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DOI: 10.1055/s-0043-1774305
CT MRI LI-RADS in Routine Practice
- Abstract
- Introduction
- LI-RADS Diagnostic Population
- LI-RADS Technical Consideration for CT and MRI
- Term Observation in LI-RADS
- LI-RADS Diagnostic Categories
- Major Imaging Features of LI-RADS on CT and MRI
- Ancillary Imaging Features of LI-RADS on CT and MRI
- Tie-Breaking Rule of LI-RADS on CT and MRI
- Final Check
- Summary
- References
Abstract
Primary liver cancer is the third most common cause of cancer-related deaths worldwide with hepatocellular carcinoma (HCC) comprising the vast majority of the cases. HCC unlike most solid cancers can be diagnosed based on imaging findings alone using multiphasic contrast-enhanced computed tomography (CT) or magnetic resonance imaging (MRI) without the need for histopathological confirmation in the majority of the cases. Liver Imaging Reporting and Data System (LI-RADS) was first introduced by the American College of Radiology in 2011 with the help of a multidisciplinary team of liver disease experts to improve the accuracy, consistency, and clarity of communication of imaging findings between radiologists and treating physicians. To date, LI-RADS has undergone four major updates in 2013, 2014, 2017, and 2018. This article reviews the technical aspects, categorization, and major and ancillary imaging features for the application of LI-RADS version 2018 using CT and MRI in routine clinical practice.
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Introduction
Liver disease is leading cause of mortality and morbidity across the world accounting for 2.14 million deaths in 2017 with a substantial increase of 11.4% since 2012. Cirrhosis and hepatocellular carcinoma (HCC) are the major factors responsible for deaths due to liver disease.[1] As per World Health Organization, liver cancer is third most common cause of cancer related deaths worldwide in 2020 out of which 90% cases are due to HCC.[2] HCC unlike most of the solid cancers can be diagnosed based on imaging findings alone using multiphasic contrast-enhanced computed tomography (CT) or magnetic resonance imaging (MRI) without need for histopathological confirmation in majority of the cases. Several classification systems such as American Association for the Study of Liver Diseases (AASLD), European Association for the Study of the Liver, and Asian Pacific Association for the Study of the Liver have been used in HCC management with key differences based on regional practice guidelines.[3] Presence of multiple classification systems limits the standardization, interpretation, and research due to lack of unification and consistency. Liver Imaging Reporting and Data System (LI-RADS) was first introduced by American College of Radiology in 2011 with the help of multidisciplinary team of liver disease experts to improve the accuracy, consistency, and clarity of communication of imaging findings between radiologist and treating physicians. Since its inception, LI-RADS is an evolving system with increasing global acceptance for providing standardized terminology, technique, interpretation, and reporting of liver imaging allowing higher accuracy and effective communication. Till date, LI-RADS has undergone four major updates in 2013, 2014, 2017, and 2018.[4] The 2018 update is considered as a major milestone in LI-RADS evolution as AASLD incorporated LI-RADS in its practice guidelines highlighting the key role of radiologist in HCC management.[5] This incorporation required modification of LR-5 category to include all 10-to19-mm observations with nonrim arterial phase hyperenhancement (APHE) and washout appearance. Requirement of qualifier -us and -g was removed from the LR-5 category. Threshold growth definition was matched to Organ Procurement and Transplantation Network: more than or equal to 50% increase in the lesion size in less than 6 months.
US-LIRADS provides algorithm for screening and surveillance in high-risk patients. Contrast-enhanced ultrasound (CEUS) is robust technique and offers comparable accuracy to CT and MRI in assessment of focal liver lesions. CEUS offers higher safety than contrast CT/MRI in patients with nephrotoxicity, contrast allergies, and pediatric age group. CEUS can be complimentary to CT/MRI in indeterminate cases.[6] CEUS LI-RADS algorithm has been used for diagnosis of HCC in at risk population. Detailed discussion of US LI-RADS and CEUS LI-RADS is beyond the scope of this article and interested readers are requested to visit ACR Web site for further details. This article will mainly focus on the CT/MRI LI-RADS and treatment response LI-RADS.
