Nobrainer is a deep learning framework for 3D image processing. It implements several 3D convolutional models from recent literature, methods for loading and augmenting volumetric data that can be used with any TensorFlow or Keras model, losses and metrics for 3D data, and simple utilities for model training, evaluation, prediction, and transfer learning.
Nobrainer also provides pre-trained models for brain extraction, brain segmentation, brain generation and other tasks. Please see the Trained models repository for more information.
The Nobrainer project is supported by NIH RF1MH121885 and is distributed under the Apache 2.0 license. It was started under the support of NIH R01 EB020470.
- Implementations
- Guide Jupyter Notebooks
- Installation
- Using pre-trained networks
- Data augmentation
- Package layout
- Questions or issues
Model | Type | Application |
---|---|---|
Highresnet (source) | supervised | segmentation/classification |
Unet (source) | supervised | segmentation/classification |
Vnet (source) | supervised | segmentation/classification |
Meshnet (source) | supervised | segmentation/clssification |
Bayesian Meshnet (source) | bayesian supervised | segmentation/classification |
Bayesian Vnet | bayesian supervised | segmentation/classification |
Semi_Bayesian Vnet | semi-bayesian supervised | segmentation/classification |
DCGAN | self supervised | generative model |
Progressive GAN | self supervised | generative model |
3D Autoencoder | self supervised | knowledge representation/dimensionality reduction |
3D Progressive Autoencoder | self supervised | knowledge representation/dimensionality reduction |
3D SimSiam (source) | self supervised | Siamese Representation Learning |
Bernouli dropout layer, Concrete dropout layer, Gaussian dropout, Group normalization layer, Costom padding layer
Dice, Jaccard, Tversky, ELBO, Wasserstien, Gradient Penalty
Dice, Generalized Dice, Jaccard, Hamming, Tversky
Center crop, Spatial Constant Padding, Random Crop, Resize, Random flip (left and right)
Add gaussian noise, Min-Max intensity scaling, Costom intensity scaling, Intensity masking, Contrast adjustment
Afifine transformation including rotation, translation, reflection.
Please refer to the Jupyter notebooks in the guide directory to get started with Nobrainer. Try them out in Google Colaboratory!
We recommend using the official Nobrainer Docker container, which includes all of the dependencies necessary to use the framework. Please see the available images on DockerHub
The Nobrainer containers with GPU support use the Tensorflow jupyter GPU containers. Please check the containers for the version of CUDA installed. Nvidia drivers are not included in the container.
$ docker pull neuronets/nobrainer:latest-gpu
$ singularity pull docker://neuronets/nobrainer:latest-gpu
This container can be used on all systems that have Docker or Singularity and does not require special hardware. This container, however, should not be used for model training (it will be very slow).
$ docker pull neuronets/nobrainer:latest-cpu
$ singularity pull docker://neuronets/nobrainer:latest-cpu
Nobrainer can also be installed with pip.
$ pip install nobrainer
Pre-trained networks are available in the Trained models
repository. Prediction can be done on the command-line with nobrainer predict
or in Python. Similarly, generation can be done on the command-line with
nobrainer generate
or in Python.
Figure: In the first column are T1-weighted brain scans, in the middle are a trained model's predictions, and on the right are binarized FreeSurfer segmentations. Despite being trained on binarized FreeSurfer segmentations, the model outperforms FreeSurfer in the bottom scan, which exhibits motion distortion. It took about three seconds for the model to predict each brainmask using an NVIDIA GTX 1080Ti. It takes about 70 seconds on a recent CPU.
In the following examples, we will use a 3D U-Net trained for brain extraction and documented in Trained models.
In the base case, we run the T1w scan through the model for prediction.
# Get sample T1w scan.
wget -nc https://dl.dropbox.com/s/g1vn5p3grifro4d/T1w.nii.gz
docker run --rm -v $PWD:/data neuronets/nobrainer \
predict \
--model=/models/neuronets/brainy/0.1.0/brain-extraction-unet-128iso-model.h5 \
--verbose \
/data/T1w.nii.gz \
/data/brainmask.nii.gz
For binary segmentation where we expect one predicted region, as is the case with brain extraction, we can reduce false positives by removing all predictions not connected to the largest contiguous label.
