Training on Polar Image Transformations Improves Biomedical Image Segmentation

Benčević, Marin; Galić, Irena; Habijan, Marija; Babin, Danilo

doi:10.1109/access.2021.3116265

Cited by 44 publications

(24 citation statements)

References 24 publications

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“…We show that this method is comparable to the state-of-theart aorta segmentation methods while being robust to small dataset sizes. In addition, we extend the method presented in [1] and further validate the use of polar transformations in neural networks for medical image segmentation. These modifications can be used to improve performance in a wide variety of medical image processing tasks where multiple elliptical objects need to be segmented, and can be added to existing methods for 2D image semantic segmentation without changing the underlying architecture.…”

Section: Introductionmentioning

confidence: 76%

“…We then sum all of the weighted images together. As shown in [1], the polar network generally performs best on objects which contain the polar origin, and worse at predicting other objects on the image. Therefore, we assign a larger weight to that component as a proxy for a confidence measure.…”

Section: Methodsmentioning

confidence: 97%

“…The work presented in this paper is an extension of [1]. We obtain the center points of the objects in the image using a rough segmentation from a U-Net-based network, instead of using a center point predictor as is described in the original paper.…”

Section: Methodsmentioning

confidence: 99%

“…The method presented in this paper is an extension and improvement over the method presented in [1]. The method uses a neural network to predict the center point of a single object in an input image.…”

Section: A Related Workmentioning

confidence: 99%

“…All models were trained for 60 epochs with checkpointing where the model with the best validation Dice coefficient was selected. We use the Dice loss function as described in [1]. All of the code, as well as the trained networks, can be found at github.com/marinbenc/medical-polar-training…”

Section: B Implementation Detailsmentioning

confidence: 99%

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Using the Polar Transform for Efficient Deep Learning-Based Aorta Segmentation in CTA Images

Benčević¹,

Habijan²,

Galić³

et al. 2022

Preprint

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Medical image segmentation often requires segmenting multiple elliptical objects on a single image. This includes, among other tasks, segmenting vessels such as the aorta in axial CTA slices. In this paper, we present a general approach to improving the semantic segmentation performance of neural networks in these tasks and validate our approach on the task of aorta segmentation. We use a cascade of two neural networks, where one performs a rough segmentation based on the U-Net architecture and the other performs the final segmentation on polar image transformations of the input. Connected component analysis of the rough segmentation is used to construct the polar transformations, and predictions on multiple transformations of the same image are fused using hysteresis thresholding. We show that this method improves aorta segmentation performance without requiring complex neural network architectures. In addition, we show that our approach improves robustness and pixel-level recall while achieving segmentation performance in line with the state of the art.

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Section: Introductionmentioning

confidence: 76%

Section: Methodsmentioning

confidence: 97%

Section: Methodsmentioning

confidence: 99%

Section: A Related Workmentioning

confidence: 99%

Section: B Implementation Detailsmentioning

confidence: 99%

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Using the Polar Transform for Efficient Deep Learning-Based Aorta Segmentation in CTA Images

Benčević¹,

Habijan²,

Galić³

et al. 2022

Preprint

Self Cite

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EPolar‐UNet: An edge‐attending polar UNet for automatic medical image segmentation with small datasets

Ling,

Wang,

liu

et al. 2024

Medical Physics

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BackgroundMedical image segmentation is one of the most key steps in computer‐aided clinical diagnosis, geometric characterization, measurement, image registration, and so forth. Convolutional neural networks especially UNet and its variants have been successfully used in many medical image segmentation tasks. However, the results are limited by the deficiency in extracting high resolution edge information because of the design of the skip connections in UNet and the need for large available datasets.PurposeIn this paper, we proposed an edge‐attending polar UNet (EPolar‐UNet), which was trained on the polar coordinate system instead of classic Cartesian coordinate system with an edge‐attending construction in skip connection path.MethodsEPolar‐UNet extracted the location information from an eight‐stacked hourglass network as the pole for polar transformation and extracted the boundary cues from an edge‐attending UNet, which consisted of a deconvolution layer and a subtraction operation.ResultsWe evaluated the performance of EPolar‐UNet across three imaging modalities for different segmentation tasks: CVC‐ClinicDB dataset for polyp, ISIC‐2018 dataset for skin lesion, and our private ultrasound dataset for liver tumor segmentation. Our proposed model outperformed state‐of‐the‐art models on all three datasets and needed only 30%–60% of training data compared with the benchmark UNet model to achieve similar performances for medical image segmentation tasks.ConclusionsWe proposed an end‐to‐end EPolar‐UNet for automatic medical image segmentation and showed good performance on small datasets, which was critical in the field of medical image segmentation.

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Comparison of Selected Neural Network Models Used for Automatic Liver Tumor Segmentation

Kwiatkowski,

Dziubich

2023

Communications in Computer and Information Science

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Training on Polar Image Transformations Improves Biomedical Image Segmentation

Cited by 44 publications

References 24 publications

Using the Polar Transform for Efficient Deep Learning-Based Aorta Segmentation in CTA Images

Using the Polar Transform for Efficient Deep Learning-Based Aorta Segmentation in CTA Images

EPolar‐UNet: An edge‐attending polar UNet for automatic medical image segmentation with small datasets

Comparison of Selected Neural Network Models Used for Automatic Liver Tumor Segmentation

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