Tools for loading, augmenting and writing 3D medical images on PyTorch.
Project description
TorchIO
torchio
is a Python package containing a set of tools to efficiently
read, sample and write 3D medical images in deep learning applications
written in PyTorch,
including intensity and spatial transforms
for data augmentation and preprocessing. Transforms include typical computer vision operations
such as random affine transformations and also domain-specific ones such as
simulation of intensity artifacts due to
MRI magnetic field inhomogeneity
or k-space motion artifacts.
This package has been greatly inspired by NiftyNet.
Jupyter notebook
The best way to quickly understand and try the library is the Jupyter notebook hosted by Google Colab. It includes many examples and visualization of most of the classes and even training of a 3D U-Net for brain segmentation of T1-weighted MRI with whole images and patch-based sampling.
Credits
If you like this repository, please click on Star!
If you used this package for your research, please cite this repository using the information available on its Zenodo entry or use this text:
Pérez-García, Fernando. (2020, January 15). fepegar/torchio: TorchIO: Tools for loading, augmenting and writing 3D medical images on PyTorch. Zenodo. http://doi.org/10.5281/zenodo.3598622
BibTeX entry:
@software{perez_garcia_fernando_2020_3598622,
author = {Pérez-García, Fernando},
title = {{fepegar/torchio: TorchIO: Tools for loading,
augmenting and writing 3D medical images on
PyTorch}},
month = jan,
year = 2020,
publisher = {Zenodo},
doi = {10.5281/zenodo.3598622},
url = {https://doi.org/10.5281/zenodo.3598622}
}
Installation
This package is on the Python Package Index (PyPI). To install the latest published version, just run the following command in a terminal:
$ pip install --upgrade torchio
Index
Features
Medical image datasets
IXI
The Information eXtraction from Images (IXI) dataset contains "nearly 600 MR images from normal, healthy subjects", including "T1, T2 and PD-weighted images, MRA images and Diffusion-weighted images (15 directions)".
The usage is very similar to torchvision.datasets
:
import torchio
import torchvision
transforms = [
torchio.ToCanonical(), # to RAS
torchio.Resample((1, 1, 1)), # to 1 mm iso
]
ixi_dataset = torchio.datasets.IXI(
'path/to/ixi_root/',
modalities=('T1', 'T2'),
transform=torchvision.transforms.Compose(transforms),
download=True,
)
print('Number of subjects in dataset:', len(ixi_dataset)) # 577
sample_subject = ixi_dataset[0]
print('Keys in subject sample:', tuple(sample_subject.keys())) # ('T1', 'T2')
print('Shape of T1 data:', sample_subject['T1'][torchio.DATA].shape) # [1, 180, 268, 268]
print('Shape of T2 data:', sample_subject['T2'][torchio.DATA].shape) # [1, 241, 257, 188]
Tiny IXI
This is the dataset used in the notebook. It is a tiny version of IXI, containing 566 T1-weighted brain MR images and their corresponding brain segmentations, all with size (83 x 44 x 55).
Data handling
ImagesDataset
ImagesDataset
is a reader of 3D medical images that directly inherits from
torch.utils.Dataset
.
It can be used with a
torch.utils.DataLoader
for efficient loading and data augmentation.
It receives a list of subjects, where each subject is an instance of
torchio.Subject
containing instances of
torchio.Image
.
The file format must be compatible with NiBabel or
SimpleITK readers.
It can also be a directory containing
DICOM files.
import torchio
from torchio import ImagesDataset, Image, Subject
subject_a = Subject([
Image('t1', '~/Dropbox/MRI/t1.nrrd', torchio.INTENSITY),
Image('label', '~/Dropbox/MRI/t1_seg.nii.gz', torchio.LABEL),
])
subject_b = Subject(
Image('t1', '/tmp/colin27_t1_tal_lin.nii.gz', torchio.INTENSITY),
Image('t2', '/tmp/colin27_t2_tal_lin.nii', torchio.INTENSITY),
Image('label', '/tmp/colin27_seg1.nii.gz', torchio.LABEL),
)
subjects_list = [subject_a, subject_b]
subjects_dataset = ImagesDataset(subjects_list)
subject_sample = subjects_dataset[0]
Samplers and aggregators
TorchIO includes grid, uniform and label patch samplers. There is also an aggregator used for dense predictions. For more information about patch-based training, see NiftyNet docs.
