The value of predicting contrast agent extravasation after mechanical thrombectomy for acute middle cerebral artery occlusion based on radiomics features of non-contrast computed tomography

doi:10.11817/j.issn.1673-9248.2024.03.004

Abstract

Abstract:

Objective

To explore the application value of imaging omics based on non-contrast computed tomography (NCCT) in predicting extravasation of contrast agents during endovascular mechanical thrombectomy in patients with unilateral middle cerebral artery occlusion stroke.

Methods

A total of 96 patients with clinically diagnosed middle cerebral artery thrombosis and underwent endovascular mechanical thrombectomy in Suzhou kowloon Hospital, Shanghai Jiaotong University School of Medicine, were collected, including 67 patients in the exudative group and 29 patients in the non-exudative group. All patients were randomly assigned into a training set (67 cases) and a test set (29 cases) at a ratio of 7:3. The regions of interest of NCCT images were delineated using ITK-SNAP software to extract radiological characteristics. Mann-Whitney U test, Pearson correlation coefficient (Pearson), and the least absolute shrinkage and selection operator were used for feature selection. Models were trained and tested using Random Forest (RF) and Extreme Gradient Boosting (XGBoost). The ROC curves were plotted, and the area under the ROC curve (AUC), sensitivity, specificity, and optimal thresholds were calculated. The clinical utility of the models was further assessed through decision curve analysis (DCA).

Results

Through screening, we obtained 6 imaging radiomics features that have the greatest predictive power. The training model of RF demonstrated the highest predictive efficiency. The AUC value of the model in the training group was 0.997, 95%CI: 0.990-1.000, and the accuracy, sensitivity, specificity and optimal thresholds were 97.0%, 97.8%, 95.2%, and 0.700, respectively. The DCA curve showed that the model threshold had a high clinical net benefit across a broad range, specifically from 0.5 to 0.9.

Conclusion

Machine learning based on NCCT demonstrates a high predictive value for the extravasation detection of contrast media during embolectomy of the middle cerebral artery.

Key words: Radiomics feature, Cerebral infarction, Middle cerebral artery, Embolectomy, Contrast agent exudation

Lelin Yu, Hailong Shang, Hongdi Du, Ying Wang, Yichao Wang, Changhe Xu, Juan Ye, Shiwei Zhao, Fanghui Zheng, Hui Shen, Hailin Shen. The value of predicting contrast agent extravasation after mechanical thrombectomy for acute middle cerebral artery occlusion based on radiomics features of non-contrast computed tomography[J]. Chinese Journal of Cerebrovascular Diseases(Electronic Edition), 2024, 18(03): 215-223.

/ / Recommend

Add to citation manager EndNote|Ris|BibTeX

URL: https://zhnxgbzz.cma-cmc.com.cn/EN/10.11817/j.issn.1673-9248.2024.03.004

https://zhnxgbzz.cma-cmc.com.cn/EN/Y2024/V18/I03/215

Figures/Tables 9

变量	外渗组（n=46）	非外渗组（n=21）	统计值	P值
年龄（岁， $x ¯ ± s$ ）	64.43±12.69	57.81±13.97	t=1.921	0.059
男性[例（%）]	43（93.5）	17（81.0）	χ²=2.374	0.123
发病到CT平扫检查时长[h，M（Q_R）]	4.00（3.00~5.50）	3.50（2.00~6.25）	Z=-1.101	0.271
手术时长[h，M（Q_R）]	2.50（2.00~4.00）	2.00（1.25~2.75）	Z=-2.278	0.023
溶栓史[例（%）]	6（13.0）	3（14.3）	χ²=0.000	1.000
ASPECTS评分[分，M（Q_R）]	8.00（7.00~8.25）	8.00（6.50~9.00）	Z=-0.502	0.616
与卒中相关的危险因素[例（%）]
高血压	32（69.6）	13（61.9）	χ²=0.384	0.536
高脂血症	1（2.1）	2（9.5）	－	0.229
糖尿病	5（10.9）	4（19.0）	χ²=0.275	0.600
冠心病	9（19.6）	3（14.3）	χ²=0.032	0.858
心房颤动	15（32.6）	7（33.3）	χ²=0.003	0.953
既往卒中或短暂性脑缺血发作病史	6（13.0）	5（23.8）	χ²=0.560	0.454
吸烟	12（26.1）	6（28.6）	χ²=0.045	0.831
饮酒	9（19.6）	4（19.0）	χ²=0.000	1.000
血压（mmHg， $x ¯ ± s$ ）
收缩压	149.00±25.80	145.29±22.55	t=0.597	0.553
舒张压	87.26±12.88	88.19±10.51	t=-0.289	0.773
NIHSS评分[分，M（Q_R）]	12.0（8.0~23.0）	10.0（7.5~19.0）	Z=-0.907	0.364

