Study of the correlation between CT image quality and radiation doses of lung nodules with different scanning parameters_Chinese Journal of Evidence-Based Medicine

Authors：

PENG Shengkun , ZHAO Yuan ,  PU Hong

Department of Radiology, Sichuan Province of People’s Hospital, Chengdu, 610000, P.R.China;

Corresponding author：

PU Hong, Email: ph1726148853@qq.com

Keywords：

Low dose; Phantom; Pulmonary nodule; Computed tomography; Image quality; Radiation dose

DOI：

10.7507/1672-2531.201901003

Video：

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Objectives To investigate the influence of scanning parameters (tube voltages and tube currents) on image quality and corresponding radiation doses with simulated lung nodules in chest CT.Methods The anthropomorphic chest phantoms with 12 simulated, randomly placed nodules of different diameters and densities in the chest were scanned by different scanning parameters. The detection rate, degree of nodular deformation, image quality (with both subjective and objective evaluation) and the corresponding radiation doses were recorded and evaluated, and the correlation between nodule detection rate, degree of nodular deformation, radiation dose and image quality using different scanning parameters was analyzed.Results The image quality improved with the increase of tube voltage and tube current (P<0.05). When the tube current was constant, the CT values of the vertebral decreased gradually with the increase of tube voltages (P<0.05); however, significant difference was not detected in CT values of the lung field (P>0.05). When the tube current was 100 mAs, the lung nodules with CT values of +100 HU and −630 HU showed statistical difference when using different tube voltage (P<0.05); but there was no significant difference in nodules of −800 HU (P=0.57). When tube voltage was 100 kV and 120 kV each, it was possible to detect all lung nodules with a detection rate of 100%. The detection rate was 33% and 66% in 3 mm diameter when the tube current was 80 kV/15 mA and 80 kV/20 mA, respectively. The nodules deformation in nodules with a CT value of −630 HU and diameter less than 5 mm was the most prominent (P<0.05). After analyzing the relationship between image quality and radiation doses using different tube voltages, we established a system of correlation equations: 80 kV: Y=2.625X+0.038; 100 kV: Y=14.66X+0.158; 120 kV: Y=18.59X+0.093.Conclusions The image quality improves with the increase of tube current and tube voltage, as well as the corresponding radiation doses. By reducing the tube voltage and increasing the tube current appropriately, the radiation doses can be reduced. Follow-up CT examination of pulmonary ground glass nodules should apply the same tube voltage imaging parameters, so as to effectively reduce the measurement error of nodule density and evaluate the change of nodules more accurately.

Citation： PENG Shengkun, ZHAO Yuan, PU Hong. Study of the correlation between CT image quality and radiation doses of lung nodules with different scanning parameters. Chinese Journal of Evidence-Based Medicine, 2019, 19(10): 1158-1162. doi: 10.7507/1672-2531.201901003 Copy

1.	周清华, 范亚光, 王颖. 中国肺癌低剂量螺旋 CT 筛查指南(2018 年版). 中国肺癌杂志, 2018, 21(2): 67-75.
2.	张丽, 于红, 刘士远, 等. 迭代重建技术对低剂量肺部平扫 CT 图像质量的影响. 中华放射医学杂志, 2013, 47(4): 316-320.
3.	蒋耀军, 吴艳, 张永高, 等. 低管电流联合迭代重建算法对胸部体模 T12 骨密度值准确性和胸部图像质量的影响. 中国医学影像技术杂志, 2018, 34(3): 429-433.
4.	彭盛坤, 曾勇明, 罗天友, 等. 冠状动脉 CTA 迭代重建算法图像质量和辐射剂量的实验研究. 第三军医大学学报, 2013, 35(13): 1371-1375.
5.	李莹, 艾娜娜, 张颖颖, 等. 前置自适应统计迭代重建技术对体模肺纯磨玻璃结节图像质量及辐射剂量的影响. 中国医学影像技术, 2018, 34(5): 775-778.
6.	Ebeah JM. Lung cancer screening with low-dose ct in the united states. J Am Coli Radiol, 2015, 12(12 Pt B): 1395-1402.
7.	Eberth JM, Qiu R, Admns SA, et al. Lung cancer screening using low-dose CT: The current national landscape. Lung Cancer, 2014, 85(3): 379-384.
8.	李琼于红张丽, 等. 迭代重建技术对低管电压胸部 CT 增强扫描图像质量的影响. 实用放射学杂志, 2012, 28(10): 1615-1618.
9.	MacMahon H, Naidich DP, Goo JM, et al. Guidelines for management of incidental pulmonary nodules detected on ct images: from the Fleischner Society 2017. Radiology, 2017, 284(1): 228-243.
10.	Aoki T, Nakata H, Watanabe H, et al. Evolution of peripheral lung adenocarcinomas: CT findings correlated with histology and tumor doubling time. AJR Am J Roentgenol, 2000, 174(3): 763-768.
11.	Sone S, Li F, Yang ZG, et al. Characteristic of small lung cancers invisible on conventional chest radiography and detected by population based screening using spiral CT. Br J Radiol, 2000, 73(866): 137-145.
12.	Sui X, Meinel F G, Song W, et al. Detection and size measurements of pulmonary nodules in ultra-low-dose CT with iterative reconstruction compared to low dose CT. Eur J Radiol, 2016, 85(3): 564-570.
13.	Messerli M, Kluckert T, Knitel M, et al. Ultralow dose CT for pulmonary nodule detection with chest X-ray equivalent dose a prospective intra-individual comparative study. Eur Radiol, 2017, 27(8): 3290-3299.
14.	叶凯, 袁慧书. 超低剂量 CT 在胸部疾病诊断的研究进展. 实用放射学杂志, 2018, 34(4): 621-623.
15.	Maffei E, Martini C, Rossi A, et al. Diagnostic accuracy of second-generation dual-source computed tomography coronary angiography with iterative reconstructions: a real-world experience. Radiol Med, 2012, 117(5): 725-738.
16.	李锋坦, 李东, 张云亭. 管电压对 CT 值测量、辐射剂量及图像质量影响的模型研究. 中华放射学杂志, 2013, 47(5): 458-461.
17.	邹平, 薛跃君. 64 排螺旋 CT 双下肢血管成像低电压扫描的初步研究. 临床放射学杂志, 2013, 32(9): 1340-1342.
18.	江一峰, 叶剑定, 丁晓毅, 等. 胸部低剂量 CT 图像噪声和伪影分析. 中华放射学杂志, 2010, 44(1): 37-40.
19.	江一峰, 叶剑定, 丁晓毅, 等. 64 层螺旋 CT 低剂量扫描检测肺小结节敏感性的实验研究. 实用放射学杂志, 2010, 26(1): 115-119.

