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Abstract

Background

Automatic segmentation has recently been developed to yield objective data. Prediction of microvascular invasion (MVI) of hepatocellular carcinoma (HCC) using radiomics has been reported.

Purpose

To develop a deep learning-based auto-segmentation algorithm (DL-AS) for the detection of HCC and to predict MVI using computed tomography (CT) texture analysis.

Material and Methods

We retrospectively collected training data from 249 patients with HCC and validation set from 35 patients. Lesions of the training set were manually drawn by radiologist, in the delayed phase. 2D U-Net was selected as the DL architecture. Using the validation set, one radiologist manually drew 2D and 3D regions of interest twice, and the developed DL-AS was performed twice with a one-month time interval. The reproducibility was calculated using intraclass correlation coefficients (ICC). Logistic regression was performed to predict MVI.

Results

ICC was in the range of 0.190–0.998/0.341–0.997 in the manual 3D/2D segmentation. In contrast, it was perfect in 3D/2D using DL-AS, with a success rate of 88.6% for the detection of HCC. For predicting MVI, sphericity was a significant parameter (odds ratio <0.001; 95% confidence interval <0.001–0.206; P = 0.020) for predicting MVI using 2D DL-AS. However, 3D DL-AS segmentation did not yield a predictive parameter.

Conclusion

The auto-segmentation of HCC using DL-AS provides perfect reproducibility, although it failed to detect 11.4% (4/35). However, the extracted parameters yielded different important predictors of MVI in HCC. Sphericity was a significant predictor in 2D DL-AS and 3D manual segmentation, while discrete compactness was a significant predictor in 2D manual segmentation.

Keywords

Liver hepatocellular carcinoma computed tomography deep learning

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References

Wakabayashi

Ouhmich

Gonzalez-Cabrera

, et al. Radiomics in hepatocellular carcinoma: a quantitative review. Hepatol Int 2019;13:546–559.

Parmar

Rios Velazquez

Leijenaar

, et al. Robust radiomics feature quantification using semiautomatic volumetric segmentation. PLoS One 2014;9:e102107.

Varghese

Cen

Hwang

, et al. Texture analysis of imaging: what radiologists need to know. AJR Am J Roentgenol 2019;212:520–528.

Sun

Guo

Zhang

, et al. Automatic segmentation of liver tumors from multiphase contrast-enhanced CT images based on FCNs. Artif Intell Med 2017;83:58–66.

Chlebus

Schenk

Moltz

, et al. Automatic liver tumor segmentation in CT with fully convolutional neural networks and object-based postprocessing. Sci Rep 2018;8:1–7.

Vorontsov

Cerny

Régnier

, et al. Deep learning for automated segmentation of liver lesions at CT in patients with colorectal cancer liver metastases. Radiol Artif Intell 2019;1:180014.

Choy

Khalilzadeh

Michalski

, et al. Current applications and future impact of machine learning in radiology. Radiol 2018;288:318–328.

Weston

Korfiatis

Kline

, et al. Automated abdominal segmentation of CT scans for body composition analysis using deep learning. Radiol 2019;290:669–679.

Wang

Qiu

Thai

, et al. A two-step convolutional neural network based computer-aided detection scheme for automatically segmenting adipose tissue volume depicting on CT images. Comput Methods Programs Biomed 2017;144:97–104.

10.

Sumie

Kuromatsu

Okuda

, et al. Microvascular invasion in patients with hepatocellular carcinoma and its predictable clinicopathological factors. Ann Surg Oncol 2008;15:1375–1382.

11.

Cucchetti

Piscaglia

Caturelli

, et al. Comparison of recurrence of hepatocellular carcinoma after resection in patients with cirrhosis to its occurrence in a surveilled cirrhotic population. Ann Surg Oncol 2009;16:413–422.

12.

