Predictive value of dynamic contrast-enhanced magnetic resonance imaging combined with multislice CT enhanced scanning for pathological remission after neoadjuvant chemotherapy in breast cancer_CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY

Authors：

CHEN Jin , HU Meixue ,  QUAN Yi

Sichuan Provincial Center for Gynaecology and Breast Surgery (Department of Breast Surgery), Affiliated Hospital of Southwest Medical University, Luzhou, Sichuan 646000, P. R. China;

Corresponding?author：

QUAN Yi, Email: 20783833@qq.com

Keywords：

breast cancer; dynamic contrast-enhanced magnetic resonance imaging; multislice computed tomography; neoadjuvant chemotherapy; pathological remission degree

DOI：

10.7507/1007-9424.202207057

Video：

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Objective To evaluate the predictive value of dynamic contrast-enhanced magnetic resonance imaging (DCE-MRI) combined with multislice computed tomography (MSCT) in the evaluation of neoadjuvant chemotherapy (NACT) for breast cancer. Methods The clinical, imaging, and pathological data of breast cancer patients who received NACT in the Affiliated Hospital of Southwest Medical University from February 2019 to August 2021 were retrospectively collected. Based on the results of postoperative pathological examination, the patients were assigned into significant remission (Miller-Payne grade Ⅰ–Ⅲ) and non-significant remission (Miller-Payne grade Ⅳ–Ⅴ). The variables with statistical significance by univariate analysis or factors with clinical significance judged based on professional knowledge were included to conduct the logistic regression multivariate analysis to screen the risk factors affecting the degree of pathological remission after NACT. Then, the screened risk factors were used to establish a prediction model for the degree of pathological remission of breast cancer after NACT, and the efficacy of this model was evaluated using the receiver operating characteristic (ROC) curve, calibration curve, and decision curve analysis (DCA) curve. Results According to the inclusion and exclusion criteria, a total of 211 breast cancer patients who received NACT were collected, including 116 patients with significant remission and 95 patients with non-significant remission. Logistic regression multivariate analysis results showed that the human epidermal growth factor receptor 2 positive, lower early enhancement rate after NACT, lower arterial stage net increment after NACT, and lower CT value of arterial phase of lesions would increase the probability of significant remission in patients with breast cancer after NACT (P<0.05). The area under the ROC curve of the model for predicting the degree of pathological remission of breast cancer after NACT was 0.984, the specificity was 93.7%, and the sensitivity was 95.7%. The calibration curve showed that the model result fit well with the actual result, and the DCA result showed that it had a high clinical net benefit value. Conclusion From the results of this study, DCE-MRI combined with MSCT enhanced scanning has a good predictive value for pathological remission degree after NACT for breast cancer, which can provide clinical guidance for further treatment.

Citation： CHEN Jin, HU Meixue, QUAN Yi. Predictive value of dynamic contrast-enhanced magnetic resonance imaging combined with multislice CT enhanced scanning for pathological remission after neoadjuvant chemotherapy in breast cancer. CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY, 2023, 30(1): 65-71. doi: 10.7507/1007-9424.202207057 Copy

