Chi Pai-Chun Melinda, Mawlawi Osama, Nehmeh Sadek A, Erdi Yusuf E, Balter Peter A, Luo Dershan, Mohan Radhe, Pan Tinsu
Department of Imaging Physics, The University of Texas M. D. Anderson Cancer Center, Houston, Texas 77030, USA.
Med Phys. 2007 Jun;34(6):2039-47. doi: 10.1118/1.2733810.
Our previous patient studies have shown that the use of respiration averaged computed tomography (ACT) for attenuation correction of the positron emission tomography (PET) data from PET/CT reduces the potential misalignment in the thorax region by matching the temporal resolution of the CT to that of the PET. In the present work, we investigated other approaches of acquiring ACT in order to reduce the CT dose and to improve the ease of clinical implementation. Four-dimensional CT (4DCT) data sets for ten patients (17 lung/esophageal tumors) were acquired in the thoracic region immediately after the routine PET/CT scan. For each patient, multiple sets of ACTs were generated based on both phase image averaging (phase approach) and fixed cine duration image averaging (cine approach). In the phase approach, the ACTs were calculated from CT images corresponding to the significant phases of the respiratory cycle: ACT(050phs) from end-inspiration (0%) and end-expiration (50%), ACT(2070phs) from mid-inspiration (20%) and mid-expiration (70%), ACT(4phs) from 0%, 20%, 50% and 70%, and ACT(10phs) from all ten phases, which was the original approach. In the cine approach, which does not require 4DCT, the ACTs were calculated based on the cine images from cine durations of 1 to 6 s at 1 s increments. PET emission data for each patient were attenuation corrected with each of the above mentioned ACTs and the tumor maximum standard uptake value (SUVmax), average SUV (SUVavg), and tumor volume measurements were compared. Percent differences were calculated between PET data corrected with various ACTs and that corrected with ACT(10phs). In the phase approach, the ACT(10phs) can be approximated by the ACT(4phs) to within a mean percent difference of 2% in SUV and tumor volume measurements. In cine approach, ACT(10phs) can be approximated to within a mean percent difference of 3% by ACTs computed from cine durations > or =3 s. Acquiring CT images only at the four significant phases for the ACT can reduce radiation dose to 1/3 of the current 4DCT dose; however, the implementation of this approach requires additional hardware that is not standard equipment on PET/CT scanners. In the cine approach, we recommend a duration of 6 +/- 1 s in order to include variations of respiratory patterns in a larger population. This approach can be easily implemented because cine acquisition mode is available on all GE PET/CT scanners. The CT dose in the cine approach can be reduced to approximately 5 mGy by using the lowest mA setting (10 mA), while still maintaining good quality CT data for PET attenuation correction. In our scanning protocol, the ACT is only acquired if respiration-induced misregistration is observed (determined before the PET scan is completed), and therefore patients do not receive unnecessary CT radiation dose.
我们之前的患者研究表明,使用呼吸平均计算机断层扫描(ACT)对正电子发射断层扫描(PET)/计算机断层扫描(CT)中的PET数据进行衰减校正,通过使CT的时间分辨率与PET的时间分辨率相匹配,可减少胸部区域的潜在错位。在本研究中,我们研究了获取ACT的其他方法,以降低CT剂量并提高临床实施的便利性。在常规PET/CT扫描后,立即在胸部区域获取了10名患者(17个肺/食管肿瘤)的四维CT(4DCT)数据集。对于每位患者,基于相位图像平均(相位法)和固定电影时长图像平均(电影法)生成了多组ACT。在相位法中,ACT是根据与呼吸周期的显著相位相对应的CT图像计算得出的:从吸气末(0%)和呼气末(50%)计算出ACT(050phs),从中吸气(20%)和中呼气(70%)计算出ACT(2070phs),从0%、20%、50%和70%计算出ACT(4phs),从所有十个相位计算出ACT(10phs),这是原始方法。在电影法中,不需要4DCT,ACT是根据电影时长为1至6秒、以1秒增量的电影图像计算得出的。用上述每种ACT对每位患者的PET发射数据进行衰减校正,并比较肿瘤最大标准摄取值(SUVmax)、平均SUV(SUVavg)和肿瘤体积测量值。计算用各种ACT校正的PET数据与用ACT(10phs)校正的PET数据之间的百分比差异。在相位法中,ACT(10phs)在SUV和肿瘤体积测量中的平均百分比差异在2%以内时,可由ACT(4phs)近似得出。在电影法中,当电影时长≥3秒时计算出的ACT在平均百分比差异3%以内时,可近似得出ACT(10phs)。仅在ACT的四个显著相位获取CT图像可将辐射剂量降低至当前4DCT剂量的1/3;然而,这种方法的实施需要额外的硬件,而这不是PET/CT扫描仪上的标准设备。在电影法中,我们建议时长为6±1秒,以便在更大的人群中纳入呼吸模式变化。这种方法易于实施,因为所有GE PET/CT扫描仪都具备电影采集模式。通过使用最低毫安设置(10 mA),电影法中的CT剂量可降低至约5 mGy,同时仍能保持用于PET衰减校正的高质量CT数据。在我们的扫描方案中,仅在观察到呼吸引起的配准误差时(在PET扫描完成前确定)才获取ACT,因此患者不会接受不必要的CT辐射剂量。
