Self-Paced Learning With Diversity for Medical Image Segmentation by Using the Query-by-Committee and Dynamic Clustering Techniques

Self-Paced Learning With Diversity for Medical Image Segmentation by Using the Query-by-Committee and Dynamic Clustering Techniques

Convolutional neural networks (CNNs), as a typical deep learning technique, have been widely used in image segmentation, but they often require a large amount of annotated data. However, the number of available pixel-wise labeled medical images is extremely small, and this prevents the application o...

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Veröffentlicht in:IEEE access 2021, Vol.9, p.9834-9844
Hauptverfasser: Pan, Xiaoying, Wei, De, Zhao, Yizhe, Ma, Minjie, Wang, Hao
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Sprache:eng
Schlagworte:
Algorithms
Artificial neural networks
Clustering
Data models
deep learning
Feature extraction
Image segmentation
Machine learning
Medical diagnostic imaging
Medical imaging
Optimization
Queries
Self-paced learning
Task analysis
Training
Training data
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Wei, De
Zhao, Yizhe
Ma, Minjie
Wang, Hao
description Convolutional neural networks (CNNs), as a typical deep learning technique, have been widely used in image segmentation, but they often require a large amount of annotated data. However, the number of available pixel-wise labeled medical images is extremely small, and this prevents the application of CNNs in many medical image segmentation tasks. We proposed a self-paced learning with diversity SPLD) framework to boost the performances of medical image segmentation models with a limited amount of annotated data. Self-paced learning (SPL) is a learning regime that selects training samples in order from the easiest to the most difficult for model training. In addition, we took the diversity of the data into consideration. The proposed self-paced learning with diversity by query-by-committee (SPLD-QBC) algorithm dynamically and diversely selects the appropriate training data to boost the performance of an image segmentation model. SPLD-QBC incorporates the query-by-committee (QBC) technique for data selection and affinity propagation for optimizing the data diversity. By dynamically selecting the optimal sequence of training samples from different probability distributions, the segmentation models achieved improved performances. To verify the effectiveness of the proposed SPLD-QBC framework, we conducted experiments on three medical image segmentation tasks with five different datasets. The experimental results indicated that the proposed SPLD-QBC algorithm significantly improved upon the segmentation performances of the baseline models and resulted in a higher Dice score, surface distance and mean intersection over union (mIoU). The proposed SPLD significantly boosts the segmentation performances of models and is easily embedded into CNN-based image segmentation models.
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subjects Algorithms
Artificial neural networks
Clustering
Data models
deep learning
Feature extraction
Image segmentation
Machine learning
Medical diagnostic imaging
Medical imaging
Optimization
Queries
Self-paced learning
Task analysis
Training
Training data
title Self-Paced Learning With Diversity for Medical Image Segmentation by Using the Query-by-Committee and Dynamic Clustering Techniques
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