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Main Authors: Jiang, Liuyun, Zhang, Yanchao, Guo, Jinyue, Lu, Yizhuo, Zhou, Ruining, Han, Hua
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.15779
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author Jiang, Liuyun
Zhang, Yanchao
Guo, Jinyue
Lu, Yizhuo
Zhou, Ruining
Han, Hua
author_facet Jiang, Liuyun
Zhang, Yanchao
Guo, Jinyue
Lu, Yizhuo
Zhou, Ruining
Han, Hua
contents Neuron segmentation in electron microscopy (EM) aims to reconstruct the complete neuronal connectome; however, current deep learning-based methods are limited by their reliance on large-scale training data and extensive, time-consuming manual annotations. Traditional methods augment the training set through geometric and photometric transformations; however, the generated samples remain highly correlated with the original images and lack structural diversity. To address this limitation, we propose a diffusion-based data augmentation framework capable of generating diverse and structurally plausible image-label pairs for neuron segmentation. Specifically, the framework employs a resolution-aware conditional diffusion model with multi-scale conditioning and EM resolution priors to enable voxel-level image synthesis from 3D masks. It further incorporates a biology-guided mask remodeling module that produces augmented masks with enhanced structural realism. Together, these components effectively enrich the training set and improve segmentation performance. On the AC3 and AC4 datasets under low-annotation regimes, our method improves the ARAND metric by 32.1% and 30.7%, respectively, when combined with two different post-processing methods. Our code is available at https://github.com/HeadLiuYun/NeuroDiff.
format Preprint
id arxiv_https___arxiv_org_abs_2601_15779
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Diffusion Model-Based Data Augmentation for Enhanced Neuron Segmentation
Jiang, Liuyun
Zhang, Yanchao
Guo, Jinyue
Lu, Yizhuo
Zhou, Ruining
Han, Hua
Computer Vision and Pattern Recognition
Neuron segmentation in electron microscopy (EM) aims to reconstruct the complete neuronal connectome; however, current deep learning-based methods are limited by their reliance on large-scale training data and extensive, time-consuming manual annotations. Traditional methods augment the training set through geometric and photometric transformations; however, the generated samples remain highly correlated with the original images and lack structural diversity. To address this limitation, we propose a diffusion-based data augmentation framework capable of generating diverse and structurally plausible image-label pairs for neuron segmentation. Specifically, the framework employs a resolution-aware conditional diffusion model with multi-scale conditioning and EM resolution priors to enable voxel-level image synthesis from 3D masks. It further incorporates a biology-guided mask remodeling module that produces augmented masks with enhanced structural realism. Together, these components effectively enrich the training set and improve segmentation performance. On the AC3 and AC4 datasets under low-annotation regimes, our method improves the ARAND metric by 32.1% and 30.7%, respectively, when combined with two different post-processing methods. Our code is available at https://github.com/HeadLiuYun/NeuroDiff.
title Diffusion Model-Based Data Augmentation for Enhanced Neuron Segmentation
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2601.15779