1.	曹毛毛, 陳萬青. GLOBOCAN2020全球癌癥統計數據解讀. 中國醫學前沿雜志(電子版), 2021, 13(3): 63-69.
2.	McLaughlin R, Hylton N. MRI in breast cancer therapy monitoring. NMR Biomed, 2011, 24(6): 712-720.
3.	Kwong MS, Chung GG, Horvath LJ, et al. Postchemotherapy MRI overestimates residual disease compared with histopathology in responders to neoadjuvant therapy for locally advanced breast cancer. Cancer J, 2006, 12(3): 212-221.
4.	Li P, Wang X, Xu C, et al. 18F-FDG PET/CT radiomic predictors of pathologic complete response (pCR) to neoadjuvant chemotherapy in breast cancer patients. Eur J Nucl Med Mol Imaging, 2020, 47(5): 1116-1126.
5.	王福軍, 楊軍, 張健, 等. 氫溴酸山莨菪堿對心肺復蘇術后冠脈內皮功能的保護作用機制. 中國急救醫學, 2021, 41(1): 60-65.
6.	Zhang S, Xu X, Huang Y, et al. Anisodamine ameliorates ischemia/reperfusion-induced renal injury in rats through activation of the extracellular signal-regulated kinase (ERK) pathway and anti-apoptotic effect. Pharmazie, 2021, 76(5): 220-224.
7.	莫雁飛, 于宗良. 冠狀動脈微血管功能障礙對STEMI患者PPCI術后恢復的影響及其治療學進展. 藥物評價研究, 2018, 41(8): 1533-1540.
8.	中國臨床腫瘤學會指南工作委員會. 中國臨床腫瘤學會(CSCO)乳腺癌診療指南2021. 北京: 人民衛生出版社, 2021.
9.	康晶, 薛志偉, 王偉. 增強磁共振成像病灶-背景實質信號增強比預測乳腺癌新輔助化療病理性完全緩解的臨床研究. 東南大學學報(醫學版), 2020, 39(2): 184-190.
10.	王鋮, 劉國強, 陳杰, 等. CT雙期增強掃描診斷肺良惡性病變的效果. 世界臨床醫學, 2017, 11(19): 179, 181.
11.	曲天宇, 葛一涵, 趙毅. 乳腺癌患者新輔助化療后病理完全緩解的相關影響因素分析及列線圖預測模型的構建. 現代腫瘤醫學, 2021, 29(4): 590-594.
12.	Braman NM, Etesami M, Prasanna P, et al. Intratumoral and peritumoral radiomics for the pretreatment prediction of pathological complete response to neoadjuvant chemotherapy based on breast DCE-MRI. Breast Cancer Res, 2017, 19(1): 57. doi: 10.1186/s13058-017-0846-1.
13.	Foust AM, Ali RM, Nguyen XV, et al. Dual-energy CT-derived iodine content and spectral attenuation analysis of metastatic versus nonmetastatic lymph nodes in squamous cell carcinoma of the oropharynx. Tomography, 2018, 4(2): 66-71.
14.	肖正遠, 陳瀾菁, 傅建梅, 等. MSCT增強掃描對非特殊型乳腺癌腋窩淋巴結轉移的診斷價值. 重慶醫學, 2022, 51(3): 438-441.
15.	黃潔, 詹強. MRI聯合CT對乳腺良惡性病變的診斷價值研究. 現代醫用影像學, 2020, 29(12): 2253-2255.
16.	Zhang H, Pan Z, Du L, et al. Advanced gastric cancer and perfusion imaging using a multidetector row computed tomography: correlation with prognostic determinants. Korean J Radiol, 2008, 9(2): 119-127.
17.	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.
18.	Chen X, He C, Han D, et al. The predictive value of Ki-67 before neoadjuvant chemotherapy for breast cancer: a systematic review and meta-analysis. Future Oncol, 2017, 13(9): 843-857.
19.	周怡君, 英旻, 何英劍, 等. 原發性乳腺癌分子分型與新輔助化療療效的相關性分析. 中華醫學雜志, 2013, 93(22): 1711-1715.
20.	曾毅. 乳腺癌新輔助化療療效的影響因素分析. 臨床和實驗醫學雜志, 2014, 23(13): 1990-1992.
21.	Tamayo Caraba?o D, álvarez Pérez R, De Bonilla Damiá á, et al. Sentinel lymph node biopsy in N+ breast cancer with conversion into N0 after neoadjuvant chemotherapy. Rev Esp Med Nucl Imagen Mol (Engl Ed), 2019, 38(3): 140-146.
22.	艾國平, 劉江勇, 薛陽, 等. DCE-MRI定量參數對乳腺癌新輔助化療的療效評估及相關性分析. 放射學實踐, 2018, 33(11): 1150-1155.
23.	Henderson S, Purdie C, Michie C, et al. Interim heterogeneity changes measured using entropy texture features on T2-weighted MRI at 3.0 T are associated with pathological response to neoadjuvant chemotherapy in primary breast cancer. Eur Radiol, 2017, 27(11): 4602-4611.
24.	Silva AC, Morse BG, Hara AK, et al. Dual-energy (spectral) CT: applications in abdominal imaging. Radiographics, 2011, 31(4): 1031-1046.
25.	Lai X, Jiang Y, Zhang B, et al. Preoperative sonographic features of follicular thyroid carcinoma predict biological behavior: a retrospective study. Medicine (Baltimore), 2018, 97(41): e12814. doi: 10.1097/MD.0000000000012814.
26.	Moon WJ, Jung SL, Lee JH, et al. Benign and malignant thyroid nodules: US differentiation-multicenter retrospective study. Radiology, 2008, 247(3): 762-770.
27.	Amarnath J, Sangeeta T, Mehta SB. Role of quantitative pharmacokinetic parameter (transfer constant: K^trans) in the characterization of breast lesions on MRI. Indian J Radiol Imaging, 2013, 23(1): 19-25.