1. 周清华, 范亚光, 王颖. 中国肺癌低剂量螺旋 CT 筛查指南(2018 年版). 中国肺癌杂志, 2018, 21(2): 67-75.
2. 张丽, 于红, 刘士远, 等. 迭代重建技术对低剂量肺部平扫 CT 图像质量的影响. 中华放射医学杂志, 2013, 47(4): 316-320.
3. 蒋耀军, 吴艳, 张永高, 等. 低管电流联合迭代重建算法对胸部体模 T12 骨密度值准确性和胸部图像质量的影响. 中国医学影像技术杂志, 2018, 34(3): 429-433.
4. 彭盛坤, 曾勇明, 罗天友, 等. 冠状动脉 CTA 迭代重建算法图像质量和辐射剂量的实验研究. 第三军医大学学报, 2013, 35(13): 1371-1375.
5. 李莹, 艾娜娜, 张颖颖, 等. 前置自适应统计迭代重建技术对体模肺纯磨玻璃结节图像质量及辐射剂量的影响. 中国医学影像技术, 2018, 34(5): 775-778.
6. Ebeah JM. Lung cancer screening with low-dose ct in the united states. J Am Coli Radiol, 2015, 12(12 Pt B): 1395-1402.
7. Eberth JM, Qiu R, Admns SA, et al. Lung cancer screening using low-dose CT: The current national landscape. Lung Cancer, 2014, 85(3): 379-384.
8. 李琼于红张丽, 等. 迭代重建技术对低管电压胸部 CT 增强扫描图像质量的影响. 实用放射学杂志, 2012, 28(10): 1615-1618.
9. MacMahon H, Naidich DP, Goo JM, et al. Guidelines for management of incidental pulmonary nodules detected on ct images: from the Fleischner Society 2017. Radiology, 2017, 284(1): 228-243.
10. Aoki T, Nakata H, Watanabe H, et al. Evolution of peripheral lung adenocarcinomas: CT findings correlated with histology and tumor doubling time. AJR Am J Roentgenol, 2000, 174(3): 763-768.
11. Sone S, Li F, Yang ZG, et al. Characteristic of small lung cancers invisible on conventional chest radiography and detected by population based screening using spiral CT. Br J Radiol, 2000, 73(866): 137-145.
12. Sui X, Meinel F G, Song W, et al. Detection and size measurements of pulmonary nodules in ultra-low-dose CT with iterative reconstruction compared to low dose CT. Eur J Radiol, 2016, 85(3): 564-570.
13. Messerli M, Kluckert T, Knitel M, et al. Ultralow dose CT for pulmonary nodule detection with chest X-ray equivalent dose a prospective intra-individual comparative study. Eur Radiol, 2017, 27(8): 3290-3299.
14. 叶凯, 袁慧书. 超低剂量 CT 在胸部疾病诊断的研究进展. 实用放射学杂志, 2018, 34(4): 621-623.
15. Maffei E, Martini C, Rossi A, et al. Diagnostic accuracy of second-generation dual-source computed tomography coronary angiography with iterative reconstructions: a real-world experience. Radiol Med, 2012, 117(5): 725-738.
16. 李锋坦, 李东, 张云亭. 管电压对 CT 值测量、辐射剂量及图像质量影响的模型研究. 中华放射学杂志, 2013, 47(5): 458-461.
17. 邹平, 薛跃君. 64 排螺旋 CT 双下肢血管成像低电压扫描的初步研究. 临床放射学杂志, 2013, 32(9): 1340-1342.
18. 江一峰, 叶剑定, 丁晓毅, 等. 胸部低剂量 CT 图像噪声和伪影分析. 中华放射学杂志, 2010, 44(1): 37-40.
19. 江一峰, 叶剑定, 丁晓毅, 等. 64 层螺旋 CT 低剂量扫描检测肺小结节敏感性的实验研究. 实用放射学杂志, 2010, 26(1): 115-119.

Chinese Journal of Evidence-Based Medicine

Study of the correlation between CT image quality and radiation doses of lung nodules with different scanning parameters

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