Woon Dixon, Qin Shane, Al-Khanaty Abdullah, Perera Marlon, Lawrentschuk Nathan
Department of Urology, Austin Health, Heidelberg, VIC 3084, Australia.
Department of Surgery, The University of Melbourne, Melbourne, VIC 3010, Australia.
Diagnostics (Basel). 2024 Sep 23;14(18):2105. doi: 10.3390/diagnostics14182105.
Imaging in renal cell carcinoma (RCC) is a constantly evolving landscape. The incidence of RCC has been rising over the years with the improvement in image quality and sensitivity in imaging modalities resulting in "incidentalomas" being detected. We aim to explore the latest advances in imaging for RCC.
A literature search was conducted using Medline and Google Scholar, up to May 2024. For each subsection of the manuscript, a separate search was performed using a combination of the following key terms "renal cell carcinoma", "renal mass", "ultrasound", "computed tomography", "magnetic resonance imaging", "18F-Fluorodeoxyglucose PET/CT", "prostate-specific membrane antigen PET/CT", "technetium-99m sestamibi SPECT/CT", "carbonic anhydrase IX", "girentuximab", and "radiomics". Studies that were not in English were excluded. The reference lists of selected manuscripts were checked manually for eligible articles.
The main imaging modalities for RCC currently are ultrasound, computed tomography (CT) and magnetic resonance imaging (MRI). Contrast-enhanced US (CEUS) has emerged as an alternative to CT or MRI for the characterisation of renal masses. Furthermore, there has been significant research in molecular imaging in recent years, including FDG PET, PSMA PET/CT, Tc-Sestamibi, and anti-carbonic anhydrase IX monoclonal antibodies/peptides. Radiomics and the use of AI in radiology is a growing area of interest.
There will be significant change in the field of imaging in RCC as molecular imaging becomes increasingly popular, which reflects a shift in management to a more conservative approach, especially for small renal masses (SRMs). There is the hope that the improvement in imaging will result in less unnecessary invasive surgeries or biopsies being performed for benign or indolent renal lesions.
肾细胞癌(RCC)的影像学检查是一个不断发展的领域。多年来,随着成像方式的图像质量和灵敏度提高,RCC的发病率一直在上升,导致“偶然瘤”被发现。我们旨在探讨RCC影像学的最新进展。
截至2024年5月,使用Medline和谷歌学术进行文献检索。对于手稿的每个小节,使用以下关键词组合进行单独检索:“肾细胞癌”、“肾肿块”、“超声”、“计算机断层扫描”、“磁共振成像”、“18F-氟脱氧葡萄糖PET/CT”、“前列腺特异性膜抗原PET/CT”、“锝-99m甲氧基异丁基异腈SPECT/CT”、“碳酸酐酶IX”、“吉妥昔单抗”和“放射组学”。排除非英文研究。手动检查所选手稿的参考文献列表以查找符合条件的文章。
目前RCC的主要成像方式是超声、计算机断层扫描(CT)和磁共振成像(MRI)。超声造影(CEUS)已成为CT或MRI之外用于肾肿块特征性诊断的替代方法。此外,近年来分子成像领域有大量研究,包括FDG PET、PSMA PET/CT、锝-甲氧基异丁基异腈和抗碳酸酐酶IX单克隆抗体/肽。放射组学以及人工智能在放射学中的应用是一个日益受到关注的领域。
随着分子成像越来越受欢迎,RCC影像学领域将发生重大变化,这反映了管理方式向更保守方法的转变,尤其是对于小肾肿块(SRM)。人们希望成像技术的改进将减少对良性或惰性肾病变进行不必要的侵入性手术或活检。
