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Main Authors: Zhang, Li, Jindal, Basu, Alaa, Ahmed, Weinreb, Robert, Wilson, David, Segal, Eran, Zou, James, Xie, Pengtao
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.17421
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author Zhang, Li
Jindal, Basu
Alaa, Ahmed
Weinreb, Robert
Wilson, David
Segal, Eran
Zou, James
Xie, Pengtao
author_facet Zhang, Li
Jindal, Basu
Alaa, Ahmed
Weinreb, Robert
Wilson, David
Segal, Eran
Zou, James
Xie, Pengtao
contents Semantic segmentation of medical images is pivotal in applications like disease diagnosis and treatment planning. While deep learning has excelled in automating this task, a major hurdle is the need for numerous annotated segmentation masks, which are resource-intensive to produce due to the required expertise and time. This scenario often leads to ultra low-data regimes, where annotated images are extremely limited, posing significant challenges for the generalization of conventional deep learning methods on test images. To address this, we introduce a generative deep learning framework, which uniquely generates high-quality paired segmentation masks and medical images, serving as auxiliary data for training robust models in data-scarce environments. Unlike traditional generative models that treat data generation and segmentation model training as separate processes, our method employs multi-level optimization for end-to-end data generation. This approach allows segmentation performance to directly influence the data generation process, ensuring that the generated data is specifically tailored to enhance the performance of the segmentation model. Our method demonstrated strong generalization performance across 9 diverse medical image segmentation tasks and on 16 datasets, in ultra-low data regimes, spanning various diseases, organs, and imaging modalities. When applied to various segmentation models, it achieved performance improvements of 10-20\% (absolute), in both same-domain and out-of-domain scenarios. Notably, it requires 8 to 20 times less training data than existing methods to achieve comparable results. This advancement significantly improves the feasibility and cost-effectiveness of applying deep learning in medical imaging, particularly in scenarios with limited data availability.
format Preprint
id arxiv_https___arxiv_org_abs_2408_17421
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Generative AI Enables Medical Image Segmentation in Ultra Low-Data Regimes
Zhang, Li
Jindal, Basu
Alaa, Ahmed
Weinreb, Robert
Wilson, David
Segal, Eran
Zou, James
Xie, Pengtao
Image and Video Processing
Computer Vision and Pattern Recognition
Semantic segmentation of medical images is pivotal in applications like disease diagnosis and treatment planning. While deep learning has excelled in automating this task, a major hurdle is the need for numerous annotated segmentation masks, which are resource-intensive to produce due to the required expertise and time. This scenario often leads to ultra low-data regimes, where annotated images are extremely limited, posing significant challenges for the generalization of conventional deep learning methods on test images. To address this, we introduce a generative deep learning framework, which uniquely generates high-quality paired segmentation masks and medical images, serving as auxiliary data for training robust models in data-scarce environments. Unlike traditional generative models that treat data generation and segmentation model training as separate processes, our method employs multi-level optimization for end-to-end data generation. This approach allows segmentation performance to directly influence the data generation process, ensuring that the generated data is specifically tailored to enhance the performance of the segmentation model. Our method demonstrated strong generalization performance across 9 diverse medical image segmentation tasks and on 16 datasets, in ultra-low data regimes, spanning various diseases, organs, and imaging modalities. When applied to various segmentation models, it achieved performance improvements of 10-20\% (absolute), in both same-domain and out-of-domain scenarios. Notably, it requires 8 to 20 times less training data than existing methods to achieve comparable results. This advancement significantly improves the feasibility and cost-effectiveness of applying deep learning in medical imaging, particularly in scenarios with limited data availability.
title Generative AI Enables Medical Image Segmentation in Ultra Low-Data Regimes
topic Image and Video Processing
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2408.17421