变量	外渗组（n=46）	非外渗组（n=21）	统计值	P值
年龄（岁， $x ¯ ± s$ ）	64.43±12.69	57.81±13.97	t=1.921	0.059
男性[例（%）]	43（93.5）	17（81.0）	χ²=2.374	0.123
发病到CT平扫检查时长[h，M（Q_R）]	4.00（3.00~5.50）	3.50（2.00~6.25）	Z=-1.101	0.271
手术时长[h，M（Q_R）]	2.50（2.00~4.00）	2.00（1.25~2.75）	Z=-2.278	0.023
溶栓史[例（%）]	6（13.0）	3（14.3）	χ²=0.000	1.000
ASPECTS评分[分，M（Q_R）]	8.00（7.00~8.25）	8.00（6.50~9.00）	Z=-0.502	0.616
与卒中相关的危险因素[例（%）]
高血压	32（69.6）	13（61.9）	χ²=0.384	0.536
高脂血症	1（2.1）	2（9.5）	－	0.229
糖尿病	5（10.9）	4（19.0）	χ²=0.275	0.600
冠心病	9（19.6）	3（14.3）	χ²=0.032	0.858
心房颤动	15（32.6）	7（33.3）	χ²=0.003	0.953
既往卒中或短暂性脑缺血发作病史	6（13.0）	5（23.8）	χ²=0.560	0.454
吸烟	12（26.1）	6（28.6）	χ²=0.045	0.831
饮酒	9（19.6）	4（19.0）	χ²=0.000	1.000
血压（mmHg， $x ¯ ± s$ ）
收缩压	149.00±25.80	145.29±22.55	t=0.597	0.553
舒张压	87.26±12.88	88.19±10.51	t=-0.289	0.773
NIHSS评分[分，M（Q_R）]	12.0（8.0~23.0）	10.0（7.5~19.0）	Z=-0.907	0.364

变量	训练集（n=67）	测试集（n=29）	统计值	P值
年龄（岁， $x ¯ ± s$ ）	62.36±13.36	64.72±19.28	t=-0.601	0.551
男性[例（%）]	41（61.2）	19（65.5）	χ²=0.161	0.688
发病到CT平扫检查时长[h，M（Q_R）]	4.00（2.50~5.50）	3.50（2.25~4.75）	Z=-1.427	0.154
手术时长[h，M（Q_R）]	2.00（1.50~3.50）	2.50（2.00~3.25）	Z=-0.558	0.577
溶栓史[例（%）]	14（20.9）	4（13.8）	χ²=0.670	0.413
ASPECTS评分[分，M（Q_R）]	8（7~9）	8（7~9）	Z=-1.907	0.057
与卒中相关的危险因素[例（%）]
高血压	45（67.2）	22（75.9）	χ²=0.726	0.394
高脂血症	3（4）	2（7）	χ²=0.240	0.624
糖尿病	9（13.4）	5（17.2）	χ²=0.236	0.627
冠心病	12（17.9）	5（17.2）	χ²=0.006	0.937
心房颤动	22（32.8）	10（34.4）	χ²=0.025	0.875
既往卒中或短暂性脑缺血发作病史	11（16.4）	7（24.1）	χ²=0.792	0.374
吸烟	18（26.9）	9（31.0）	χ²=0.174	0.677
饮酒	13（19.4）	4（13.8）	χ²=0.437	0.509
血压（mmHg， $x ¯ ± s$ ）
收缩压	147.84±24.72	141.79±17.54	t=1.361	0.178
舒张压	87.55±12.11	85.76±12.58	t=0.658	0.512
NIHSS评分[分，M（Q_R）]）	12.0（8.0~23.0）	12.0（11.5~23.0）	Z=-1.441	0.150

