Anomaly detection (AD) is the identification of data samples that do not fit
a learned data distribution. As such, AD systems can help physicians to
determine the presence, severity, and extension of a pathology. Deep generative
models, such as Generative Adversarial Networks (GANs), can be exploited to
capture anatomical variability. Consequently, any outlier (i.e., sample falling
outside of the learned distribution) can be detected as an abnormality in an
unsupervised fashion. By using this method, we can not only detect expected or
known lesions, but we can even unveil previously unrecognized biomarkers. To
the best of our knowledge, this study exemplifies the first AD approach that
can efficiently handle volumetric data and detect 3D brain anomalies in one
single model. Our proposal is a volumetric and high-detail extension of the 2D
f-AnoGAN model obtained by combining a state-of-the-art 3D GAN with refinement
training steps. In experiments using non-contrast computed tomography images
from traumatic brain injury (TBI) patients, the model detects and localizes TBI
abnormalities with an area under the ROC curve of ~75%. Moreover, we test the
potential of the method for detecting other anomalies such as low quality
images, preprocessing inaccuracies, artifacts, and even the presence of
post-operative signs (such as a craniectomy or a brain shunt). The method has
potential for rapidly labeling abnormalities in massive imaging datasets, as
well as identifying new biomarkers.Comment: Accepted at BrainLes Workshop in MICCAI 202