# Get sample T1w scan.
wget -nc https://dl.dropbox.com/s/g1vn5p3grifro4d/T1w.nii.gz
docker run --rm -v $PWD:/data neuronets/nobrainer \
predict \
--model=/models/neuronets/brainy/0.1.0/brain-extraction-unet-128iso-model.h5 \
--largest-label \
--verbose \
/data/T1w.nii.gz \
/data/brainmask-largestlabel.nii.gz
Because the network was trained on randomly rotated data, it should be agnostic
to orientation. Therefore, we can rotate the volume, predict on it, undo the
rotation in the prediction, and average the prediction with that from the original
volume. This can lead to a better overall prediction but will at least double the
processing time. To enable this, use the flag --rotate-and-predict
in
nobrainer predict
.
# Get sample T1w scan.
wget -nc https://dl.dropbox.com/s/g1vn5p3grifro4d/T1w.nii.gz
docker run --rm -v $PWD:/data neuronets/nobrainer \
predict \
--model=/models/neuronets/brainy/0.1.0/brain-extraction-unet-128iso-model.h5 \
--rotate-and-predict \
--verbose \
/data/T1w.nii.gz \
/data/brainmask-withrotation.nii.gz
Combining the above, we can usually achieve the best brain extraction by using
--rotate-and-predict
in conjunction with --largest-label
.
# Get sample T1w scan.
wget -nc https://dl.dropbox.com/s/g1vn5p3grifro4d/T1w.nii.gz
docker run --rm -v $PWD:/data neuronets/nobrainer \
predict \
--model=/models/neuronets/brainy/0.1.0/brain-extraction-unet-128iso-model.h5 \
--largest-label \
--rotate-and-predict \
--verbose \
/data/T1w.nii.gz \
/data/brainmask-maybebest.nii.gz
Figure: Progressive generation of T1-weighted brain MR scan starting from a resolution of 32 to 256 (Left to Right: 323, 643, 1283, 2563). The brain scans are generated using the same latents in all resolutions. It took about 6 milliseconds for the model to generate the 2563 brainscan using an NVIDIA TESLA V-100.
In the following examples, we will use a Progressive Generative Adversarial Network trained for brain image generation and documented in Trained models.
In the base case, we generate a T1w scan through the model for a given resolution.
We need to pass the directory containing the models (tf.SavedModel)
created
while training the networks.
docker run --rm -v $PWD:/data neuronets/nobrainer \
generate \
--model=/models/neuronets/braingen/0.1.0 \
--output-shape=128 128 128 \
/data/generated.nii.gz
We can also generate multiple resolutions of the brain image using the same latents to visualize the progression
# Get sample T1w scan.
docker run --rm -v $PWD:/data neuronets/nobrainer \
generate \
--model=/models/neuronets/braingen/0.1.0 \
--multi-resolution \
/data/generated.nii.gz
In the above example, the multi resolution images will be saved as
generated_res_{resolution}.nii.gz
The pre-trained models can be used for transfer learning. To avoid forgetting important information in the pre-trained model, you can apply regularization to the kernel weights and also use a low learning rate. For more information, please see the Nobrainer guide notebook on transfer learning.
As an example of transfer learning, @kaczmarj re-trained a brain extraction model to label meningiomas in 3D T1-weighted, contrast-enhanced MR scans. The original model is publicly available and was trained on 10,000 T1-weighted MR brain scans from healthy participants. These were all research scans (i.e., non-clinical) and did not include any contrast agents. The meningioma dataset, on the other hand, was composed of relatively few scans, all of which were clinical and used gadolinium as a contrast agent. You can observe the differences in contrast below.
Despite the differences between the two datasets, transfer learning led to a much better model than training from randomly-initialized weights. As evidence, please see below violin plots of Dice coefficients on a validation set. In the left plot are Dice coefficients of predictions obtained with the model trained from randomly-initialized weights, and on the right are Dice coefficients of predictions obtained with the transfer-learned model. In general, Dice coefficients are higher on the right, and the variance of Dice scores is lower. Overall, the model on the right is more accurate and more robust than the one on the left.
nobrainer.io
: input/output methodsnobrainer.layers
: custom layers, which conform to the Keras APInobrainer.losses
: loss functions for volumetric segmentationnobrainer.metrics
: metrics for volumetric segmentationnobrainer.models
: pre-defined Keras modelsnobrainer.training
: training utilities (supports training on single and multiple GPUs)nobrainer.transform
: random rigid transformations for data augmentationnobrainer.volume
:tf.data.Dataset
creation and data augmentation utilities
If you use this package, please cite it.
If you have questions about Nobrainer or encounter any issues using the framework, please submit a GitHub issue.