <path/to/image> <path/to/segmentation> -o results.csv -f csv
pyradiomics <path/to/input> -o results.csv -f csv

Voxel-based Radiomics

To extract feature maps (“voxel-based” extraction), simply add the argument --mode voxel. The calculated feature maps are then stored as images (NRRD format) in the current working directory. The name convention used is “Case-<idx>_<FeatureName>.nrrd”. An alternative output directory can be provided in the --out-dir command line switch. The results that are printed to the console window or the out file will still contain the diagnostic information, and the value of the extracted features is set to the location where the feature maps are stored.

Interactive Use

  • (LINUX) To run from source code, add pyradiomics to the environment variable PYTHONPATH (Not necessary when PyRadiomics is installed):

    • setenv PYTHONPATH /path/to/pyradiomics/radiomics
  • Start the python interactive session:

    • python
  • Import the necessary classes:

    import os
    
    import SimpleITK as sitk
    import six
    
    from radiomics import featureextractor, getTestCase
    
  • Set up a pyradiomics directory variable:

    dataDir = '/path/to/pyradiomics'
    
  • You will find sample data files brain1_image.nrrd and brain1_label.nrrd in that directory. Note that NRRD format used here does not mean that your image and label must always be in this format. Any format readable by ITK is suitable (e.g., NIfTI, MHA, MHD, HDR, etc). See more details in `this section of FAQ https://pyradiomics.readthedocs.io/en/latest/faq.html#what-file-types-are-supported-by-pyradiomics-for-input-image-and-mask`_.

  • Store the path of your image and mask in two variables:

    imageName, maskName = getTestCase('brain1', dataDir)
    
  • Also store the path to the file containing the extraction settings:

    params = os.path.join(dataDir, "examples", "exampleSettings", "Params.yaml")
    
  • Instantiate the feature extractor class with the parameter file:

    extractor = featureextractor.RadiomicsFeatureExtractor(params)
    
  • Calculate the features (segment-based):

    result = extractor.execute(imageName, maskName)
    for key, val in six.iteritems(result):
      print("\t%s: %s" %(key, val))
    
  • Calculate the features (voxel-based):

    result = extractor.execute(imageName, maskName, voxelBased=True)
    for key, val in six.iteritems(result):
      if isinstance(val, sitk.Image):  # Feature map
        sitk.WriteImage(val, key + '.nrrd', True)
        print("Stored feature %s in %s" % (key, key + ".nrrd"))
      else:  # Diagnostic information
        print("\t%s: %s" %(key, val))
    
  • See the feature extractor class for more information on using this core class.

PyRadiomics in 3D Slicer

A convenient front-end interface is provided as the ‘Radiomics’ extension for 3D Slicer. It is available here.

Setting Up Logging

PyRadiomics features extensive logging to help track down any issues with the extraction of features. By default PyRadiomics logging reports messages of level WARNING and up (reporting any warnings or errors that occur), and prints this to the output (stderr). By default, PyRadiomics does not create a log file.

To change the amount of information that is printed to the output, use setVerbosity() in interactive use and the optional --verbosity argument in commandline use.

When using PyRadiomics in interactive mode, enable storing the PyRadiomics logging in a file by adding an appropriate handler to the pyradiomics logger:

import radiomics

log_file = 'path/to/log_file.txt'
handler = logging.FileHandler(filename=log_file, mode='w')  # overwrites log_files from previous runs. Change mode to 'a' to append.
formatter = logging.Formatter("%(levelname)s:%(name)s: %(message)s")  # format string for log messages
handler.setFormatter(formatter)
radiomics.logger.addHandler(handler)

# Control the amount of logging stored by setting the level of the logger. N.B. if the level is higher than the
# Verbositiy level, the logger level will also determine the amount of information printed to the output
radiomics.logger.setLevel(logging.DEBUG)

To store a log file when running pyradiomics from the commandline, specify a file location in the optional --log-file argument. The amount of logging that is stored is controlled by the --logging-level argument (default level WARNING and up).