Feasibility of generating sagittal radiographs from coronal views using GAN-based deep learning framework in adolescent idiopathic scoliosis.

IF 3.6 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING European Radiology Experimental Pub Date : 2025-01-29 DOI:10.1186/s41747-025-00553-6

Tito Bassani, Andrea Cina, Fabio Galbusera, Andrea Cazzato, Maria Elena Pellegrino, Domenico Albano, Luca Maria Sconfienza

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Abstract

Background: Minimizing radiation exposure is crucial in monitoring adolescent idiopathic scoliosis (AIS). Generative adversarial networks (GANs) have emerged as valuable tools being able to generate high-quality synthetic images. This study explores the use of GANs to generate synthetic sagittal radiographs from coronal views in AIS patients.

Methods: A dataset of 3,935 AIS patients who underwent spine and pelvis radiographic examinations using the EOS system, which simultaneously acquires coronal and sagittal images, was analyzed. The dataset was divided into training-set (85%, n = 3,356) and test-set (15%, n = 579). GAN model was trained to generate sagittal images from coronal views, with real sagittal views as reference standard. To assess accuracy, 100 subjects from the test-set were randomly selected for manual measurement of lumbar lordosis (LL), sacral slope (SS), pelvic incidence (PI), and sagittal vertical axis (SVA) by two radiologists in both synthetic and real images.

Results: Sixty-nine synthetic images were considered assessable. The intraclass correlation coefficient ranged 0.93-0.99 for measurements in real images, and from 0.83 to 0.88 for synthetic images. Correlations between parameters of real and synthetic images were 0.52 (LL), 0.17 (SS), 0.18 (PI), and 0.74 (SVA). Measurement errors showed minimal correlation with scoliosis severity. Mean ± standard deviation absolute errors were 7 ± 7° (LL), 9 ± 7° (SS), 9 ± 8° (PI), and 1.1 ± 0.8 cm (SVA).

Conclusion: While the model generates sagittal images visually consistent with reference images, their quality is not sufficient for clinical parameter assessment, except for promising results in SVA.

Relevance statement: AI can generate synthetic sagittal radiographs from coronal views to reduce radiation exposure in monitoring adolescent idiopathic scoliosis (AIS). However, while these synthetic images appear visually consistent with real ones, their quality remains insufficient for accurate clinical assessment.

Key points: AI can be exploited to generate synthetic sagittal radiographs from coronal views. Dataset of 3,935 subjects was used to train and test AI-model; spinal parameters from synthetic and real images were compared. Synthetic images were visually consistent with real ones, but quality was generally insufficient for accurate clinical assessment.

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基于gan的深度学习框架在青少年特发性脊柱侧凸中从冠状面生成矢状面x线片的可行性。

背景：减少辐射暴露是监测青少年特发性脊柱侧凸（AIS）的关键。生成对抗网络（GANs）已经成为能够生成高质量合成图像的有价值的工具。本研究探讨了使用gan从AIS患者的冠状位视图生成合成矢状位x线片。方法：对3,935名AIS患者的数据集进行分析，这些患者使用EOS系统进行脊柱和骨盆放射检查，同时获得冠状和矢状图像。数据集分为训练集（85%,n = 3356）和测试集（15%,n = 579）。以真实矢状面图像为参考标准，训练GAN模型从冠状面生成矢状面图像。为了评估准确性，从测试集中随机选择100名受试者，由两名放射科医生在合成和真实图像中手动测量腰椎前凸（LL）、骶骨斜率（SS）、骨盆发生率（PI）和矢状垂直轴（SVA）。结果：69幅合成图像被认为是可评估的。真实图像的类内相关系数为0.93 ~ 0.99，合成图像的类内相关系数为0.83 ~ 0.88。真实图像与合成图像的相关系数分别为0.52 （LL）、0.17 （SS）、0.18 （PI）和0.74 （SVA）。测量误差显示与脊柱侧凸严重程度的相关性很小。均值±标准差绝对错误7±7°(LL), 9±7°(SS)、9±8°(π)和1.1±0.8厘米(上海广电)。结论：虽然该模型生成的矢状面图像视觉上与参考图像一致，但其质量不足以用于临床参数评估，但在SVA方面效果良好。相关性声明：人工智能可以从冠状位视图生成合成矢状位x线片，以减少监测青少年特发性脊柱侧凸（AIS）时的辐射暴露。然而，虽然这些合成图像在视觉上与真实图像一致，但其质量仍不足以进行准确的临床评估。重点：人工智能可以利用冠状面生成合成矢状面x线片。使用3,935名受试者的数据集对ai模型进行训练和测试；比较了合成图像和真实图像的脊柱参数。合成图像在视觉上与真实图像一致，但质量普遍不足，无法进行准确的临床评估。

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