收稿日期: 2019-02-17
网络出版日期: 2021-02-07
基金资助
国家自然科学基金(81871326);国家自然科学基金(81701648)
CT spectral curve in differentiating spinal tumor metastasis and infections
Received date: 2019-02-17
Online published: 2021-02-07
Supported by
National Natural Science Foundation of China(81871326);National Natural Science Foundation of China(81701648)
目的: 探讨CT能谱曲线在脊柱转移瘤和感染性病变中鉴别诊断的价值。方法: 收集经手术、穿刺组织病理检查或临床治疗证实的29例脊柱转移瘤和18例脊柱感染性病变的能谱CT增强静脉期扫描图像,经后处理获得单能量图像,生成病变感兴趣区(region of interest,ROI)CT能谱曲线,计算40~140 keV不同能级水平(每10 keV)下的CT值和能谱曲线斜率,同时在传统混合能量图像的同一ROI测量CT值,对所得CT值、能谱曲线斜率及其诊断效能进行统计学分析。结果: 脊柱转移瘤和感染性病变的中位年龄分别为58岁和64岁,两组差异无统计学意义(U=171,P=0.4)。40~100 keV各能级下脊柱转移瘤的CT值分别为281.79 (143.67, 446.19) HU、199.68 (100.04, 321.49) HU、151.54 (81.47, 243.49) HU、(122.64±27.72) HU、(99.90±23.88) HU、(85.82±21.61) HU、(75.94±20.27) HU,脊柱感染性疾病的CT值分别为185.29 (164.19, 277.03) HU、138.44 (124.98, 238.56) HU、105.46 (92.94, 169.53) HU、(93.77±15.55) HU、(79.15±12.84) HU、(68.99±11.75) HU、(62.22±11.71) HU。脊柱转移瘤在同一能级的CT值显著高于脊柱感染性病变(P均<0.05),110~140 keV能量水平下的CT值差异无统计学意义(P均>0.05)。混合能量图像测量的CT值差异无统计学意义(P>0.05)。脊柱转移瘤的能谱曲线斜率为2.43±0.58,高于脊柱感染性疾病的能谱曲线斜率1.50±0.40(P<0.001)。当静脉期能谱曲线斜率阈值取1.72、40 keV CT值取248.80 HU时,曲线下面积分别为0.905、0.892,灵敏度分别为88.0%、80.0%,特异度分别为76.9%、92.3%。结论: CT能谱曲线能够对鉴别脊柱转移瘤及感染性病变提供有价值的半定量信息,可以作为传统CT影像学的补充。
袁源 , 郎宁 , 袁慧书 . CT能谱曲线在脊柱转移瘤和感染性病变中的鉴别诊断价值[J]. 北京大学学报(医学版), 2021 , 53(1) : 183 -187 . DOI: 10.19723/j.issn.1671-167X.2021.01.027
Objective: To evaluate the value of CT spectral curve in differentiating spinal tumor metastasis (STM) from spinal infections (SI).Methods: In the study, 29 STM and 18 SI patients proved pathologically and clinically were examined by dual energy spectral CT (DESCT). The monochromatic images and CT spectral curves were generated automatically by GSI Viewer software. The attenuation values at different energy levels (40-140 keV, every 10 keV), the attenuation values of the lesions on the conventional polychromatic CT images and the gradients of the curve were calculated and compared between STM and SI.Results: The median age of STM and SI (58 years vs. 64 years) were not significantly different (U=171, P=0.4). The attenuation values of STM at 40-100 keV were 281.79 (143.67, 446.19) HU, 199.68 (100.04, 321.49) HU, 151.54 (81.47, 243.49) HU, (122.64±27.72) HU, (99.90±23.88) HU, (85.82±21.61) HU, and (75.94±20.27) HU, respectively, which were significantly higher than SI: 185.29 (164.19, 277.03) HU, 138.44 (124.98, 238.56) HU, 105.46 (92.94, 169.53) HU, (93.77±15.55) HU, (79.15±12.84) HU, (68.99±11.75) HU, and (62.22±11.71) HU (all P<0.05). The attenuation values at 110-140 keV and the attenuation value on the conventional CT images were not significantly different between STM and SI. The gradient of CT spectral curve of STM was 2.43±0.58, which was higher than the value of 1.50±0.40 for SI (P<0.001). Using 1.72 and 248.80 HU as the threshold value for CT spectral curve slope and the attenuation value at 40 keV, could obtain the area under receiver operating characteristic (ROC) curve of 0.905 and 0.892, sensitivity of 88.0% and 80.0%, and specificity of 76.9% and 92.3%.Conclusion: CT spectral curve provides valuable semi-quantitative information for the differential diagnosis of STM and SI, which can be used as a supplement to traditional CT imaging.