import torch
import torch.nn as nn
import torchio
CHANNELS_DIMENSION = 1
patch_overlap = 4
patch_size = 128
grid_sampler = torchio.inference.GridSampler(
input_data, # some PyTorch tensor or NumPy array
patch_size,
patch_overlap,
)
patch_loader = torch.utils.data.DataLoader(grid_sampler, batch_size=4)
aggregator = torchio.inference.GridAggregator(
input_data, # some PyTorch tensor or NumPy array
patch_overlap,
)
model = nn.Module()
model.to(device)
model.eval()
with torch.no_grad():
for patches_batch in patch_loader:
input_tensor = patches_batch['image'].to(device)
locations = patches_batch['location']
logits = model(input_tensor)
labels = logits.argmax(dim=CHANNELS_DIMENSION, keepdim=True)
outputs = labels
aggregator.add_batch(outputs, locations)
output_tensor = aggregator.get_output_tensor()
Queue
A patches Queue
(or buffer) can be used for randomized patch-based sampling
during training.
This interactive animation
can be used to understand how the queue works.
import torch
import torchio
patches_queue = torchio.Queue(
subjects_dataset=subjects_dataset, # instance of torchio.ImagesDataset
max_length=300,
samples_per_volume=10,
patch_size=96,
sampler_class=torchio.sampler.ImageSampler,
num_workers=4,
shuffle_subjects=True,
shuffle_patches=True,
)
patches_loader = DataLoader(patches_queue, batch_size=4)
num_epochs = 20
for epoch_index in range(num_epochs):
for patches_batch in patches_loader:
logits = model(patches_batch) # model is some torch.nn.Module
Transforms
The transforms module should remind users of
torchvision.transforms
.
TorchIO transforms take as input samples generated by an ImagesDataset
.
A transform can be quickly applied to an image file using the command-line
tool torchio-transform
:
$ torchio-transform input.nii.gz RandomMotion output.nii.gz --kwargs "proportion_to_augment=1 num_transforms=4"
Augmentation
Intensity
MRI k-space motion artifacts
Magnetic resonance images suffer from motion artifacts when the subject moves during image acquisition. This transform follows Shaw et al., 2019 to simulate motion artifacts for data augmentation.
MRI k-space ghosting artifacts
Discrete "ghost" artifacts may occur along the phase-encode direction whenever the position or signal intensity of imaged structures within the field-of-view vary or move in a regular (periodic) fashion. Pulsatile flow of blood or CSF, cardiac motion, and respiratory motion are the most important patient-related causes of ghost artifacts in clinical MR imaging (From mriquestions.com).
MRI k-space spike artifacts
Also known as Herringbone artifact, crisscross artifact or corduroy artifact, it creates stripes in different directions in image space due to spikes in k-space.
MRI magnetic field inhomogeneity
MRI magnetic field inhomogeneity creates slow frequency intensity variations. This transform is very similar to the one in NiftyNet.
Patch swap
Randomly swaps patches in the image. This is typically used in context restoration for self-supervised learning.
Gaussian noise
Adds noise sampled from a normal distribution with mean 0 and standard
deviation sampled from a uniform distribution in the range std_range
.
It is often used after ZNormalization
, as the output of
this transform has zero-mean.
Gaussian blurring
Blurs the image using a discrete Gaussian image filter.
Spatial
B-spline dense elastic deformation
Flip
Reverse the order of elements in an image along the given axes.
Affine transform
Random affine transformation of the image keeping center invariant.
Preprocessing
Histogram standardization
Implementation of New variants of a method of MRI scale standardization adapted from NiftyNet.
Rescale
Rescale intensity values in an image to a certain range.
Z-normalization
This transform first extracts the values with intensity greater than the mean, which is an approximation of the foreground voxels. Then the foreground mean is subtracted from the image and it is divided by the foreground standard deviation.
Resample
Resample images to a new voxel spacing using nibabel
.
Pad
Pad images, like in torchvision.transforms.Pad
.
Crop
Crop images passing 1, 3, or 6 integers, as in Pad.
