Feasibility of low dose computed tomography perfusion imaging in quantitative evaluating proximal gastric cancer: a pilot study_CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY

Authors：

YANG Lanqing , YU Xin , ZHANG Jing , LI Zhenlin , XIA Chunchao , SHUAI Tao ,  WU Bing

Department of Radiology, West China Hospital, Sichuan University, Chengdu 610041, P.R.China;

Corresponding author：

WU Bing, Email: bingwu69@163.com

Keywords：

computed tomography perfusion imaging; low dose; proximal gastric cancer

DOI：

10.7507/1007-9424.201706081

Video：

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Objective To explore feasibility and clinical value of low dose computed tomography perfusion imaging (CTPI) in quantitative assessing proximal gastric cancer. Methods A total of 34 patients diagnosed with proximal gastric cancer (a proximal gastric cancer group) were enrolled prospectively in this study. The 25 normal parts of gastric fundus of the included patients constituted a control group. All the patients underwent the low dose CTPI before surgery. The total effective radiation dose was recorded, and a specific post-processing software was used to automatically generate the perfusion parameters values, including the time to peak (TTP), blood flow (BF), blood volume (BV), mean transmit time (MTT), and permeability (PMB). The perfusion parameters in the different histopathologic types and stages of the patients were compared. Receiver operating characteristic (ROC) curves were generated to compare their diagnosis performances. Results The histopathologic findings verified that there were 11 patients with T1+T2 stage and 23 patients with T3+T4 stage; 8 patients with signet ring cell carcinoma and 26 patients with adenocarcinoma; and 17 patients with lymphatic metastasis and 17 patients without lymphatic metastasis. ① Compared with the control group, the BF, BV, and PMB values were significantly higher and the MTT and TTP values were significantly lower in the proximal gastric cancer group. The area under the ROC curve (AUC) values of the BF, BV, PMB, MTT, and TTP in the diagnosing proximal gastric cancer was 0.955, 0.807, 0.987, 0.654, and 0.649 respectively. The BF and PMB represented the best diagnostic performances, and the BV was secondary in the ROC curve results. ② The BF value was significantly lower and the PMB value was significantly higher in the patients with signet ring cell carcinoma as compared with the patients with adenocarcinoma. However, the BV, MTT, and TTP values had no significant differences in both them. And the BF (AUC=0.986) had a better ability than the PMB (AUC=0.856) in the discriminating the histopathological type (P=0.047). ③ The PMB value in the patients with pathological stage T3 and T4 was significantly higher than that of the patients with pathological stage T1 and T2 (P=0.004), but the BF, BV, MTT, and TTP values had no differences in both them. The diagnosis value of the PMB in the discriminating the pathological stage was good with an AUC value of 0.814. ④ None of the parameters had significant difference between the patients with and without lymphatic metastasis (P>0.05). ⑤ The total effective radiation dose of each scan was 8.58 mSv, which was lower than that of the standard radiation dose of CTPI. ⑥ The rates of lymphatic metastasis and high T staging were not related to the histopathological type of the proximal gastric cancer (P>0.05). Conclusion Low dose CTPI used in this study could effectively reduce radiation dose, could quantitatively evaluate angiogenesis in proximal gastric cancer, and has a certain clinical value in identifying of histopathological type and evaluating of pathological stage.

Citation： YANG Lanqing, YU Xin, ZHANG Jing, LI Zhenlin, XIA Chunchao, SHUAI Tao, WU Bing. Feasibility of low dose computed tomography perfusion imaging in quantitative evaluating proximal gastric cancer: a pilot study. CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY, 2017, 24(8): 1014-1020. doi: 10.7507/1007-9424.201706081 Copy

