Department of Clinical Physiology and Nuclear Medicine & Cluster for Molecular Imaging, Copenhagen University Hospital-Rigshospitalet & Department of Biomedical Sciences, University of Copenhagen, Copenhagen, Denmark.
ENETS Neuroendocrine Tumor Center of Excellence, Copenhagen University Hospital-Rigshospitalet, Copenhagen, Denmark.
J Nucl Med. 2023 Jun;64(6):951-959. doi: 10.2967/jnumed.122.264826. Epub 2023 May 11.
Frequent somatostatin receptor PET, for example, Cu-DOTATATE PET, is part of the diagnostic work-up of patients with neuroendocrine neoplasms (NENs), resulting in high accumulated radiation doses. Scan-related radiation exposure should be minimized in accordance with the as-low-as-reasonably achievable principle, for example, by reducing injected radiotracer activity. Previous investigations found that reducing Cu-DOTATATE activity to below 50 MBq results in inadequate image quality and lesion detection. We therefore investigated whether image quality and lesion detection of less than 50 MBq of Cu-DOTATATE PET could be restored using artificial intelligence (AI). We implemented a parameter-transferred Wasserstein generative adversarial network for patients with NENs on simulated low-dose Cu-DOTATATE PET images corresponding to 25% (PET), or about 48 MBq, of the injected activity of the reference full dose (PET), or about 191 MBq, to generate denoised PET images (PET). We included 38 patients in the training sets for network optimization. We analyzed PET intensity correlation, peak signal-to-noise ratio (PSNR), structural similarity index (SSIM), and mean-square error (MSE) of PET/PET versus PET/PET Two readers assessed Likert scale-defined image quality (1, very poor; 2, poor; 3, moderate; 4, good; 5, excellent) and identified lesion-suspicious foci on PET and PET in a subset of the patients with no more than 20 lesions per organ ( = 33) to allow comparison of all foci on a 1:1 basis. Detected foci were scored (C, definite lesion; C, lesion-suspicious focus) and matched with PET as the reference. True-positive (TP), false-positive (FP), and false-negative (FN) lesions were assessed. For PET/PET versus PET/PET, PET intensity correlation had a goodness-of-fit value of 0.94 versus 0.81, PSNR was 58.1 versus 53.0, SSIM was 0.908 versus 0.899, and MSE was 2.6 versus 4.7. Likert scale-defined image quality was rated good or excellent in 33 of 33 and 32 of 33 patients on PET and PET, respectively Total number of detected lesions was 118 on PET and 115 on PET Only 78 PET lesions were TP, 40 were FN, and 37 were FP, yielding detection sensitivity (TP/(TP+FN)) and a false discovery rate (FP/(TP+FP)) of 66% (78/118) and 32% (37/115), respectively. In 62% (23/37) of cases, the FP lesion was scored C, suggesting a definite lesion. PET improved visual similarity with PET compared with PET, and PET and PET had similar Likert scale-defined image quality. However, lesion detection analysis performed by physicians showed high proportions of FP and FN lesions on PET, highlighting the need for clinical validation of AI algorithms.
频繁的生长抑素受体 PET,例如 Cu-DOTATATE PET,是神经内分泌肿瘤 (NEN) 患者诊断的一部分,会导致累积辐射剂量很高。应根据尽量降低可达原则将与扫描相关的辐射暴露降至最低,例如通过减少注射的放射性示踪剂活性。先前的研究发现,将 Cu-DOTATATE 活性降低到 50MBq 以下会导致图像质量和病变检测不足。因此,我们研究了使用人工智能 (AI) 是否可以恢复低于 50MBq 的 Cu-DOTATATE PET 的图像质量和病变检测。 我们针对神经内分泌肿瘤患者,在对应于参考全剂量 (PET) 注射活性的 25%(PET)或约 48MBq 的模拟低剂量 Cu-DOTATATE PET 图像上实施了基于参数转移的 Wasserstein 生成对抗网络,以生成去噪 PET 图像 (PET)。我们将 38 名患者纳入网络优化的训练集。我们分析了 PET 强度相关性、峰值信噪比 (PSNR)、结构相似性指数 (SSIM) 和 PET/PET 与 PET/PET 的均方误差 (MSE)。两位读者评估了 Likert 量表定义的图像质量 (1,很差;2,差;3,中等;4,好;5,很好),并在不超过 20 个病变/器官的患者子集 (n=33) 中识别 PET 和 PET 上的可疑病变焦点,以允许在 1:1 的基础上比较所有焦点。检测到的焦点被评分 (C,明确的病变;C,可疑病变焦点),并与作为参考的 PET 相匹配。评估了真阳性 (TP)、假阳性 (FP) 和假阴性 (FN) 病变。对于 PET/PET 与 PET/PET,PET 强度相关性的拟合优度值为 0.94 对 0.81,PSNR 为 58.1 对 53.0,SSIM 为 0.908 对 0.899,MSE 为 2.6 对 4.7。在 PET 和 PET 上,分别有 33 名和 33 名患者中的 33 名患者对图像质量进行了良好或优秀的评价。在 PET 上共检测到 118 个病变,在 PET 上共检测到 115 个病变。仅在 PET 上有 78 个 TP 病变,40 个 FN 病变和 37 个 FP 病变,TP 病变的检测灵敏度 (TP/(TP+FN)) 和假发现率 (FP/(TP+FP)) 分别为 66% (78/118) 和 32% (37/115)。在 37 个 FP 病变中有 62% (23/37) 的病变被评分 C,提示为明确病变。与 PET 相比,PET 提高了与 PET 的视觉相似性,并且 PET 和 PET 具有相似的 Likert 量表定义的图像质量。然而,医生进行的病变检测分析显示 PET 上 FP 和 FN 病变的比例较高,这突出表明需要对人工智能算法进行临床验证。