Ahn

Lee

Joo

, et al. Prediction of microvascular invasion of hepatocellular carcinoma using gadoxetic acid-enhanced MR and 18 F-FDG PET/CT. Abdom Imaging 2015;40:843–851.

13.

Kim

Park

Y-N

, et al. Single hepatocellular carcinoma: preoperative MR imaging to predict early recurrence after curative resection. Radiol 2015;276:433–443.

14.

Ariizumi

S-i

Kitagawa

Kotera

, et al. A non-smooth tumor margin in the hepatobiliary phase of gadoxetic acid disodium (Gd-EOB-DTPA)-enhanced magnetic resonance imaging predicts microscopic portal vein invasion, intrahepatic metastasis, and early recurrence after hepatectomy in patients with hepatocellular carcinoma. J Hepatobiliary Pancreat Sci 2011;18:575–585.

15.

Ahn SJ, Kim JH, Park SJ, et al. Hepatocellular carcinoma: preoperative gadoxetic acid-enhanced MR imaging can predict early recurrence after curative resection using image features and texture analysis. Abdom Radiol (NY) 2019;44:539--548.

16.

Zhu

H-B

Zheng

Z-Y

Zhao

, et al. Radiomics-based nomogram using CT imaging for noninvasive preoperative prediction of early recurrence in patients with hepatocellular carcinoma. Diagn Interv Radiol 2020;26:411.

17.

Chen

Zhu

Liu

, et al. Texture analysis of baseline multiphasic hepatic computed tomography images for the prognosis of single hepatocellular carcinoma after hepatectomy: a retrospective pilot study. Eur J Radiol 2017;90:198–204.

18.

Zhang Z, Jiang H, Chen J, et al. Hepatocellular carcinoma: radiomics nomogram on gadoxetic acid-enhanced MR imaging for early postoperative recurrence prediction. Cancer Imaging 2019;19:1–10.

19.

Cicchetti

. Guidelines, criteria, and rules of thumb for evaluating normed and standardized assessment instruments in psychology. Psychol Assess 1994;6:284.

20.

Gillies

Kinahan

Hricak

. Radiomics: images are more than pictures, they are data. Radiol 2016;278:563–577.

21.

van Timmeren

Leijenaar

van Elmpt

, et al.

Test–retest data for radiomics feature stability analysis: generalizable or study-specific?

Tomography 2016;2:361–365.

22.

Häme

Pollari

. Semi-automatic liver tumor segmentation with hidden Markov measure field model and non-parametric distribution estimation. Med Image Anal 2012;16:140–149.

23.

Park

Kim

, et al. Reproducibility and generalizability in radiomics modeling: possible strategies in radiologic and statistical perspectives. Korean J Radiol 2019;20:1124–1137.

24.

Heimann

Van Ginneken

Styner

, et al. Comparison and evaluation of methods for liver segmentation from CT datasets. IEEE Trans Med Imaging 2009;28:1251–1265.

25.

Savadjiev

Chong

Dohan

, et al. Demystification of AI-driven medical image interpretation: past, present and future. Eur Radiol 2019;29:1616–1624.

26.

Van Griethuysen

Fedorov

Parmar

, et al. Computational radiomics system to decode the radiographic phenotype. Cancer Res 2017;77:e104–e107.

27.

Bribiesca

. An easy measure of compactness for 2D and 3D shapes. Pattern Recognit 2008;41:543–554.

28.

Renzulli

Brocchi

Cucchetti

, et al.

Can current preoperative imaging be used to detect microvascular invasion of hepatocellular carcinoma?

Radiol 2016;279:432–442.

29.

Lee

Kim

Lee

, et al. Preoperative gadoxetic acid–enhanced MRI for predicting microvascular invasion in patients with single hepatocellular carcinoma. J Hepatol 2017;67:526–534.

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Development of a deep learning-based auto-segmentation algorithm for hepatocellular carcinoma (HCC) and application to predict microvascular invasion of HCC using CT texture analysis: preliminary results