nach oben

Erschienen in:

30.01.2020 | Gastrointestinal

Predicting the ISUP grade of clear cell renal cell carcinoma with multiparametric MR and multiphase CT radiomics

verfasst von: Enming Cui, Zhuoyong Li, Changyi Ma, Qing Li, Yi Lei, Yong Lan, Juan Yu, Zhipeng Zhou, Ronggang Li, Wansheng Long, Fan Lin

Erschienen in: European Radiology | Ausgabe 5/2020

Einloggen, um Zugang zu erhalten

Abstract

Objective

To investigate externally validated magnetic resonance (MR)–based and computed tomography (CT)–based machine learning (ML) models for grading clear cell renal cell carcinoma (ccRCC).

Materials and methods

Patients with pathologically proven ccRCC in 2009–2018 were retrospectively included for model development and internal validation; patients from another independent institution and The Cancer Imaging Archive dataset were included for external validation. Features were extracted from T1-weighted, T2-weighted, corticomedullary-phase (CMP), and nephrographic-phase (NP) MR as well as precontrast-phase (PCP), CMP, and NP CT. CatBoost was used for ML-model investigation. The reproducibility of texture features was assessed using intraclass correlation coefficient (ICC). Accuracy (ACC) was used for ML-model performance evaluation.

Results

Twenty external and 440 internal cases were included. Among 368 and 276 texture features from MR and CT, 322 and 250 features with good to excellent reproducibility (ICC ≥ 0.75) were included for ML-model development. The best MR- and CT-based ML models satisfactorily distinguished high- from low-grade ccRCCs in internal (MR-ACC = 73% and CT-ACC = 79%) and external (MR-ACC = 74% and CT-ACC = 69%) validation. Compared to single-sequence or single-phase images, the classifiers based on all-sequence MR (71% to 73% in internal and 64% to 74% in external validation) and all-phase CT (77% to 79% in internal and 61% to 69% in external validation) images had significant increases in ACC.

Conclusions

MR- and CT-based ML models are valuable noninvasive techniques for discriminating high- from low-grade ccRCCs, and multiparameter MR- and multiphase CT–based classifiers are potentially superior to those based on single-sequence or single-phase imaging.

Key Points

• Both the MR- and CT-based machine learning models are reliable predictors for differentiating high- from low-grade ccRCCs.

• ML models based on multiparameter MR sequences and multiphase CT images potentially outperform those based on single-sequence or single-phase images in ccRCC grading.

Girgis H, Masui O, White NM et al (2014) Lactate dehydrogenase A is a potential prognostic marker in clear cell renal cell carcinoma. Mol Cancer 13:101CrossRef

Dagher J, Delahunt B, Rioux-Leclercq N et al (2017) Clear cell renal cell carcinoma: validation of World Health Organization/International Society of Urological Pathology grading. Histopathology 71:918–925CrossRef

Delahunt B, Eble JN, Egevad L, Samaratunga H (2019) Grading of renal cell carcinoma. Histopathology 74:4–17CrossRef

Kim H, Inomoto C, Uchida T et al (2018) Verification of the International Society of Urological Pathology recommendations in Japanese patients with clear cell renal cell carcinoma. Int J Oncol 52:1139–1148PubMedPubMedCentral

Halverson SJ, Kunju LP, Bhalla R et al (2013) Accuracy of determining small renal mass management with risk stratified biopsies: confirmation by final pathology. J Urol 189:441–446CrossRef

Haifler M, Kutikov A (2017) Update on renal mass biopsy. Curr Urol Rep 18:28CrossRef

Zhao J, Zhang P, Chen X, Cao W, Ye Z (2016) Lesion size and iodine quantification to distinguish low-grade from high-grade clear cell renal cell carcinoma using dual-energy spectral computed tomography. J Comput Assist Tomogr 40:673–677CrossRef

Parada Villavicencio C, Mc Carthy RJ, Miller FH (2017) Can diffusion-weighted magnetic resonance imaging of clear cell renal carcinoma predict low from high nuclear grade tumors. Abdom Radiol (NY) 42:1241–1249CrossRef

Aslan A, Inan I, Aktan A et al (2018) The utility of ADC measurement techniques for differentiation of low- and high-grade clear cell RCC. Pol J Radiol 83:e446–e451CrossRef

10.

Chen C, Kang Q, Xu B et al (2017) Differentiation of low- and high-grade clear cell renal cell carcinoma: tumor size versus CT perfusion parameters. Clin Imaging 46:14–19CrossRef

11.

Erickson BJ, Korfiatis P, Akkus Z, Kline TL (2017) Machine learning for medical imaging. Radiographics 37:505–515CrossRef

12.

Kocak B, Ates E, Durmaz ES, Ulusan MB, Kilickesmez O (2019) Influence of segmentation margin on machine learning-based high-dimensional quantitative CT texture analysis: a reproducibility study on renal clear cell carcinomas. Eur Radiol. https://doi.org/10.1007/s00330-019-6003-8

13.

Bektas CT, Kocak B, Yardimci AH et al (2019) Clear cell renal cell carcinoma: machine learning-based quantitative computed tomography texture analysis for prediction of Fuhrman nuclear grade. Eur Radiol 29:1153–1163CrossRef

14.

Ding J, Xing Z, Jiang Z et al (2018) CT-based radiomic model predicts high grade of clear cell renal cell carcinoma. Eur J Radiol 103:51–56CrossRef

15.