1.	陈万青, 张思维, 曾红梅, 等. 中国 2010 年恶性肿瘤发病与死亡. 中国肿瘤, 2014, 23(1): 1-10.
2.	An JY, Baik YH, Choi MG, et al. The prognosis of gastric cardia cancer after R0 resection. Am J Surg, 2010, 199(6): 725-729.
3.	García-Figueiras R, Goh VJ, Padhani AR, et al. CT perfusion in oncologic imaging: a useful tool? AJR Am J Roentgenol, 2013, 200(1): 8-19.
4.	Huda W, Ogden KM, Khorasani MR. Converting dose-length product to effective dose at CT. Radiology, 2008, 248(3): 995-1003.
5.	Satoh A, Shuto K, Okazumi S, et al. Role of perfusion CT in assessing tumor blood flow and malignancy level of gastric cancer. Dig Surg, 2010, 27(4): 253-260.
6.	Hayano K, Fujishiro T, Sahani DV, et al. Computed tomography perfusion imaging as a potential imaging biomarker of colorectal cancer. World J Gastroenterol, 2014, 20(46): 17345-17351.
7.	Yao J, Yang ZG, Chen HJ, et al. Gastric adenocarcinoma: can perfusion CT help to noninvasively evaluate tumor angiogenesis? Abdom Imaging, 2011, 36(1): 15-21.
8.	Kandel S, Kloeters C, Meyer H, et al. Whole-organ perfusion of the pancreas using dynamic volume CT in patients with primary pancreas carcinoma: acquisition technique, post-processing and initial results. Eur Radiol, 2009, 19(11): 2641-2646.
9.	Miles KA. Perfusion CT for the assessment of tumour vascularity: which protocol? Br J Radiol, 2003, 76 Spec No 1: S36-S42.
10.	Dighe S, Blake H, Jeyadevan N, et al. Perfusion CT vascular parameters do not correlate with immunohistochemically derived microvessel density count in colorectal tumors. Radiology, 2013, 268(2): 400-410.
11.	Miles KA, Hayball M, Dixon AK. Colour perfusion imaging: a new application of computed tomography. Lancet, 1991, 337(8742): 643-645.
12.	Kim SH, Kamaya A, Willmann JK. CT perfusion of the liver: principles and applications in oncology. Radiology, 2014, 272(2): 322-344.
13.	Goh V, Halligan S, Daley F, et al. Colorectal tumor vascularity: quantitative assessment with multidetector CTᾺdo tumor perfusion measurements reflect angiogenesis? Radiology, 2008, 249(2): 510-517.
14.	Reiner CS, Roessle M, Thiesler T, et al. Computed tomography perfusion imaging of renal cell carcinoma: systematic comparison with histopathological angiogenic and prognostic markers. Invest Radiol, 2013, 48(4): 183-191.
15.	d’Assignies G, Couvelard A, Bahrami S, et al. Pancreatic endocrine tumors: tumor blood flow assessed with perfusion CT reflects angiogenesis and correlates with prognostic factors. Radiology, 2009, 250(2): 407-416.
16.	Makari Y, Yasuda T, Doki Y, et al. Correlation between tumor blood flow assessed by perfusion CT and effect of neoadjuvant therapy in advanced esophageal cancers. J Surg Oncol, 2007, 96(3): 220-229.
17.	Tacelli N, Remy-Jardin M, Copin MC, et al. Assessment of non-small cell lung cancer perfusion: pathologic-CT correlation in 15 patients. Radiology, 2010, 257(3): 863-871.
18.	Sun H, Xu Y, Yang Q, et al. Assessment of tumor grade and angiogenesis in colorectal cancer: whole-volume perfusion CT. Acad Radiol, 2014, 21(6): 750-757.
19.	Khan S, Goh V, Tam E, et al. Perfusion CT assessment of the colon and rectum: feasibility of quantification of bowel wall perfusion and vascularization. Eur J Radiol, 2012, 81(5): 821-824.
20.	Goh V, Glynne-Jones R. Perfusion CT imaging of colorectal cancer. Br J Radiol, 2014, 87(1034): 20130811.
21.	Bellomi M, Petralia G, Sonzogni A, et al. CT perfusion for the monitoring of neoadjuvant chemotherapy and radiation therapy in rectal carcinoma: initial experience. Radiology, 2007, 244(2): 486-493.
22.	Sahani DV, Kalva SP, Hamberg LM, et al. Assessing tumor perfusion and treatment response in rectal cancer with multisection CT: initial observations. Radiology, 2005, 234(3): 785-792.
23.	Prezzi D, Khan A, Goh V. Perfusion CT imaging of treatment response in oncology. Eur J Radiol, 2015, 84(12): 2380-2385.
24.	Sun ZQ, Li XH, Cai W, et al. CT perfusion imaging of the stomach: a quantitative analysis according to different degrees of adenocarcinoma cell differentiation. Clin Imaging, 2016, 40(3): 558-562.
25.	Sun Y, Yang M, Mao D, et al. Low-dose volume perfusion computed tomography (VPCT) for diagnosis of solitary pulmonary nodules. Eur J Radiol, 2016, 85(6): 1208-1218.
26.	Ng QS, Goh V, Fichte H, et al. Lung cancer perfusion at multi-detector row CT: reproducibility of whole tumor quantitative measurements. Radiology, 2006, 239(2): 547-553.
27.	Miles K A, Lee T Y, Goh V, et al. Current status and guidelines for the assessment of tumour vascular support with dynamic contrast-enhanced computed tomography. Eur Radiol, 2012, 22(7): 1430-1441.