变量	训练集（n=67）	测试集（n=29）	统计值	P值
年龄（岁， $x ¯ ± s$ ）	62.36±13.36	64.72±19.28	t=-0.601	0.551
男性[例（%）]	41（61.2）	19（65.5）	χ²=0.161	0.688
发病到CT平扫检查时长[h，M（Q_R）]	4.00（2.50~5.50）	3.50（2.25~4.75）	Z=-1.427	0.154
手术时长[h，M（Q_R）]	2.00（1.50~3.50）	2.50（2.00~3.25）	Z=-0.558	0.577
溶栓史[例（%）]	14（20.9）	4（13.8）	χ²=0.670	0.413
ASPECTS评分[分，M（Q_R）]	8（7~9）	8（7~9）	Z=-1.907	0.057
与卒中相关的危险因素[例（%）]
高血压	45（67.2）	22（75.9）	χ²=0.726	0.394
高脂血症	3（4）	2（7）	χ²=0.240	0.624
糖尿病	9（13.4）	5（17.2）	χ²=0.236	0.627
冠心病	12（17.9）	5（17.2）	χ²=0.006	0.937
心房颤动	22（32.8）	10（34.4）	χ²=0.025	0.875
既往卒中或短暂性脑缺血发作病史	11（16.4）	7（24.1）	χ²=0.792	0.374
吸烟	18（26.9）	9（31.0）	χ²=0.174	0.677
饮酒	13（19.4）	4（13.8）	χ²=0.437	0.509
血压（mmHg， $x ¯ ± s$ ）
收缩压	147.84±24.72	141.79±17.54	t=1.361	0.178
舒张压	87.55±12.11	85.76±12.58	t=0.658	0.512
NIHSS评分[分，M（Q_R）]）	12.0（8.0~23.0）	12.0（11.5~23.0）	Z=-1.441	0.150

模型	准确性	AUC	95%可信区间	敏感度	特异度	最佳阈值
随机森林
训练集	0.970	0.997	0.990~1.000	0.978	0.952	0.700
测试集	0.724	0.810	0.625~0.942	0.762	0.625	0.700
XGBoost
训练集	0.955	0.993	0.981~1.000	0.957	0.952	0.486
测试集	0.737	0.808	0.595~1.000	0.846	0.833	0.573