Akin O, Elnajjar P, Heller M et al (2016) Radiology data from the cancer genome atlas kidney renal clear cell carcinoma [TCGA-KIRC] collection. Cancer Imaging Arch. https://doi.org/10.7937/K9/TCIA.2016.V6PBVTDR

16.

Clark K, Vendt B, Smith K et al (2013) The Cancer Imaging Archive (TCIA): maintaining and operating a public information repository. J Digit Imaging 26:1045–1057CrossRef

17.

Yushkevich PA, Piven J, Hazlett HC et al (2006) User-guided 3D active contour segmentation of anatomical structures: significantly improved efficiency and reliability. Neuroimage 31:1116–1128CrossRef

18.

Koo TK, Li MY (2016) A guideline of selecting and reporting intraclass correlation coefficients for reliability research. J Chiropr Med 15:155–163CrossRef

19.

van Griethuysen JJM, Fedorov A, Parmar C et al (2017) Computational radiomics system to decode the radiographic phenotype. Cancer Res 77:e104–e107CrossRef

20.

Dorogush AV, Gulin A, Gusev G, Kazeev N, Prokhorenkova LO, Vorobev A (2017) Fighting biases with dynamic boosting. arXiv preprint arXiv:170609516

21.

Dorogush AV, Ershov V, Gulin A (2018) CatBoost: gradient boosting with categorical features support. arXiv preprint arXiv:181011363. https://arxiv.org/abs/1810.11363

22.

Hunter JD (2007) Matplotlib: a 2D graphics environment. Comput Sci Eng 9:90. https://doi.org/10.1109/MCSE.2007.55 CrossRef

23.

Silverman SG, Israel GM, Herts BR, Richie JP (2008) Management of the incidental renal mass. Radiology 249:16–31CrossRef

24.

Heilbrun ME, Remer EM, Casalino DD et al (2015) ACR Appropriateness Criteria indeterminate renal mass. J Am Coll Radiol 12:333–341CrossRef

25.

Shu J, Tang Y, Cui J et al (2018) Clear cell renal cell carcinoma: CT-based radiomics features for the prediction of Fuhrman grade. Eur J Radiol 109:8–12CrossRef

26.

Kocak B, Durmaz ES, Ates E, Kaya OK, Kilickesmez O (2019) Unenhanced CT texture analysis of clear cell renal cell carcinomas: a machine learning-based study for predicting histopathologic nuclear grade. AJR Am J Roentgenol. https://doi.org/10.2214/AJR.18.20742

27.

He X, Zhang H, Zhang T, Han F, Song B (2019) Predictive models composed by radiomic features extracted from multi-detector computed tomography images for predicting low- and high- grade clear cell renal cell carcinoma: a STARD-compliant article. Medicine (Baltimore) 98:e13957. https://doi.org/10.1097/MD.0000000000013957 CrossRef

28.

Sun X, Liu L, Xu K et al (2019) Prediction of ISUP grading of clear cell renal cell carcinoma using support vector machine model based on CT images. Medicine (Baltimore) 98:e15022. https://doi.org/10.1097/MD.0000000000015022 CrossRef

29.

Kocak B, Yardimci AH, Bektas CT et al (2018) Textural differences between renal cell carcinoma subtypes: machine learning-based quantitative computed tomography texture analysis with independent external validation. Eur J Radiol 107:149–157CrossRef

30.

Frank I, Blute ML, Cheville JC, Lohse CM, Weaver AL, Zincke H (2002) An outcome prediction model for patients with clear cell renal cell carcinoma treated with radical nephrectomy based on tumor stage, size, grade and necrosis: the SSIGN score. J Urol 168:2395–2400CrossRef

31.

Klatte T, Patard JJ, de Martino M et al (2008) Tumor size does not predict risk of metastatic disease or prognosis of small renal cell carcinomas. J Urol 179:1719–1726CrossRef

32.

Hori J, Kobayashi S, Tamaki G, Azumi M, Kakizaki H (2017) Diagnostic efficacy of percutaneous renal tumor biopsy - concomitant use of frozen section to accurately diagnose renal tumor with necrosis. Gan To Kagaku Ryoho 44:771–774PubMed

33.

Deng Y, Soule E, Samuel A et al (2019) CT texture analysis in the differentiation of major renal cell carcinoma subtypes and correlation with Fuhrman grade. Eur Radiol. https://doi.org/10.1007/s00330-019-06260-2

34.

Marconi L, Dabestani S, Lam TB et al (2016) Systematic review and meta-analysis of diagnostic accuracy of percutaneous renal tumour biopsy. Eur Urol 69:660–673CrossRef

Titel: Predicting the ISUP grade of clear cell renal cell carcinoma with multiparametric MR and multiphase CT radiomics
verfasst von: Enming Cui
Zhuoyong Li
Changyi Ma
Qing Li
Yi Lei
Yong Lan
Juan Yu
Zhipeng Zhou
Ronggang Li
Wansheng Long
Fan Lin
Publikationsdatum: 30.01.2020
Verlag: Springer Berlin Heidelberg
Erschienen in: European Radiology / Ausgabe 5/2020
Print ISSN: 0938-7994
Elektronische ISSN: 1432-1084
DOI: https://doi.org/10.1007/s00330-019-06601-1

Update Radiologie

Bestellen Sie unseren Fach-Newsletter und bleiben Sie gut informiert.

Newsletter bestellen

Springer Medizin

Predicting the ISUP grade of clear cell renal cell carcinoma with multiparametric MR and multiphase CT radiomics