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Abstract

Background

Dual-energy virtual monoenergetic images can increase iodine signal, potentially increasing the conspicuity of hepatic masses.

Purpose

To determine if dual-energy 50-keV virtual monoenergetic images improve visualization of key imaging findings or diagnostic confidence for small (≤2 cm) hepatocellular carcinomas (HCC) at multiphase, contrast-enhanced liver computed tomography (CT).

Material and Methods

Patients with chronic liver disease underwent multiphase dual-energy CT imaging for HCC, with late arterial and delayed phase dual-energy 50-keV images reconstructed. Two non-reader subspecialized gastrointestinal (GI) radiologists established the reference standard, determining the location and diagnosis of all hepatic lesions using predetermined criteria. Three GI radiologists interpreted mixed kV CT images without or with dual-energy 50-keV images. Radiologists identified potential HCCs and rated their confidence (0–100 scales) in imaging findings of arterial enhancement, enhancing capsule, tumor washout, and LI-RADS 5 (2018) category.

Results

In total, 45 patients (14 women; mean age = 59.5 ± 10.9 years) with chronic liver disease were included. Of them, 19 patients had 25 HCCs ≤2 cm (mean size = 1.5 ± 0.4 cm). There were 17 LI-RADS 3 and 4 lesions and 19 benign lesions. Reader confidence in imaging findings of arterial enhancement, enhancing capsule, and non-peripheral washout significantly increased with dual-energy images (P ≤ 0.022). Overall confidence in HCC diagnosis increased significantly with dual-energy 50-keV images (52.4 vs. 68.8; P = 0.001). Dual-energy images demonstrated a slight but significant decrease in overall image quality.

Conclusion

Radiologist confidence in key imaging features of small HCCs and confidence in imaging diagnosis increases with use of dual-energy 50-keV images at multiphase, contrast-enhanced liver CT.

Keywords

X-ray computed tomography radiography dual-energy scanned projection/methods carcinoma hepatocellular/diagnosis liver cirrhosis

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References

Holmes

, 3rd, Fletcher JG, Apel A, et al. Evaluation of non-linear blending in dual-energy computed tomography. Eur J Radiol 2008;68(30):409–413.

Leng

Fletcher

, et al. Maximizing iodine contrast-to-noise ratios in abdominal CT imaging through use of energy domain noise reduction and virtual monoenergetic dual-energy CT. Radiology 2015;276:562–570.

Lin

Chen

, et al. Spectral CT in patients with small HCC: investigation of image quality and diagnostic accuracy. Eur Radiol 2012;22:2117–2124.

Riederer

Mistretta

. Selective iodine imaging using K-edge energies in computerized X-ray tomography. Med Phys 1977;4:474–481.

Leng

McCollough

. Dual-energy CT-based monochromatic imaging. AJR Am J Roentgenol 2012;199(5 Suppl):S9–S15.

Khandelwal

Mileto

Leng

, et al. State-of-the-art dual-energy computed tomography in gastrointestinal and genitourinary imaging. Adv Clin Radiol 2019;1:1–17.

Hanson

Michalak

Childs

, et al. Low kV versus dual-energy virtual monoenergetic CT imaging for proven liver lesions: what are the advantages and trade-offs in conspicuity and image quality? A pilot study. Abdom Radiol (NY) 2018;43(6):1404–1412.

Manjunatha

Rudraswamy

. Study of effective atomic number and electron density for tissues from human organs in the energy range of 1 keV-100 GeV. Health Phys 2013;104:158–162.

Albrecht

Scholtz

J-E

Hüsers

, et al.

Advanced image-based virtual monoenergetic dual-energy CT angiography of the abdomen: optimization of kiloelectron volt settings to improve image contrast

Eur Radiol 2015;26:1863–1870.

10.

Michalak

Grimes

Fletcher

, et al. Selection of optimal tube potential settings for dual-energy CT virtual mono-energetic imaging of iodine in the abdomen. Abdom Radiol (NY) 2017;42(9):2289–2296.

11.

Chernyak

Fowler

Kamaya

, et al. Liver imaging reporting and data system (LI-RADS) version 2018: imaging of hepatocellular carcinoma in At-risk patients. Radiology 2018;289:816–830.

12.

Boning

Feldhaus

Adelt

, et al. Clinical routine use of virtual monochromatic datasets based on spectral CT in patients with hypervascularized abdominal tumors - evaluation of effectiveness and efficiency. Acta Radiol 2019;60:425–432.

13.

Kaltenbach

Wichmann

Pfeifer

, et al. Iodine quantification to distinguish hepatic neuroendocrine tumor metastasis from hepatocellular carcinoma at dual-source dual-energy liver CT. Eur J Radiol 2018;105:20–24.

14.

Zhou

Liu

, et al.

Can virtual monochromatic images from dual-energy CT replace low-kVp images for abdominal contrast-enhanced CT in small- and medium-sized patients?

Eur Radiol 2019;29:2878–2889.

15.

Matsuda

Tsuda

Kido

, et al. Dual-energy computed tomography in patients with small hepatocellular carcinoma: utility of noise-reduced monoenergetic images for the evaluation of washout and image quality in the equilibrium phase. J Comput Assist Tomogr 2018;42:937–943.

16.

Yang

Zhang

Jia

, et al. Dual energy spectral CT imaging for the evaluation of small hepatocellular carcinoma microvascular invasion. Eur J Radiol 2017;95:222–227.