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LI-RADS Diagnostic Population
LI-RDAS aims to achieve higher specificity in diagnosing HCC; hence, it is currently applied only to certain subset of patients having higher pretext probability of developing HCC. Inclusion and exclusion criteria for eligibility for LI-RADS have been detailed in [Table 1].[7] The major limitation of evaluating focal lesions in cirrhosis secondary to vascular disorders is the presence of benign arterialized nodules that can mimic HCC leading to reduced specificity; hence, LI-RADS is not used in these cases. LI-RADS is still not validated for use in the pediatric population; hence, patients under 18 years old are excluded from the diagnostic algorithm. Diagnostic accuracy of LI-RADS in noncirrhotic HCC is not completely established in current literature.
Abbreviations: HCC, hepatocellular carcinoma; LI-RADS, Liver Imaging Reporting and Data System.
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LI-RADS Technical Consideration for CT and MRI
Standardized hepatic imaging protocols are required to yield good quality images providing consistent accuracy and reproducibility. Multiphasic CT and MRI using intravenous contrast form cornerstone of imaging evaluation. MRI is more sensitive than CT in detection of smaller lesions (< 1 cm), assessment of arterial phase enhancement and enhancing capsule due to higher inherent soft tissue resolution. Currently LI-RADS guidelines do not recommend use of MRI over CT.[8] Contrast used in liver MRI imaging is usually of two broad categories—hepatobiliary-specific agents or extracellular agents (nonspecific). Hepatobiliary-specific contrast used in current practice is gadobenate (also known as gadobenate dimeglumine or Gd-BOPTA) and gadoxetate (also known as gadoxetic acid or Gd-EOB-DTPA), out of which gadoxetate is not available in India.
The LI-RADS Technique Working Group presents imaging protocol and hardware specifications for CT and MRI based as detailed in [Table 2].[9] Recommended postcontrast phases in CT and MRI when using extracellular contrast agent or gadobenate dimeglumine are late arterial, portal venous, and delayed phase acquisitions ([Figs. 1] and [2]). Late arterial phase shows enhancement of hepatic artery along with early enhancement of portal vein (homogenous/heterogenous) without antegrade enhancement of hepatic veins. Late arterial phase is strongly recommended as it offers optimal enhancement of hypervascular lesions in form of APHE that is a major diagnostic feature of HCC. Early AP is equivalent to the angiographic phase and shows no or less enhancement of the portal vein than the liver. Portal venous phase (PVP) is characterized by enhancement of portal vein and hepatic veins more than the background liver and corresponds to peak parenchymal enhancement. Delayed phase can be differentiated due to lower degree enhancement of liver and intrahepatic vessels as compared with PVP. If postcontrast imaging is done using fixed delay technique, the suggested timings for acquisition after start of injection are 30 to 45 seconds for late arterial phase, 60 to 75 seconds for PVP, and 2 to 5 minutes for delayed phase.[10] Portal venous and delayed phase imaging is required for the evaluation of washout and capsule appearance characteristic of HCC as well as vascular thrombosis. In cases of gadoxetate injection, the phase acquired after 2 to 5 minutes is termed as transitional phase instead of delayed phase. Transitional phase hypointensity is useful ancillary imaging features favoring malignancy.
Abbreviations: CT, computed tomography; DP, delayed phase; ECA, extracellular contrast-enhanced; IP, in-phase; LI-RADS, Liver Imaging Reporting and Data System; MRI, magnetic resonance imaging; OP, out-of-phase; PVP, portal venous phase.




