1.Value of introvoxel incoherent motion model in assessment of differentiation and blood supply of cervical cancer
Yan ZHOU ; Jianyu LIU ; Congrong LIU ; Jing JIA ; Shunan CHE ; Nan LI ; Zhenyu ZHOU
Chinese Journal of Radiology 2015;(5):354-359
Objective To investigate the value of intravoxel incoherent motion (IVIM) model of diffusion weighted MRI in assessing grades and enhancement patten of uterine cervical cancer. Methods Thirty one patients with pathologically proven cervical cancer, who underwent MRI scan preoperatively, were analyzed retrospectively and were divided into 3 groups according to their pathological grading of cacer, including 6 with G1 cancer, 17 with G2 and 8 with G3. The diameter of each lesion was≥1 cm. 10 b values (0, 30, 50, 100, 150, 200, 400, 800, 1 000, 1 500 s/mm2) were used in DWI, and DCE-MRI was performed with a time resolution of 9.8 s. Parameters of DWI (ADC, D, f, D*) and semiquantitative parameters of DCE-MRI (Slop, Maxslop, CER, Washout, AUC90) were measured. One-way ANOVA analysis of variance and Pearson correlation were used to analyze normally distributed continuous data. Kruskal-Wallis H test and Spearman correlation were used to analyze abnormally distributed continuous data. Tumor volume and all of the MRI parameters were compared as well as correlated with pathological grading.The perfusion parameters derived from IVIM were correlated with those derived from dynamic enhanced MR imaging. The sensitivity and specificity of f value to to diagnose G3 cervical cancer and the best cutoff were calculated from areas under the ROC curves.Results Tumor volume of G1,G2 and G3 cancers were(33.8±31.1),(19.6±16.9)and(31.2±29.1)cm3(F=1.147,P=0.332), respectively.ADC values of the three groups were(1.03 ± 0.11)× 10-3,(1.00 ± 0.10)× 10-3 and(0.90 ± 0.05)× 10-3mm2/s,respectively(F=4.619,P=0.018).D values of the three groups were (0.80 ± 0.11) × 10-3, (0.77 ± 0.06) × 10-3and (0.69 ± 0.06) × 10-3mm2/s ,respectively(F=5.272, P=0.011).f values of the three groups were 0.20±0.02, 0.22±0.03 and 0.24± 0.03, respectively (F=3.524, P=0.043).All of the others were of no significant difference (P>0.05).Both ADC and D correlated negatively with tumor grading (r=-0.464 and-0.493, P=0.009 and 0.005, respectively). f value correlated positively with tumor grading (r=0.436, P=0.014).Areas of ADC, D and f value under ROC curves to diagnose G3 cancers were 0.179, 0.147 and 0.690, respectively. While the cut-off value of f was 0.22, the diagnostic performance for G3 cancer was with a sensitivity of 75.0% (6/8) and a specificity of 60.9% (14/23). The value of f had weak positive correlations with Slop, Maxslop, CER and AUC90 of semiquantitative analysis of DCE-MRI (r=0.319, 0.337, 0.293 and 0.344, respectively, P<0.01). Conclusion IVIM model of multi-b value DWI may provide information in the assessment of differentiation and en hancement pattern of cervical cancer.
2. The value of diffusion kurtosis imaging in diagnosing breast lesions and its diagnostic efficacy combined with diffusion weighted imaging
Chenglu KE ; Shunan CHE ; Jing LI
Chinese Journal of Radiology 2018;52(8):593-597
Objective:
To investigate the diagnostic value of diffusion kurtosis imaging (DKI) and its combination with DWI for differentiating benign and malignant breast lesions.
Methods:
Eighty two patients with clinically suspected breast lesions from May 2016 to February 2017 in the Cancer Hospital of Chinese Academy of Medical Sciences were prospectively enrolled in the study. Mammary MRI was performed in all the all patients (89 lesions), and the pathology results were confirmed by surgery or biopsies. All of them underwent 3.0 T MR examinations, including conventional fat-suppression imaging, DWI, DKI and dynamic contrast-enhanced MR imaging (DCE-MRI). The ADC values, mean diffusivity (MD), and mean diffusion kurtosis (MK) values of lesions were obtained, and the lesion morphology, enhancement patterns, and time-signal intensity curve (TIC) types were observed. Independent-samples
3.Comparison of MRI and CT for target volume delineation and dose coverage for partial breast irradiation in patients with breast cancer
Yuchun SONG ; Xin XIE ; Shunan CHE ; Guangyi SUN ; Yu TANG ; Jianghu ZHANG ; Jianyang WANG ; Hui FANG ; Bo CHEN ; Yongwen SONG ; Jing JIN ; Yueping LIU ; Shunan QI ; Yuan TANG ; Ningning LU ; Hao JING ; Yong YANG ; Ning LI ; Jing LI ; Shulian WANG ; Yexiong LI
Chinese Journal of Radiation Oncology 2021;30(3):244-248