17.

De Cecco

Boll

Bolus

, et al. White paper of the society of computed body tomography and magnetic resonance on dual-energy CT, part 4: abdominal and pelvic applications. J Comput Assist Tomogr 2017;41:8–14.

18.

Patel

Alexander

Allen

, et al. Dual-energy CT workflow: multi-institutional consensus on standardization of abdominopelvic MDCT protocols. Abdom Radiol (NY) 2017;42:676–687.

19.

Fletcher

Fidler

Venkatesh

, et al. Observer performance with varying radiation dose and reconstruction methods for detection of hepatic metastases. Radiology 2018;289(2):455–464.

20.

Di Martino

De Filippis

De Santis

, et al. Hepatocellular carcinoma in cirrhotic patients: prospective comparison of US, CT and MR imaging. Eur Radiol 2013;23:887–896.

21.

Kim

Lee

Kim

, et al. Image fusion in dual energy computed tomography for detection of hypervascular liver hepatocellular carcinoma: phantom and preliminary studies. Invest Radiol 2010;45:149–157.

22.

American College of Radiology. CT/MRI LI-RADS (v2018). Available at: https://www.acr.org/Clinical-Resources/Reporting-and-Data-Systems/LI-RADS/CT-MRI-LI-RADS-v2018 (accessed 20 February 2020).

23.

Froemming

Kawashima

Takahashi

, et al. Individualized kV selection and tube current reduction in excretory phase computed tomography urography: potential for radiation dose reduction and the contribution of iterative reconstruction to image quality. J Comput Assist Tomogr 2013;37(4):551–559.

24.

Directorate-General for Research and Innovation (European Commission). European guidelines on quality criteria for computed tomography (2000). Available at: https://op.europa.eu/en/publication-detail/-/publication/d229c9e1-a967-49de-b169-59ee68605f1a (accessed 30 June 2021).

25.

Brehmer

Brismar

Morsbach

, et al. Triple arterial phase CT of the liver with radiation dose equivalent to that of single arterial phase CT: initial experience. Radiology 2018;289:111–118.

26.

Yoon

Chang

Lee

, et al. Double low-dose dual-energy liver CT in patients at high-risk of HCC: a prospective, randomized, single-center study. Invest Radiol 2020;55:340–348.

27.

Addley

Griffin

Shaw

, et al. Accuracy of hepatocellular carcinoma detection on multidetector CT in a transplant liver population with explant liver correlation. Clin Radiol 2011;66:349–356.

28.

Rhee

Han

, et al. Added value of smooth hypointense rim in the hepatobiliary phase of gadoxetic acid-enhanced MRI in identifying tumour capsule and diagnosing hepatocellular carcinoma. Eur Radiol 2017;27:2610–2618.

29.

Kim

Choi

, et al. Detection of recurrent hepatocellular carcinoma on post-operative surveillance: comparison of MDCT and gadoxetic acid-enhanced MRI. Abdom Imaging 2014;39:291–299.

30.

Colli

Fraquelli

Casazza

, et al. Accuracy of ultrasonography, spiral CT, magnetic resonance, and alpha-fetoprotein in diagnosing hepatocellular carcinoma: a systematic review. Am J Gastroenterol 2006;101:513–523.

31.

Hennedige

Yang

Ong

, et al. Utility of non-contrast-enhanced CT for improved detection of arterial phase hyperenhancement in hepatocellular carcinoma. Abdom Imaging 2014;39:1247–1254.

32.

Shuman

Green

Busey

, et al. Dual-energy liver CT: effect of monochromatic imaging on lesion detection, conspicuity, and contrast-to-noise ratio of hypervascular lesions on late arterial phase. AJR Am J Roentgenol 2014;203:601–606.

33.

Laroia

Bhadoria

Venigalla

, et al. Role of dual energy spectral computed tomography in characterization of hepatocellular carcinoma: initial experience from a tertiary liver care institute. Eur J Radiol Open 2016;3:162–171.

34.

De Cecco

Caruso

Schoepf

, et al. Optimization of window settings for virtual monoenergetic imaging in dual-energy CT of the liver: a multi-reader evaluation of standard monoenergetic and advanced imaged-based monoenergetic datasets. Eur J Radiol 2016;85:695–699.

35.

Mileto

Nelson

Samei

, et al. Dual-energy MDCT in hypervascular liver tumors: effect of body size on selection of the optimal monochromatic energy level. AJR Am J Roentgenol 2014;203:1257–1264.

36.

Euler

Obmann

Szucs-Farkas

, et al. Comparison of image quality and radiation dose between split-filter dual-energy images and single-energy images in single-source abdominal CT. Eur Radiol 2018;28:3405–3412.

37.

Purysko

Primak

Baker

, et al. Comparison of radiation dose and image quality from single-energy and dual-energy CT examinations in the same patients screened for hepatocellular carcinoma. Clin Radiol 2014;69:e538–e544.

38.

Pfeiffer

Parakh

Patino

, et al. Iodine material density images in dual-energy CT: quantification of contrast uptake and washout in HCC. Abdom Radiol (NY) 2018;43:3317–3323.

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Impact of dual-energy 50-keV virtual monoenergetic images on radiologist confidence in detection of key imaging findings of small hepatocellular carcinomas using multiphase liver CT

Abstract

Background

Purpose

Material and Methods

Results

Conclusion

Keywords

Get full access to this article

References

Supplementary Material