Thymic Imaging Pitfalls and Strategies for Optimized Diagnosis

IF 5.2 1区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Radiographics Pub Date : 2024-04-11 DOI:10.1148/rg.230091

Maximiliano Klug, Chad D. Strange, Mylene T. Truong, Zehavit Kirshenboim, Efrat Ofek, Eli Konen, Edith Michelle Marom

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Abstract

Thymic imaging is challenging because the imaging appearance of a variety of benign and malignant thymic conditions are similar. CT is the most commonly used modality for mediastinal imaging, while MRI and fluorine 18 fluorodeoxyglucose (FDG) PET/CT are helpful when they are tailored to the correct indication. Each of these imaging modalities has limitations and technical pitfalls that may lead to an incorrect diagnosis and mismanagement. CT may not be sufficient for the characterization of cystic thymic processes and differentiation between thymic hyperplasia and thymic tumors. MRI can be used to overcome these limitations but is subject to other potential pitfalls such as an equivocal decrease in signal intensity at chemical shift imaging, size limitations, unusual signal intensity for cysts, subtraction artifacts, pseudonodularity on T2-weighted MR images, early imaging misinterpretation, flow and spatial resolution issues hampering assessment of local invasion, and the overlap of apparent diffusion coefficients between malignant and benign thymic entities. FDG PET/CT is not routinely indicated due to some overlap in FDG uptake between thymomas and benign thymic processes. However, it is useful for staging and follow-up of aggressive tumors (eg, thymic carcinoma), particularly for detection of occult metastatic disease. Pitfalls in imaging after treatment of thymic malignancies relate to technical challenges such as postthymectomy sternotomy streak metal artifacts, differentiation of postsurgical thymic bed changes from tumor recurrence, or human error with typical “blind spots” for identification of metastatic disease. Understanding these pitfalls enables appropriate selection of imaging modalities, improves diagnostic accuracy, and guides patient treatment.

^©RSNA, 2024

Test Your Knowledge questions for this article are available in the supplemental material.

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胸腺成像陷阱与优化诊断策略

胸腺成像具有挑战性，因为各种良性和恶性胸腺疾病的成像表现相似。CT 是纵隔成像最常用的方式，而磁共振成像和 18 氟脱氧葡萄糖 (FDG) PET/CT 在适应症正确的情况下也很有帮助。每种成像方式都有其局限性和技术缺陷，可能导致诊断错误和处理不当。CT 可能不足以确定胸腺囊性过程的特征以及区分胸腺增生和胸腺肿瘤。核磁共振成像可用于克服这些局限性，但也存在其他潜在的缺陷，如化学位移成像时信号强度下降不明显、尺寸限制、囊肿信号强度异常、减影伪影、T2加权核磁共振成像上的假结节、早期成像误读、血流和空间分辨率问题妨碍对局部侵犯的评估，以及恶性和良性胸腺实体之间表观扩散系数的重叠。由于胸腺瘤和良性胸腺过程的 FDG 摄取存在一些重叠，因此 FDG PET/CT 并非常规检查方法。不过，它对侵袭性肿瘤（如胸腺癌）的分期和随访非常有用，尤其是在检测隐匿性转移性疾病时。胸腺恶性肿瘤治疗后成像的缺陷与技术挑战有关，如胸腺切除术后胸骨条纹金属伪影、手术后胸腺床变化与肿瘤复发的鉴别，或识别转移性疾病典型 "盲点 "的人为错误。了解这些误区有助于适当选择成像方式、提高诊断准确性并指导患者治疗。©RSNA，2024本文的 "知识测试 "问题可在补充材料中找到。

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

Radiographics 医学-核医学

CiteScore

8.20

自引率

5.50%

发文量

224

审稿时长

4-8 weeks

期刊介绍： Launched by the Radiological Society of North America (RSNA) in 1981, RadioGraphics is one of the premier education journals in diagnostic radiology. Each bimonthly issue features 15–20 practice-focused articles spanning the full spectrum of radiologic subspecialties and addressing topics such as diagnostic imaging techniques, imaging features of a disease or group of diseases, radiologic-pathologic correlation, practice policy and quality initiatives, imaging physics, informatics, and lifelong learning. A special issue, a monograph focused on a single subspecialty or on a crossover topic of interest to multiple subspecialties, is published each October. Each issue offers more than a dozen opportunities to earn continuing medical education credits that qualify for AMA PRA Category 1 CreditTM and all online activities can be applied toward the ABR MOC Self-Assessment Requirement.