Objective:To compare magnetic resonance imaging (MRI)-based and computed tomography (CT)-based target volume delineation and dose coverage in partial breast irradiation (PBI) for patients with breast cancer, aiming to explore the application value of MRI localization in PBI after breast-conserving surgery.Methods:Twenty-nine patients with early breast cancer underwent simulating CT and MRI scans in a supine position. The cavity visualization score (CVS) of tumor bed (TB) was evaluated. The TB, clinical target volume (CTV), planning target volume (PTV) were delineated on CT and MRI images, and then statistically compared. Conformity indices (CI) between CT- and MRI-defined target volumes were calculated. PBI treatment plan of 40 Gy in 10 fractions was designed based on PTV-CT, and the dose coverage for PTV-MRI was evaluated.Results:The CVS on CT and MRI images was 2.97±1.40 vs. 3.10±1.40( P=0.408). The volumes of TB, CTV, PTV on MRI were significantly larger than those on CT, (24.48±16.60) cm 3vs. (38.00±19.77) cm 3, (126.76±56.81) cm 3vs. (168.42±70.54) cm 3, (216.63±81.99) cm 3vs. (279.24±101.55) cm 3, respectively, whereas the increasing percentage of CTV and PTV were significantly smaller than those of TB. The CI between CT-based and MRI-based TB, CTV, PTV were 0.43±0.13, 0.66±0.11, 0.70±0.09( P<0.001), respectively. The median percentage of PTV-MRI receiving 40 Gy dose was 81.9%(62.3% to 92.4%), significantly lower than 95.6%(95.0%~97.5%) of PTV-CT. Conclusions:The CVS between CT and MRI is not significantly different, but the MRI-based TB, CTV, PTV are significantly larger than CT-based values. The PTV-MRI is of underdose if PBI treatment plan is designed for PTV-CT. As a supplement of CT scan, MRI can enhance the accuracy of TB delineation after breast-onserving surgery.
4.Preoperative prediction of Ki-67 expression status in breast cancer based on dynamic contrast enhanced MRI radiomics combined with clinical imaging features model
Shunan CHE ; Mei XUE ; Jing LI ; Yuan TIAN ; Jiesi HU ; Sicong WANG ; Xinming ZHAO ; Chunwu ZHOU
Chinese Journal of Radiology 2022;56(9):967-975
Objective:To investigate the value of preoperative prediction of Ki-67 expression status in breast cancer based on multi-phase enhanced MRI combined with clinical imaging characteristics prediction model.Methods:This study was retrospective. A total of 213 breast cancer patients who underwent surgical treatment at Cancer Hospital, Chinese Academy of Medical Sciences and Peking Union Medical College between June 2016 and May 2017 were enrolled. All patients were female, aged 24-78 (51±10) years, and underwent routine breast MRI within 2 weeks prior to surgery. According to the different Ki-67 expression of postoperative pathological results, patients were divided into high expression group (Ki-67≥20%, 153 cases) and low expression group (Ki-67<20%, 60 cases). The radiomic features of breast cancer lesions were extracted from phase 2 (CE-2) and phase 7 (CE-7) images of dynamic contrast enhanced (DCE)-MRI, and all cases were divided into training and test sets according to the ratio of 7∶3. The radiomic features were first selected using ANOVA and Wilcoxon signed-rank test, followed by the least absolute shrinkage and selection operator method regression model. The same method of parameters selection was applied to clinical information and conventional imaging features [including gland classification, degree of background parenchymal enhancement, multifocal/multicentric, lesion location, lesion morphology, lesion long diameter, lesion short diameter, T 2WI signal characteristics, diffusion-weighted imaging (DWI) signal characteristics, apparent diffusion coefficient (ADC) values, time-signal intensity curve type, and axillary lymph nodes larger than 1 cm in short axis]. Support vector machine (SVM) was then used to construct prediction models for Ki-67 high and low expression states. The predictive performance of the models were evaluated using receiver operating characteristic (ROC) curves and area under cueve(AUC). Results:Totally 1 029 radiomic features were extracted from CE-2 and CE-7 images, respectively, and 9 and 7 best features were obtained after selection, respectively. And combining the two sets of features for a total of 16 features constituted the CE-2+CE-7 image best features. Five valuable parameters including lesion location, lesion short diameter, DWI signal characteristics, ADC values, and axillary lymph nodes larger than 1 cm in short axis, were selected from all clinical image features. The SVM prediction models obtained from the radiomic features of CE-2 and CE-7 images had a high AUC in predicting Ki-67 expression status (>0.70) in both the training set and the test set. The models were constructed by combining the CE-2, CE-7, and CE-2+CE-7 radiomic features with clinical imaging features, respectively, and the corresponding model performance in predicting Ki-67 expression status was improved compared with the models obtained by using the CE-2, CE-7, and CE-2+CE-7 radiomic features alone. The SVM prediction model obtained from CE-2+CE-7 radiomic features combined with clinical imaging features had the best prediction performance, with AUC of 0.895, accuracy of 84.6%, sensitivity of 87.9%, and specificity of 76.2% for predicting Ki-67 expression status in the training set and AUC of 0.822, accuracy of 70.3%, sensitivity of 76.1%, and specificity of 55.6% in test sets.Conclusion:The SVM prediction model based on DCE-MRI radiomic features can effectively predict Ki-67 expression status, and the combination of radiomic features and clinical imaging features can further improve the model prediction performance.