References 29

21	Choi MH, Park GH, Lee JS, et al. Erythrocyte fraction within retrieved thrombi contributes to thrombolytic response in acute ischemic stroke [J]. Stroke, 2018, 49(3): 652-659.
22	Shin JW, Jeong HS, Kwon HJ, et al. High red blood cell composition in clots is associated with successful recanalization during intra-arterial thrombectomy [J]. PLoS One, 2018, 13(5): e0197492.
23	Hofmeister J, Bernava G, Rosi A, et al. Clot-based radiomics predict a mechanical thrombectomy strategy for successful recanalization in acute ischemic stroke [J]. Stroke, 2020, 51(8): 2488-2494.
24	Sarioglu O, Sarioglu FC, Capar AE, et al. Clot-based radiomics features predict first pass effect in acute ischemic stroke [J]. Interv Neuroradiol, 2022, 28(2): 160-168.
25	Van Voorst H, Bruggeman AAE, Yang W, et al. Thrombus radiomics in patients with anterior circulation acute ischemic stroke undergoing endovascular treatment [J]. J Neurointerv Surg, 2023, 15(e1): e79-e85.
26	Lummel N, Schulte-Altedorneburg G, Bernau C, et al. Hyperattenuated intracerebral lesions after mechanical recanalization in acute stroke [J]. AJNR Am J Neuroradiol, 2014, 35(2): 345-351.
27	Renú A, Amaro S, Laredo C, et al. Relevance of blood-brain barrier disruption after endovascular treatment of ischemic stroke: dual-energy computed tomographic study [J]. Stroke, 2015, 46(3): 673-679.
28	Aerts H, Velazquez ER, Leijenaar R, et al. Corrigendum: decoding tumour phenotype by noninvasive imaging using a quantitative radiomics approach [J]. Nat Commun, 2014, 5: 4006.
29	Song Y, Yin Z, Zhang C, et al. Random forest classifier improving phenylketonuria screening performance in two Chinese populations [J]. Front Mol Biosci, 2022, 9: 986556.
1	Warner JJ, Harrington RA, Sacco RL, et al. Guidelines for the early management of patients with acute ischemic stroke: 2019 update to the 2018 guidelines for the early management of acute ischemic stroke [J]. Stroke, 2019, 50(12): 3331-3332.
2	Powers WJ, Derdeyn CP, Biller J, et al. 2015 American Heart Association/American Stroke Association focused update of the 2013 guidelines for the early management of patients with acute ischemic stroke regarding endovascular treatment: a guideline for healthcare professionals from the American Heart Association/American Stroke Association [J]. Stroke, 2015, 46(10): 3020-3035.
3	Ohta H, Nakano S, Yokogami K, et al. Appearance of early venous filling during intra-arterial Reperfusion therapy for acute middle cerebral artery occlusion - a predictive sign for hemorrhagic complications [J]. Stroke, 2004, 35(4): 893-898.
4	Wang D, Liu J, Liu M, et al. Patterns of stroke between university hospitals and nonuniversity hospitals in mainland China: prospective multicenter hospital-based registry study [J]. World Neurosurg, 2017, 98: 258-265.
5	Chen Z, Zhang Y, Su Y, et al. Contrast extravasation is predictive of poor clinical outcomes in patients undergoing endovascular therapy for acute ischemic stroke in the anterior circulation [J]. J Stroke Cerebrovasc Dis, 2019, 29(1): 104494.
