English

A self-supervised learning strategy for postoperative brain cavity segmentation simulating resections

Image and Video Processing 2021-06-04 v1 Computer Vision and Pattern Recognition

Abstract

Accurate segmentation of brain resection cavities (RCs) aids in postoperative analysis and determining follow-up treatment. Convolutional neural networks (CNNs) are the state-of-the-art image segmentation technique, but require large annotated datasets for training. Annotation of 3D medical images is time-consuming, requires highly-trained raters, and may suffer from high inter-rater variability. Self-supervised learning strategies can leverage unlabeled data for training. We developed an algorithm to simulate resections from preoperative magnetic resonance images (MRIs). We performed self-supervised training of a 3D CNN for RC segmentation using our simulation method. We curated EPISURG, a dataset comprising 430 postoperative and 268 preoperative MRIs from 430 refractory epilepsy patients who underwent resective neurosurgery. We fine-tuned our model on three small annotated datasets from different institutions and on the annotated images in EPISURG, comprising 20, 33, 19 and 133 subjects. The model trained on data with simulated resections obtained median (interquartile range) Dice score coefficients (DSCs) of 81.7 (16.4), 82.4 (36.4), 74.9 (24.2) and 80.5 (18.7) for each of the four datasets. After fine-tuning, DSCs were 89.2 (13.3), 84.1 (19.8), 80.2 (20.1) and 85.2 (10.8). For comparison, inter-rater agreement between human annotators from our previous study was 84.0 (9.9). We present a self-supervised learning strategy for 3D CNNs using simulated RCs to accurately segment real RCs on postoperative MRI. Our method generalizes well to data from different institutions, pathologies and modalities. Source code, segmentation models and the EPISURG dataset are available at https://github.com/fepegar/ressegijcars .

Keywords

Cite

@article{arxiv.2105.11239,
  title  = {A self-supervised learning strategy for postoperative brain cavity segmentation simulating resections},
  author = {Fernando Pérez-García and Reuben Dorent and Michele Rizzi and Francesco Cardinale and Valerio Frazzini and Vincent Navarro and Caroline Essert and Irène Ollivier and Tom Vercauteren and Rachel Sparks and John S. Duncan and Sébastien Ourselin},
  journal= {arXiv preprint arXiv:2105.11239},
  year   = {2021}
}

Comments

To be published in the International Journal of Computer Assisted Radiology and Surgery (IJCARS) - Special issue MICCAI 2020

R2 v1 2026-06-24T02:24:16.882Z