Department of Nuclear Medicine & Molecular Imaging, Medical Imaging Center, University of Groningen, University Medical Center Groningen, Groningen, The Netherlands.
Department of Applied Mathematics and Technical Medicine Center, University of Twente, Enschede, The Netherlands.
Med Phys. 2024 Apr;51(4):2611-2620. doi: 10.1002/mp.16787. Epub 2023 Oct 13.
Currently, computed tomography (CT) is used for risk profiling of (asymptomatic) individuals by calculating coronary artery calcium scores. Although this score is a strong predictor of major adverse cardiovascular events, this method has limitations. Sodium [F]fluoride (Na[F]F) positron emission tomography (PET) has shown promise as an early marker for atherosclerotic progression. However, evidence on Na[F]F as a marker for high-risk plaques is limited, particularly on its presentation in clinical PET/CT. Besides, the relationship between microcalcifications visualized by Na[F]F PET and macrocalcifications detectable on CT is unknown.
To establish a match/mismatch score in the aorta between macrocalcified plaque content on CT and microcalcification Na[F]F PET uptake.
Na[F]F-PET/CT scans acquired in our centre in 2019-2020 were retrospectively collected. The aorta of each low-dose CT was manually segmented. Background measurements were placed in the superior vena cava. The vertebrae were automatically segmented using an open-source convolutional neural network, dilated with 10 mm, and subtracted from the aortic mask. Per patient, calcium and Na[F]F-hotspot masks were retrieved using an in-house developed algorithm. Three match/mismatch analyses were performed: a population analysis, a per slice analysis, and an overlap score. To generate a population image of calcium and Na[F]F hotspot distribution, all aortic masks were aligned. Then, a heatmap of calcium HU and Na[F]F-uptake on the surface was obtained by outward projection of HU and uptake values from the centerline. In each slice of the aortic wall of each patient, the calcium mass score and target-to-bloodpool ratios (TBR) were calculated within the calcium masks, in the aortic wall except the calcium masks, and in the aortic wall in slices without calcium. For the overlap score, three volumes were identified in the calcium and Na[F]F masks: volume of PET (PET+/CT-), volume of CT (PET-/CT+), and overlapping volumes (PET+/CT+). A Spearman's correlation analysis with Bonferroni correction was performed on the population image, assessing the correlation between all HU and Na[F]F vertex values. In the per slice analysis, a paired Wilcoxon signed-rank test was used to compare TBR values within each slice, while an ANOVA with post-hoc Kruskal-Wallis test was employed to compare TBR values between slices. p-values < 0.05 were considered significant.
In total, 186 Na[F]F-PET/CT scans were included. A moderate positive exponential correlation was observed between total aortic calcium mass and total aortic TBR (r = 0.68, p < 0.001). A strong positive correlation (r = 0.77, p < 0.0001) was observed between CT values and Na[F]F values on the population image. Significantly higher TBR values were found outside calcium masks than inside calcium masks (p < 0.0001). TBR values in slices where no calcium was present, were significantly lower compared with outside calcium and inside calcium (both p < 0.0001). On average, only 3.7% of the mask volumes were overlapping.
Na[F]F-uptake in the aorta behaves similarly to macrocalcification detectable on CT. Na[F]F-uptake values are also moderately correlated to calcium mass scores (match). Higher uptake values were found just outside macrocalcification masks instead of inside the macrocalcification masks (mismatch). Also, only a small percentage of the Na[F]F-uptake volumes overlapped with the calcium volumes (mismatch).
目前,通过计算冠状动脉钙分数,计算机断层扫描(CT)用于(无症状)个体的风险分析。尽管该评分是主要不良心血管事件的有力预测指标,但该方法存在局限性。[F]氟酸钠(Na[F]F)正电子发射断层扫描(PET)已显示出作为动脉粥样硬化进展的早期标志物的潜力。然而,Na[F]F 作为高危斑块标志物的证据有限,特别是在其在临床 PET/CT 中的表现。此外,Na[F]F PET 检测到的微钙化与 CT 可检测到的宏观钙化之间的关系尚不清楚。
在 CT 上检测到的大血管钙化斑块含量与 Na[F]F PET 摄取之间建立匹配/不匹配评分。
回顾性收集了我们中心在 2019-2020 年采集的 Na[F]F-PET/CT 扫描。手动分割每个低剂量 CT 的主动脉。在上下腔静脉中放置背景测量值。使用开源卷积神经网络自动分割椎体,用 10 毫米进行扩张,从主动脉掩模中减去。使用内部开发的算法从每个患者中检索钙和 Na[F]F 热点掩模。进行了三种匹配/不匹配分析:人群分析、每片分析和重叠评分。为了生成钙和 Na[F]F 热点分布的人群图像,对齐所有主动脉掩模。然后,通过从中心线向外投影 HU 和摄取值,获得主动脉表面的钙 HU 和 Na[F]F 摄取的热图。在每个患者的主动脉壁的每片切片中,在钙掩模内、钙掩模外的主动脉壁内以及无钙切片的主动脉壁内计算钙质量评分和靶血池比(TBR)。对于重叠评分,在钙和 Na[F]F 掩模中识别出三个体积:PET 体积(PET+/CT-)、CT 体积(PET-/CT+)和重叠体积(PET+/CT+)。使用带有 Bonferroni 校正的 Spearman 相关性分析对人群图像进行分析,评估所有 HU 和 Na[F]F 顶点值之间的相关性。在每片分析中,使用配对 Wilcoxon 符号秩检验比较每片切片内的 TBR 值,使用单因素方差分析和事后 Kruskal-Wallis 检验比较切片之间的 TBR 值。p 值<0.05 被认为具有统计学意义。
共纳入 186 例 Na[F]F-PET/CT 扫描。总主动脉钙质量与总主动脉 TBR 之间观察到中等正指数相关性(r=0.68,p<0.001)。人群图像上观察到 CT 值与 Na[F]F 值之间的强正相关(r=0.77,p<0.0001)。与钙掩模内相比,钙掩模外的 TBR 值明显更高(p<0.0001)。无钙存在的切片中的 TBR 值明显低于钙外和钙内(均 p<0.0001)。平均而言,只有 3.7%的掩模体积重叠。
主动脉中的 Na[F]F 摄取与 CT 上可检测到的宏观钙化相似。Na[F]F 摄取值与钙质量评分(匹配)也呈中度相关。在宏观钙化掩模外而不是在宏观钙化掩模内发现了更高的摄取值(不匹配)。此外,只有一小部分 Na[F]F 摄取体积与钙体积重叠(不匹配)。
