开发用于自动检测双能量 CT 扫描中痛风绿色像素的深度学习模型

Research in diagnostic and interventional imaging Pub Date : 2024-03-01 DOI:10.1016/j.redii.2024.100044

Shahriar Faghani , Rhodes G. Nicholas , Soham Patel , Francis I. Baffour , Mana Moassefi , Pouria Rouzrokh , Bardia Khosravi , Garret M. Powell , Shuai Leng , Katrina N. Glazebrook , Bradley J. Erickson , Christin A. Tiegs-Heiden

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引用次数: 0

摘要

背景双能 CT（DECT）是在痛风检查中确定是否存在单钠尿酸盐（MSU）结晶的一种无创方法。在材料分解和后处理之后，颜色编码可将 MSU 与钙区分开来。大多数软件将 MSU 标为绿色，将钙标为蓝色。目前的图像处理方法在分割绿色编码像素方面存在局限性。此外，识别绿色病灶非常繁琐，自动检测可改善工作流程。本研究旨在确定在 DECTs 上分割 MSU 晶体绿色编码像素的最佳深度学习（DL）算法。数据集分为训练集（N = 28）和保持测试集（N = 30）。为了进行交叉验证，训练集被分成了七个褶皱。将图像展示给两名肌肉骨骼放射科医生，由他们独立识别绿色编码体素。结果Segresnet表现优异，背景像素的DSC为0.9999，绿色像素的DSC为0.7868，两类像素的平均DSC为0.8934。根据后处理结果，Segresnet 的体素级灵敏度和特异度分别达到了 98.72 % 和 99.98 %。Segresnet 的性能指标更优越。所开发的算法提供了一种潜在的快速、一致、高灵敏度和特异性的计算机辅助诊断工具。最终，放射科医生可以利用这种算法简化 DECT 工作流程，提高痛风检测的准确性。

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Development of a deep learning model for the automated detection of green pixels indicative of gout on dual energy CT scan

Background

Dual-energy CT (DECT) is a non-invasive way to determine the presence of monosodium urate (MSU) crystals in the workup of gout. Color-coding distinguishes MSU from calcium following material decomposition and post-processing. Most software labels MSU as green and calcium as blue. There are limitations in the current image processing methods of segmenting green-encoded pixels. Additionally, identifying green foci is tedious, and automated detection would improve workflow. This study aimed to determine the optimal deep learning (DL) algorithm for segmenting green-encoded pixels of MSU crystals on DECTs.

Methods

DECT images of positive and negative gout cases were retrospectively collected. The dataset was split into train (N = 28) and held-out test (N = 30) sets. To perform cross-validation, the train set was split into seven folds. The images were presented to two musculoskeletal radiologists, who independently identified green-encoded voxels. Two 3D Unet-based DL models, Segresnet and SwinUNETR, were trained, and the Dice similarity coefficient (DSC), sensitivity, and specificity were reported as the segmentation metrics.

Results

Segresnet showed superior performance, achieving a DSC of 0.9999 for the background pixels, 0.7868 for the green pixels, and an average DSC of 0.8934 for both types of pixels, respectively. According to the post-processed results, the Segresnet reached voxel-level sensitivity and specificity of 98.72 % and 99.98 %, respectively.

Conclusion

In this study, we compared two DL-based segmentation approaches for detecting MSU deposits in a DECT dataset. The Segresnet resulted in superior performance metrics. The developed algorithm provides a potential fast, consistent, highly sensitive and specific computer-aided diagnosis tool. Ultimately, such an algorithm could be used by radiologists to streamline DECT workflow and improve accuracy in the detection of gout.

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Research in diagnostic and interventional imaging Radiology and Imaging

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