Synthetic temporal bone CT generation from UTE-MRI using a cycleGAN-based deep learning model: advancing beyond CT-MR imaging fusion.

IF 4.7 2区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING European Radiology Pub Date : 2025-01-01 Epub Date: 2024-07-18 DOI:10.1007/s00330-024-10967-2

Sung-Hye You, Yongwon Cho, Byungjun Kim, Jeeho Kim, Gi Jung Im, Euyhyun Park, InSeong Kim, Kyung Min Kim, Bo Kyu Kim

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Abstract

Objectives: The aim of this study is to develop a deep-learning model to create synthetic temporal bone computed tomography (CT) images from ultrashort echo-time magnetic resonance imaging (MRI) scans, thereby addressing the intrinsic limitations of MRI in localizing anatomic landmarks in temporal bone CT.

Materials and methods: This retrospective study included patients who underwent temporal MRI and temporal bone CT within one month between April 2020 and March 2023. These patients were randomly divided into training and validation datasets. A CycleGAN model for generating synthetic temporal bone CT images was developed using temporal bone CT and pointwise encoding-time reduction with radial acquisition (PETRA). To assess the model's performance, the pixel count in mastoid air cells was measured. Two neuroradiologists evaluated the successful generation rates of 11 anatomical landmarks.

Results: A total of 102 patients were included in this study (training dataset, n = 54, mean age 58 ± 14, 34 females (63%); validation dataset, n = 48, mean age 61 ± 13, 29 females (60%)). In the pixel count of mastoid air cells, no difference was observed between synthetic and real images (679 ± 342 vs 738 ± 342, p = 0.13). For the six major anatomical sites, the positive generation rates were 97-100%, whereas those of the five major anatomical structures ranged from 24% to 83%.

Conclusion: We developed a model to generate synthetic temporal bone CT images using PETRA MRI. This model can provide information regarding the major anatomic sites of the temporal bone using MRI.

Clinical relevance statement: The proposed algorithm addresses the primary limitations of MRI in localizing anatomic sites within the temporal bone.

Key points: CT is preferred for imaging the temporal bone, but has limitations in differentiating pathology there. The model achieved a high success rate in generating synthetic images of six anatomic sites. This can overcome the limitations of MRI in visualizing key anatomic sites in the temporal skull.

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利用基于 cycleGAN 的深度学习模型从 UTE-MRI 生成合成颞骨 CT：超越 CT-MR 成像融合。

研究目的本研究旨在开发一种深度学习模型，从超短回波时间磁共振成像（MRI）扫描中创建合成颞骨计算机断层扫描（CT）图像，从而解决 MRI 在颞骨 CT 中定位解剖标志物的内在局限性：这项回顾性研究纳入了在 2020 年 4 月至 2023 年 3 月期间一个月内接受过颞部 MRI 和颞骨 CT 检查的患者。这些患者被随机分为训练数据集和验证数据集。利用颞骨 CT 和径向采集（PETRA）的点式编码时间还原，开发了用于生成合成颞骨 CT 图像的 CycleGAN 模型。为了评估模型的性能，测量了乳突气室的像素计数。两位神经放射学专家评估了 11 个解剖标志的成功生成率：本研究共纳入 102 名患者（训练数据集，n = 54，平均年龄 58 ± 14，女性 34 人（63%）；验证数据集，n = 48，平均年龄 61 ± 13，女性 29 人（60%））。在乳突气室的像素计数方面，合成图像和真实图像之间没有差异（679 ± 342 vs 738 ± 342，p = 0.13）。六个主要解剖部位的阳性生成率为 97%-100%，而五个主要解剖结构的阳性生成率为 24%-83%：我们开发了一种利用 PETRA MRI 生成合成颞骨 CT 图像的模型。结论：我们开发了一种利用 PETRA MRI 生成合成颞骨 CT 图像的模型，该模型可利用 MRI 提供有关颞骨主要解剖部位的信息：提出的算法解决了磁共振成像在定位颞骨解剖部位方面的主要局限性：要点：CT 是颞骨成像的首选，但在区分颞骨病变方面存在局限性。该模型在生成六个解剖部位的合成图像方面取得了很高的成功率。这可以克服核磁共振成像在观察颞骨关键解剖部位方面的局限性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

European Radiology 医学-核医学

CiteScore

11.60

自引率

8.50%

发文量

874

审稿时长

2-4 weeks

期刊介绍： European Radiology (ER) continuously updates scientific knowledge in radiology by publication of strong original articles and state-of-the-art reviews written by leading radiologists. A well balanced combination of review articles, original papers, short communications from European radiological congresses and information on society matters makes ER an indispensable source for current information in this field. This is the Journal of the European Society of Radiology, and the official journal of a number of societies. From 2004-2008 supplements to European Radiology were published under its companion, European Radiology Supplements, ISSN 1613-3749.