Key words: Spinal neoplasms; Bacterial infections; Tomography; X-ray computed; Diagnosis; differential
| [1] | Lee SH, Lee JM, Kim KW, et al. Dual-energy computed tomography to assess tumor response to hepatic radiofrequency ablation: potential diagnostic value of virtual noncontrast images and iodine maps[J]. Invest Radiol, 2011,46(2):77-84. |
| [2] | Lang N, Yuan H, Yu HJ, et al. Diagnosis of spinal lesions using heuristic and pharmacokinetic parameters measured by dynamic contrast-enhanced MRI[J]. Acad Radiol, 2017,24(7):867-875. |
| [3] | Babic M, Simpfendorfer CS. Infections of the Spine[J]. Infect Dis Clin North Am, 2017,31(2):279-297. |
| [4] | Dong Y, Zheng S, Machida H, et al. Differential diagnosis of osteoblastic metastases from bone islands in patients with lung cancer by single-source dual-energy CT: advantages of spectral CT imaging[J]. Eur J Radiol, 2015,84(5):901-907. |
| [5] | Ko JP, Brandman S, Stember J, et al. Dual-energy computed tomography: concepts, performance, and thoracic applications[J]. J Thorac Imaging, 2012,27(1):7-22. |
| [6] | Flais J, Coiffier G, Brillet E, et al. Atypical presentation of spine bone metastasis in prostate cancer mimicking Pott’s disease[J]. Clin Cases Miner Bone Metab, 2017,14(2):239-240. |
| [7] | 袁源, 张艳, 郎宁, 等. CT能谱曲线鉴别诊断脊柱肿瘤及肿瘤样病变[J]. 中国医学影像技术, 2015,31(4):600-603. |
| [8] | Avrin DE, Macovski A, Zatz LE. Clinical application of Compton and photo-electric reconstruction in computed tomography: preliminary results[J]. Invest Radiol, 1978,13(3):217-222. |
| [9] | Dilmanian FA. Computed tomography with monochromatic X rays[J]. Am J Physiol Imaging, 1992,7(3/4):175-193. |
| [10] | Riederer SJ, Mistretta CA. Selective iodine imaging using K-edge energies in computerized X-ray tomography[J]. Med Phys, 1977,4(6):474-481. |
| [11] | Silva AC, Morse BG, Hara AK, et al. Dual-energy (spectral) CT: applications in abdominal imaging[J]. Radiographics, 2011,31(4):1031-1050. |
| [12] | 雷立昌, 陈建宇. 能谱CT的临床应用与研究进展[J]. 中国医学影像技术, 2013,29(1):146-149. |
| [13] | 林晓珠, 沈云, 陈克敏. CT能谱成像的基本原理与临床应用研究进展[J]. 中华放射学杂志, 2011,45(8):798-800. |
| [14] | 张靖, 周新社. 脊柱肿瘤的诊断和外科分期研究进展[J]. 中华全科医学, 2011,9(2):277-279. |
| [15] | Go SW, Lee HY, Lim CH, et al. Atypical disseminated skeletal tuberculosis mimicking metastasis on PET-CT and MRI[J]. Intern Med, 2012,51(20):2961-2965. |
| [16] | Mittal S, Khalid M, Sabir AB, et al. Comparison of magnetic resonance imaging findings between pathologically proven cases of atypical tubercular spine and tumour metastasis: A retrospective study in 40 patients[J]. Asian Spine J, 2016,10(4):734-743. |
| [17] | Sezgin B, Atilganoglu U, Yigit O, et al. Concomitant cutaneous metastatic tuberculous abscesses and multifocal skeletal tuberculosis[J]. Indian J Dermatol, 2008,53(3):149-153. |
| [18] | Chang DS, Rafii M, McGuinness G, et al. Primary multifocal tuberculous osteomyelitis with involvement of the ribs[J]. Skeletal Radiol, 1998,27(11):641-645. |
| [19] | Lang N, Su MY, Yu HJ, et al. Differentiation of tuberculosis and metastatic cancer in the spine using dynamic contrast-enhanced MRI[J]. Eur Spine J, 2015,24(8):1729-1737. |
| [20] | Zheng S, Dong Y, Miao Y, et al. Differentiation of osteolytic metastases and Schmorl’s nodes in cancer patients using dual-energy CT: Advantage of spectral CT imaging[J]. Eur J Radiol, 2014,83(7):1216-1221. |
| [21] | Gupta S, Wagner-Bartak N, Jensen CT, et al. Dual-energy CT of pancreatic adenocarcinoma: Reproducibility of primary tumor measurements and assessment of tumor conspicuity and margin sharpness[J]. Abdom Radiol (NY), 2016,41(7):1317-1324. |
| [22] | Ramon A, Bohm-Sigrand A, Pottecher P, et al. Role of dual-energy CT in the diagnosis and follow-up of gout: systematic analysis of the literature[J]. Clin Rheumatol, 2018,37(3):587-595. |
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