1. 曹毛毛, 陳萬青. GLOBOCAN2020全球癌癥統計數據解讀. 中國醫學前沿雜志(電子版), 2021, 13(3): 63-69.
2. McLaughlin R, Hylton N. MRI in breast cancer therapy monitoring. NMR Biomed, 2011, 24(6): 712-720.
3. Kwong MS, Chung GG, Horvath LJ, et al. Postchemotherapy MRI overestimates residual disease compared with histopathology in responders to neoadjuvant therapy for locally advanced breast cancer. Cancer J, 2006, 12(3): 212-221.
4. Li P, Wang X, Xu C, et al. 18F-FDG PET/CT radiomic predictors of pathologic complete response (pCR) to neoadjuvant chemotherapy in breast cancer patients. Eur J Nucl Med Mol Imaging, 2020, 47(5): 1116-1126.
5. 王福軍, 楊軍, 張健, 等. 氫溴酸山莨菪堿對心肺復蘇術后冠脈內皮功能的保護作用機制. 中國急救醫學, 2021, 41(1): 60-65.
6. Zhang S, Xu X, Huang Y, et al. Anisodamine ameliorates ischemia/reperfusion-induced renal injury in rats through activation of the extracellular signal-regulated kinase (ERK) pathway and anti-apoptotic effect. Pharmazie, 2021, 76(5): 220-224.
7. 莫雁飛, 于宗良. 冠狀動脈微血管功能障礙對STEMI患者PPCI術后恢復的影響及其治療學進展. 藥物評價研究, 2018, 41(8): 1533-1540.
8. 中國臨床腫瘤學會指南工作委員會. 中國臨床腫瘤學會(CSCO)乳腺癌診療指南2021. 北京: 人民衛生出版社, 2021.
9. 康晶, 薛志偉, 王偉. 增強磁共振成像病灶-背景實質信號增強比預測乳腺癌新輔助化療病理性完全緩解的臨床研究. 東南大學學報(醫學版), 2020, 39(2): 184-190.
10. 王鋮, 劉國強, 陳杰, 等. CT雙期增強掃描診斷肺良惡性病變的效果. 世界臨床醫學, 2017, 11(19): 179, 181.
11. 曲天宇, 葛一涵, 趙毅. 乳腺癌患者新輔助化療后病理完全緩解的相關影響因素分析及列線圖預測模型的構建. 現代腫瘤醫學, 2021, 29(4): 590-594.
12. Braman NM, Etesami M, Prasanna P, et al. Intratumoral and peritumoral radiomics for the pretreatment prediction of pathological complete response to neoadjuvant chemotherapy based on breast DCE-MRI. Breast Cancer Res, 2017, 19(1): 57. doi: 10.1186/s13058-017-0846-1.
13. Foust AM, Ali RM, Nguyen XV, et al. Dual-energy CT-derived iodine content and spectral attenuation analysis of metastatic versus nonmetastatic lymph nodes in squamous cell carcinoma of the oropharynx. Tomography, 2018, 4(2): 66-71.
14. 肖正遠, 陳瀾菁, 傅建梅, 等. MSCT增強掃描對非特殊型乳腺癌腋窩淋巴結轉移的診斷價值. 重慶醫學, 2022, 51(3): 438-441.
15. 黃潔, 詹強. MRI聯合CT對乳腺良惡性病變的診斷價值研究. 現代醫用影像學, 2020, 29(12): 2253-2255.
16. Zhang H, Pan Z, Du L, et al. Advanced gastric cancer and perfusion imaging using a multidetector row computed tomography: correlation with prognostic determinants. Korean J Radiol, 2008, 9(2): 119-127.
17. 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.
18. Chen X, He C, Han D, et al. The predictive value of Ki-67 before neoadjuvant chemotherapy for breast cancer: a systematic review and meta-analysis. Future Oncol, 2017, 13(9): 843-857.
19. 周怡君, 英旻, 何英劍, 等. 原發性乳腺癌分子分型與新輔助化療療效的相關性分析. 中華醫學雜志, 2013, 93(22): 1711-1715.
20. 曾毅. 乳腺癌新輔助化療療效的影響因素分析. 臨床和實驗醫學雜志, 2014, 23(13): 1990-1992.
21. Tamayo Caraba?o D, álvarez Pérez R, De Bonilla Damiá á, et al. Sentinel lymph node biopsy in N+ breast cancer with conversion into N0 after neoadjuvant chemotherapy. Rev Esp Med Nucl Imagen Mol (Engl Ed), 2019, 38(3): 140-146.
22. 艾國平, 劉江勇, 薛陽, 等. DCE-MRI定量參數對乳腺癌新輔助化療的療效評估及相關性分析. 放射學實踐, 2018, 33(11): 1150-1155.
23. Henderson S, Purdie C, Michie C, et al. Interim heterogeneity changes measured using entropy texture features on T2-weighted MRI at 3.0 T are associated with pathological response to neoadjuvant chemotherapy in primary breast cancer. Eur Radiol, 2017, 27(11): 4602-4611.
24. Silva AC, Morse BG, Hara AK, et al. Dual-energy (spectral) CT: applications in abdominal imaging. Radiographics, 2011, 31(4): 1031-1046.
25. Lai X, Jiang Y, Zhang B, et al. Preoperative sonographic features of follicular thyroid carcinoma predict biological behavior: a retrospective study. Medicine (Baltimore), 2018, 97(41): e12814. doi: 10.1097/MD.0000000000012814.
26. Moon WJ, Jung SL, Lee JH, et al. Benign and malignant thyroid nodules: US differentiation-multicenter retrospective study. Radiology, 2008, 247(3): 762-770.
27. Amarnath J, Sangeeta T, Mehta SB. Role of quantitative pharmacokinetic parameter (transfer constant: K^trans) in the characterization of breast lesions on MRI. Indian J Radiol Imaging, 2013, 23(1): 19-25.

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CHINESE JOURNAL OF BASES AND CLINICS IN GENERAL SURGERY

Predictive value of dynamic contrast-enhanced magnetic resonance imaging combined with multislice CT enhanced scanning for pathological remission after neoadjuvant chemotherapy in breast cancer

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