6	王艳, 李倩文, 郭道德, 等. CTP预测急性缺血性卒中患者脑动脉机械取栓术后对比剂外渗风险的初步研究 [J]. 医学影像学杂志, 2022, 32(7): 1085-1089.
7	Tang TY, Jiao Y, Cui Y, et al. Penumbra-based radiomics signature as prognostic biomarkers for thrombolysis of acute ischemic stroke patients: a multicenter cohort study [J]. J Neurol, 2020, 267(5): 1454-1463.
8	Chen X, Li Y, Zhou Y, et al. CT-based radiomics for differentiating intracranial contrast extravasation from intraparenchymal haemorrhage after mechanical thrombectomy [J]. Eur Radiol, 2022, 32(7): 4771-4779.
9	Ma Y, Wang J, Zhang H, et al. A CT-based radiomics nomogram for classification of intraparenchymal hyperdense areas in patients with acute ischemic stroke following mechanical thrombectomy treatment [J]. Front Neurosci, 2022, 16: 1061745.
10	Xu T, Wang Y, Yuan J, et al. Contrast extravasation and outcome of endovascular therapy in acute ischaemic stroke: a systematic review and meta-analysis [J]. BMJ Open, 2021, 11(7): e044917.
11	You SH, Kim B, Kim BK, et al. MR imaging for differentiating contrast staining from hemorrhagic transformation after endovascular thrombectomy in acute ischemic stroke: phantom and patient study [J]. AJNR Am J Neuroradiol, 2018, 39(12): 2313-2319.
12	霍礼功, 王钰, 陈蓓蕾, 等. 血脑屏障通透性定量评估及其在急性缺血性卒中患者中的应用 [J]. 国际脑血管病杂志, 2019, 27(4): 287-293.
13	Yedavalli V, Sammet S. Contrast extravasation versus hemorrhage after thrombectomy in patients with acute stroke [J]. J Neuroimaging, 2017, 27(6): 570-576.
14	Dekeyzer S, Nikoubashman O, Lutin B, et al. Distinction between contrast staining and hemorrhage after endovascular stroke treatment: one CT is not enough [J]. J Neurointerv Surg, 2017, 9(4): 394-398.
15	Bilgic AB, Gocmen R, Arsava EM, et al. The Effect of clot volume and permeability on response to intravenous tissue plasminogen activator in acute ischemic stroke [J]. J Stroke Cerebrovasc Dis, 2020, 29(2): 104541.
16	Dutra BG, Tolhuisen ML, Alves HCBR, et al. Thrombus imaging characteristics and outcomes in acute ischemic stroke patients undergoing endovascular treatment [J]. Stroke, 2019, 50(8): 2057-2064.
17	Shin JW, Jeong HS, Kwon HJ, et al. High red blood cell composition in clots is associated with successful recanalization during intra-arterial thrombectomy [J]. PLoS One, 2018, 13(5): e0197492.
18	Aliena-Valero A, Baixauli-Martín J, Torregrosa G, et al.Clot composition analysis as a diagnostic tool to gain insight into ischemic stroke etiology: a systematic review [J]. J Stroke, 2021, 23(3): 327-342.
19	Patel TR, Fricano S, Waqas M, et al. Increased perviousness on CT for acute ischemic stroke is associated with fibrin/platelet-rich clots [J]. AJNR Am J Neuroradiol, 2021, 42(1): 57-64.
20	Patel TR, Santo BA, Baig AA, et al. Histologically interpretable clot radiomic features predict treatment outcomes of mechanical thrombectomy for ischemic stroke [J]. Neuroradiology, 2023, 65(4): 737-749.

