3 research outputs found
Test-time augmentation-based active learning and self-training for label-efficient segmentation
Deep learning techniques depend on large datasets whose annotation is
time-consuming. To reduce annotation burden, the self-training (ST) and
active-learning (AL) methods have been developed as well as methods that
combine them in an iterative fashion. However, it remains unclear when each
method is the most useful, and when it is advantageous to combine them. In this
paper, we propose a new method that combines ST with AL using Test-Time
Augmentations (TTA). First, TTA is performed on an initial teacher network.
Then, cases for annotation are selected based on the lowest estimated Dice
score. Cases with high estimated scores are used as soft pseudo-labels for ST.
The selected annotated cases are trained with existing annotated cases and ST
cases with border slices annotations. We demonstrate the method on MRI fetal
body and placenta segmentation tasks with different data variability
characteristics. Our results indicate that ST is highly effective for both
tasks, boosting performance for in-distribution (ID) and out-of-distribution
(OOD) data. However, while self-training improved the performance of
single-sequence fetal body segmentation when combined with AL, it slightly
deteriorated performance of multi-sequence placenta segmentation on ID data. AL
was helpful for the high variability placenta data, but did not improve upon
random selection for the single-sequence body data. For fetal body segmentation
sequence transfer, combining AL with ST following ST iteration yielded a Dice
of 0.961 with only 6 original scans and 2 new sequence scans. Results using
only 15 high-variability placenta cases were similar to those using 50 cases.
Code is available at: https://github.com/Bella31/TTA-quality-estimation-ST-ALComment: Accepted to MICCAI MILLanD workshop 202
Fetal Brain Tissue Annotation and Segmentation Challenge Results
In-utero fetal MRI is emerging as an important tool in the diagnosis and
analysis of the developing human brain. Automatic segmentation of the
developing fetal brain is a vital step in the quantitative analysis of prenatal
neurodevelopment both in the research and clinical context. However, manual
segmentation of cerebral structures is time-consuming and prone to error and
inter-observer variability. Therefore, we organized the Fetal Tissue Annotation
(FeTA) Challenge in 2021 in order to encourage the development of automatic
segmentation algorithms on an international level. The challenge utilized FeTA
Dataset, an open dataset of fetal brain MRI reconstructions segmented into
seven different tissues (external cerebrospinal fluid, grey matter, white
matter, ventricles, cerebellum, brainstem, deep grey matter). 20 international
teams participated in this challenge, submitting a total of 21 algorithms for
evaluation. In this paper, we provide a detailed analysis of the results from
both a technical and clinical perspective. All participants relied on deep
learning methods, mainly U-Nets, with some variability present in the network
architecture, optimization, and image pre- and post-processing. The majority of
teams used existing medical imaging deep learning frameworks. The main
differences between the submissions were the fine tuning done during training,
and the specific pre- and post-processing steps performed. The challenge
results showed that almost all submissions performed similarly. Four of the top
five teams used ensemble learning methods. However, one team's algorithm
performed significantly superior to the other submissions, and consisted of an
asymmetrical U-Net network architecture. This paper provides a first of its
kind benchmark for future automatic multi-tissue segmentation algorithms for
the developing human brain in utero.Comment: Results from FeTA Challenge 2021, held at MICCAI; Manuscript
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