利用容差骰子损失函数改进角膜神经分割

IF 2 4区计算机科学 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC

Signal Image and Video Processing Pub Date : 2023-10-26 DOI:10.1007/s11760-023-02790-x

Alessia Colonna, Fabio Scarpa

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引用次数: 0

摘要

体内共聚焦显微镜是一种快速、无创地获取角膜层图像的技术。对基底下神经的分析可以获得有关眼睛和人体健康的重要临床信息。为了获得这些信息，有必要正确识别和追踪神经纤维。手工分析既耗时又主观。许多自动算法已经被提出来克服这些问题，但还没有一个被纳入临床实践。在这项工作中，我们利用了深度学习技术。我们对通过UNet(基线)获得的性能进行了分析，其中添加了各种架构解决方案来提高性能。根据不同损失函数的使用，分析了跟踪结果的变化，这里介绍其中一种:它考虑容差裕度(带容差的骰子)。所研究的结构已被证明能够改善角膜神经纤维的追踪。与基线相比，具有注意力模块和阿斯特空间金字塔池模块的模型改善最大，评价分数从86.51提高到90.21%。此外，所提出的损失函数进一步提高了结果(达到92.44%)。

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Improving corneal nerve segmentation using tolerance Dice loss function

Abstract In vivo confocal microscopy is a technique that allows to acquire images of the corneal layers in a rapid and noninvasive way. Analysis of sub-basal nerve allows obtaining important clinical information regarding the eye and the human body’s health. To obtain that information, it is necessary to correctly identify and trace the nerve fibers. Manual analysis is time-consuming and subjective. Numerous automatic algorithms have been proposed to overcome these problems, but none have been included in clinical practice yet. In this work, we take advantage of deep learning techniques. We present an analysis of the performances obtained through UNet (baseline) to which various architectural solutions have been added to boost performance. The variation of the tracing results is also analyzed according to the use of different loss functions, one of which is introduced here: It considers a tolerance margin (Dice with tolerance). The investigated configurations have been shown to be capable of improving the tracing of corneal nerve fibers. The model with attention modules and atrous-spatial pyramid pooling modules showed the greatest improvement compared to the baseline, increasing in the evaluation score from 86.51 to 90.21%. Furthermore, the proposed loss function further increases the results (achieving 92.44%).

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来源期刊

Signal Image and Video Processing ENGINEERING, ELECTRICAL & ELECTRONIC-IMAGING SCIENCE & PHOTOGRAPHIC TECHNOLOGY

CiteScore

3.80

自引率

8.70%

发文量

328

审稿时长

6 months

期刊介绍： The journal is an interdisciplinary journal presenting the theory and practice of signal, image and video processing. It aims at: - Disseminating high level research results and engineering developments to all signal, image or video processing researchers and research groups. - Presenting practical solutions for the current signal, image and video processing problems in Engineering and Science. Subject areas covered by the journal include but are not limited to: Adaptive processing – biomedical signal processing – multimedia signal processing – communication signal processing – non-linear signal processing – array processing – statistics and statistical signal processing – modeling – filtering – data science – graph signal processing – multi-resolution signal analysis and wavelets – segmentation – coding – restoration – enhancement – storage and retrieval – colour and multi-spectral processing – scanning – displaying – printing – interpolation – image processing - video processing-motion detection and estimation – stereoscopic processing – image and video coding.