[1]	Shujie Wei, Pinjing Hui, Yafang Ding, Bai Zhang, Yanhong Yan, Peng Zhou, Yabo Huang. Evaluation of cerebral hemodynamics in patients with unilateral internal carotid artery occlusion undergoing superficial temporal artery-middle cerebral artery bypass [J]. Chinese Journal of Medical Ultrasound (Electronic Edition), 2023, 20(10): 1046-1055.
[2]	Huanyan Liu, Yang Hua, Lingyun Jia, Xinyu Zhao, Beibei Liu. Lumen structure and hemodynamic characteristics of occluded internal carotid artery [J]. Chinese Journal of Medical Ultrasound (Electronic Edition), 2023, 20(08): 809-815.
[3]	Ze Yuan, Li Zhuang. Value of ultrasound detection of fetal umbilical artery and middle cerebral artery blood flow in diagnosis of fetal intrauterine distress [J]. Chinese Journal of Medical Ultrasound (Electronic Edition), 2023, 20(06): 618-621.
[4]	Yi Zhang, Xiujun Ren, Mengwei Guo, Yafang Zhao, Yifan Li, Jiayang Li, Xiaoxuan Ren, Jihong Wu, Haiyang Lu. Effects of electroacupuncture preconditioning on behavioural and peripheral blood EPCs in cerebral ischaemia-reperfusion injury rats [J]. Chinese Journal of Neurotraumatic Surgery(Electronic Edition), 2024, 10(02): 71-77.
[5]	Xin Cui, Peng Zhang, Tongnan Gu, Yanzhi Zhao. Effect of sulbactam on brain tissue injury in rats with focal cerebral ischemia-reperfusion [J]. Chinese Journal of Neurotraumatic Surgery(Electronic Edition), 2023, 09(06): 333-337.
[6]	Chenyu Chu, Qiang Xu, Junhua Rao, Yuefeng Li. Taking supraorbital keyhole approach operation to build cynomolgus monkey middle cerebral artery occlusion model [J]. Chinese Journal of Brain Diseases and Rehabilitation(Electronic Edition), 2024, 14(01): 8-13.
[7]	Lihui Dou, Peng Li, Jingmin Dou, Guiling Wang. Therapeutic effect of syndrome differentiation acupuncture and moxibustion combined with bifidobacterium triple live bacteria capsule in the treatment of functional dyspepsia with spleen and stomach weakness during cerebral infarction convalescence [J]. Chinese Journal of Digestion and Medical Imageology(Electronic Edition), 2024, 14(03): 218-221.
[8]	Qian Zhao, Wenchao Liu, Xilin Li, Qiudong Zhang. Risk factors analysis and model construction of gastrointestinal injury induced by acute cerebral infarction in the elderly [J]. Chinese Journal of Digestion and Medical Imageology(Electronic Edition), 2024, 14(03): 213-217.
[9]	Yiren Liu, Shijun Cui, Zhu Tong, Jianming Guo, Shengjia Yang, Yongquan Gu, Lianrui Guo. Aspiration therapy for acute embolic occlusion of the superior mesenteric artery [J]. Chinese Journal of Interventional Radiology(Electronic Edition), 2024, 12(02): 131-136.
[10]	Chaotao Nan, Jian Chen, Shuhong Wang, Gang Li, Junjie Hao. Value of serum cytokines in predicting pneumonia secondary to acute cerebral infarction [J]. Chinese Journal of Hygiene Rescue(Electronic Edition), 2024, 10(01): 16-20.
[11]	Yu Liu, Xiaoxiao Xu, Ziyu Gu, Zhouquan Wu. Feasibility of transcranial color Doppler in intraoperative cerebral blood flow monitoring [J]. Chinese Journal of Hygiene Rescue(Electronic Edition), 2023, 09(06): 343-347.
[12]	Xuan Chen, Ningjiang Ou, Jiemei Ye, Jinqian Deng. Correlation between polymorphisms of fibrinogen β-chain promoter gene and the stability of carotid atherosclerotic plaques [J]. Chinese Journal of Cerebrovascular Diseases(Electronic Edition), 2024, 18(01): 33-39.
[13]	Hongyuan Li, Shuyu Dong, Hanbing Lu. Predictive effect of serum Hcy, sdLDL-C, and Lp-PLA2 levels on the progression of transient ischemic attack to acute cerebral infarction [J]. Chinese Journal of Cerebrovascular Diseases(Electronic Edition), 2024, 18(01): 40-48.
[14]	Huagang Zhang, Xiaoqian Wang, Chen Zhang, Yu Fu, Xiaogang Li, Dongsheng Fan, Yue Wang, Ju Shi, Shuhong Bi. Trend and influencing factors of hospitalization expenses in patients with acute cerebral infarction: an analysis from a tertiary hospital in Beijing [J]. Chinese Journal of Cerebrovascular Diseases(Electronic Edition), 2023, 17(06): 557-564.
[15]	Jialun Xin, Xingyun Yuan, Zhiqin Liu, Rui Shi, Feng Jiang, Fengchang Liu, Weiwang Li, Heng Zhang, Qiang Guo, Jianbo He, Li Yao. Clinical efficacy of drug-eluting stents in emergency angioplasty for patients with acute middle cerebral artery atherosclerotic occlusive stroke [J]. Chinese Journal of Cerebrovascular Diseases(Electronic Edition), 2023, 17(06): 539-544.

Please choose a citation manager

Content to export