1. 陈万青, 张思维, 曾红梅, 等. 中国 2010 年恶性肿瘤发病与死亡. 中国肿瘤, 2014, 23(1): 1-10.
2. An JY, Baik YH, Choi MG, et al. The prognosis of gastric cardia cancer after R0 resection. Am J Surg, 2010, 199(6): 725-729.
3. García-Figueiras R, Goh VJ, Padhani AR, et al. CT perfusion in oncologic imaging: a useful tool? AJR Am J Roentgenol, 2013, 200(1): 8-19.
4. Huda W, Ogden KM, Khorasani MR. Converting dose-length product to effective dose at CT. Radiology, 2008, 248(3): 995-1003.
5. Satoh A, Shuto K, Okazumi S, et al. Role of perfusion CT in assessing tumor blood flow and malignancy level of gastric cancer. Dig Surg, 2010, 27(4): 253-260.
6. Hayano K, Fujishiro T, Sahani DV, et al. Computed tomography perfusion imaging as a potential imaging biomarker of colorectal cancer. World J Gastroenterol, 2014, 20(46): 17345-17351.
7. Yao J, Yang ZG, Chen HJ, et al. Gastric adenocarcinoma: can perfusion CT help to noninvasively evaluate tumor angiogenesis? Abdom Imaging, 2011, 36(1): 15-21.
8. Kandel S, Kloeters C, Meyer H, et al. Whole-organ perfusion of the pancreas using dynamic volume CT in patients with primary pancreas carcinoma: acquisition technique, post-processing and initial results. Eur Radiol, 2009, 19(11): 2641-2646.
9. Miles KA. Perfusion CT for the assessment of tumour vascularity: which protocol? Br J Radiol, 2003, 76 Spec No 1: S36-S42.
10. Dighe S, Blake H, Jeyadevan N, et al. Perfusion CT vascular parameters do not correlate with immunohistochemically derived microvessel density count in colorectal tumors. Radiology, 2013, 268(2): 400-410.
11. Miles KA, Hayball M, Dixon AK. Colour perfusion imaging: a new application of computed tomography. Lancet, 1991, 337(8742): 643-645.
12. Kim SH, Kamaya A, Willmann JK. CT perfusion of the liver: principles and applications in oncology. Radiology, 2014, 272(2): 322-344.
13. Goh V, Halligan S, Daley F, et al. Colorectal tumor vascularity: quantitative assessment with multidetector CTᾺdo tumor perfusion measurements reflect angiogenesis? Radiology, 2008, 249(2): 510-517.
14. Reiner CS, Roessle M, Thiesler T, et al. Computed tomography perfusion imaging of renal cell carcinoma: systematic comparison with histopathological angiogenic and prognostic markers. Invest Radiol, 2013, 48(4): 183-191.
15. d’Assignies G, Couvelard A, Bahrami S, et al. Pancreatic endocrine tumors: tumor blood flow assessed with perfusion CT reflects angiogenesis and correlates with prognostic factors. Radiology, 2009, 250(2): 407-416.
16. Makari Y, Yasuda T, Doki Y, et al. Correlation between tumor blood flow assessed by perfusion CT and effect of neoadjuvant therapy in advanced esophageal cancers. J Surg Oncol, 2007, 96(3): 220-229.
17. Tacelli N, Remy-Jardin M, Copin MC, et al. Assessment of non-small cell lung cancer perfusion: pathologic-CT correlation in 15 patients. Radiology, 2010, 257(3): 863-871.
18. Sun H, Xu Y, Yang Q, et al. Assessment of tumor grade and angiogenesis in colorectal cancer: whole-volume perfusion CT. Acad Radiol, 2014, 21(6): 750-757.
19. Khan S, Goh V, Tam E, et al. Perfusion CT assessment of the colon and rectum: feasibility of quantification of bowel wall perfusion and vascularization. Eur J Radiol, 2012, 81(5): 821-824.
20. Goh V, Glynne-Jones R. Perfusion CT imaging of colorectal cancer. Br J Radiol, 2014, 87(1034): 20130811.
21. Bellomi M, Petralia G, Sonzogni A, et al. CT perfusion for the monitoring of neoadjuvant chemotherapy and radiation therapy in rectal carcinoma: initial experience. Radiology, 2007, 244(2): 486-493.
22. Sahani DV, Kalva SP, Hamberg LM, et al. Assessing tumor perfusion and treatment response in rectal cancer with multisection CT: initial observations. Radiology, 2005, 234(3): 785-792.
23. Prezzi D, Khan A, Goh V. Perfusion CT imaging of treatment response in oncology. Eur J Radiol, 2015, 84(12): 2380-2385.
24. Sun ZQ, Li XH, Cai W, et al. CT perfusion imaging of the stomach: a quantitative analysis according to different degrees of adenocarcinoma cell differentiation. Clin Imaging, 2016, 40(3): 558-562.
25. Sun Y, Yang M, Mao D, et al. Low-dose volume perfusion computed tomography (VPCT) for diagnosis of solitary pulmonary nodules. Eur J Radiol, 2016, 85(6): 1208-1218.
26. Ng QS, Goh V, Fichte H, et al. Lung cancer perfusion at multi-detector row CT: reproducibility of whole tumor quantitative measurements. Radiology, 2006, 239(2): 547-553.
27. Miles K A, Lee T Y, Goh V, et al. Current status and guidelines for the assessment of tumour vascular support with dynamic contrast-enhanced computed tomography. Eur Radiol, 2012, 22(7): 1430-1441.

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Feasibility of low dose computed tomography perfusion imaging in quantitative evaluating proximal gastric cancer: a pilot study

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