ToCanonical
Reorder the data so that it is closest to canonical NIfTI (RAS+) orientation.
CenterCropOrPad
Crops or pads image center to a target size, modifying the affine accordingly.
Others
Lambda
Applies a user-defined function as transform.
For example, image intensity can be inverted with
Lambda(lambda x: -x, types_to_apply=[torchio.INTENSITY])
and a mask can be negated with
Lambda(lambda x: 1 - x, types_to_apply=[torchio.LABEL])
.
Example
This example shows the improvement in performance when multiple workers are used to load and preprocess the volumes using multiple workers.
import time
import multiprocessing as mp
from tqdm import trange
import torch.nn as nn
from torch.utils.data import DataLoader
from torchvision.transforms import Compose
from torchio import ImagesDataset, Queue, DATA
from torchio.data.sampler import ImageSampler
from torchio.utils import create_dummy_dataset
from torchio.transforms import (
ZNormalization,
RandomNoise,
RandomFlip,
RandomAffine,
)
# Define training and patches sampling parameters
num_epochs = 4
patch_size = 128
queue_length = 400
samples_per_volume = 10
batch_size = 4
class Network(nn.Module):
def __init__(self):
super().__init__()
self.conv = nn.Conv3d(
in_channels=1,
out_channels=3,
kernel_size=3,
)
def forward(self, x):
return self.conv(x)
model = Network()
# Create a dummy dataset in the temporary directory, for this example
subjects_list = create_dummy_dataset(
num_images=100,
size_range=(193, 229),
force=False,
)
# Each element of subjects_list is an instance of torchio.Subject:
# subject = Subject(
# torchio.Image('one_image', path_to_one_image, torchio.INTENSITY),
# torchio.Image('another_image', path_to_another_image, torchio.INTENSITY),
# torchio.Image('a_label', path_to_a_label, torchio.LABEL),
# )
# Define transforms for data normalization and augmentation
transforms = (
ZNormalization(),
RandomNoise(std_range=(0, 0.25)),
RandomAffine(scales=(0.9, 1.1), degrees=10),
RandomFlip(axes=(0,)),
)
transform = Compose(transforms)
subjects_dataset = ImagesDataset(subjects_list, transform)
# Run a benchmark for different numbers of workers
workers = range(mp.cpu_count() + 1)
for num_workers in workers:
print('Number of workers:', num_workers)
# Define the dataset as a queue of patches
queue_dataset = Queue(
subjects_dataset,
queue_length,
samples_per_volume,
patch_size,
ImageSampler,
num_workers=num_workers,
)
batch_loader = DataLoader(queue_dataset, batch_size=batch_size)
start = time.time()
for epoch_index in trange(num_epochs, leave=False):
for batch in batch_loader:
# The keys of batch have been defined in create_dummy_dataset()
inputs = batch['one_modality'][DATA]
targets = batch['segmentation'][DATA]
logits = model(inputs)
print('Time:', int(time.time() - start), 'seconds')
print()
Output:
Number of workers: 0
Time: 394 seconds
Number of workers: 1
Time: 372 seconds
Number of workers: 2
Time: 278 seconds
Number of workers: 3
Time: 259 seconds
Number of workers: 4
Time: 242 seconds
Related projects
See also
======= History
0.13.0 (24-02-2020)
- Add Subject class
- Add random blur transform
- Add lambda transform
- Add random patches swapping transform
- Add MRI k-space ghosting artefact augmentation
0.12.0 (21-01-2020)
- Add ToCanonical transform
- Add CenterCropOrPad transform
0.11.0 (15-01-2020)
- Add Resample transform
0.10.0 (15-01-2020)
- Add Pad transform
- Add Crop transform
0.9.0 (14-01-2020)
- Add CLI tool to transform an image from file
0.8.0 (11-01-2020)
- Add Image class
0.7.0 (02-01-2020)
- Make transforms use PyTorch tensors consistently
0.6.0 (02-01-2020)
- Add support for NRRD
0.5.0 (01-01-2020)
- Add bias field transform
0.4.0 (29-12-2019)
- Add MRI k-space motion artefact augmentation
0.3.0 (21-12-2019)
- Add Rescale transform
- Add support for multimodal data and missing modalities
0.2.0 (2019-12-06)
- First release on PyPI.
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