Hepatobiliary phase (HBP) is postcontrast phase acquired after injection of hepatobiliary contrast (gadoxetate or gadobenate) and is identified by hepatic parenchyma appearing hyperintense compared with hepatic vasculature. The HBP is typically acquired approximately 20 minutes after injection of gadoxetate and 1 to 3 hours after injection of gadobenate. HBP isointensity and hypointensity are used as ancillary features for favoring benignity and malignancy (not specific for HCC), respectively. Hepatobiliary contrast agents are helpful in the diagnosis of small (<2 cm in size) HCC and early HCC (without showing arterial enhancement or washout).[11]
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Term Observation in LI-RADS
Observation is a generic term used in LI-RADS to denote any focal area appearing distinct from the background liver parenchyma. Term observation is preferred over lesion or nodule as it allows incorporation of true lesions as well as pseudolesions in the liver. Pseudolesions are non-pathological conditions and are likely to represent perfusion alterations, artifacts, and hypertrophic pseudomass. True lesions can be of HC or non-HC origin and range from benign to neoplastic and from premalignant to malignant spectrum.
The stepwise approach to diagnosis of nontreated observation is listed in [Table 3].
Abbreviations: CT, computed tomography; LI-RADS, Liver Imaging Reporting and Data System; MRI, magnetic resonance imaging.
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LI-RADS Diagnostic Categories
Focal lesion in cirrhotic liver can vary in spectrum from benign nature to malignancy (HC or non-HC). To address the broad-spectrum nature of the untreated lesions, LI-RADS gives eight categories including LR-NC (noncharacterizable), LR-1 (definitely benign), LR-2 (probably benign), LR-3 (intermediate probability of malignancy), LR-4 (probably HCC), LR-5 (definitely HCC), LR-M (probably or definitely malignant not HCC specific), and LR-TIV (malignancy with tumor in vein) as detailed in [Table 4].[12] Readers should remember that LI-RADS categories do not correspond exactly to histologic categories, instead reflect probability of benignity, HCC, non-HCC malignancy, and TIV.
Abbreviations: APHE, arterial phase hyperenhancement; CT, computed tomography; HBP, hepatobiliary phase; HCC, hepatocellular carcinoma; LI-RADS, Liver Imaging Reporting and Data System; MRI, magnetic resonance imaging; TIV, tumor in vein; TP, transitional phase.
Additional major features include nonperipheral washout, enhancing capsule, and threshold growth.
LR-NC category should be reserved if quality and completeness of dynamic post-contrast study do not allow assessment of one or major imaging features. These patients should be assessed via repeat or alternative diagnostic imaging in less than or equal to 3 months.
Categories LR-1 and LR-2 are on the benign spectrum of the LI-RADS scale with LR-1 being 100% benign and LR-2 being probably benign ([Fig. 2]). LI-RADS does not strictly define the imaging criteria of benign lesions and instead leaves it to radiologists' understanding of common benign entities. Category LR-1 incorporates benign, non-HC lesions, and pseudolesions. The majority of LR-2 lesions are benign with exception of dysplastic or malignant lesions that can contribute up to 14% cases. The cirrhotic liver can show many benign entities that can be due to underlying cirrhosis (e.g., regenerative nodules, vascular shunts, confluent fibrosis) or be incidental non-HC lesions (e.g., cysts, hemangiomas). Examples of LR-1 and LR-2 lesions are detailed in [Table 5].[13] In general, MRI allows better characterization of lesions as LR-1 and LR-2 as compared with CT. Patients with LR-1 and LR-2 lesions undergo routine surveillance at 6 months interval.
Abbreviation: HCC, hepatocellular carcinoma.
Lists above are not meant to be exhaustive.
LR-3 category represents indeterminate lesions that can range from benign to dysplastic nodules to HCCs ([Fig. 2]). The hypervascular pseudolesion is considered to be most common cause of LR-3 observation.[14] Up to 11% observations from LR-3 category can evolve into LR-5 or uncommonly to LR-M by 12 months. LR-3 lesions should be reassessed with routine or alternative diagnostic imaging in 3 to 6 months.
LR-4 category incorporates lesions with high but not 100% probability of HCC ([Fig. 3]). LR-4 does not exclude non-HCC malignancy. LR-4 lesions require multidisciplinary discussion for tailored workup that may include biopsy.


LR-5 category aims at achieving the highest specificity and positive predictive value for the diagnosis of HCC using stringent imaging criteria with combination of major imaging features. Majority of the LR-5 lesions is progressed HCCs ([Fig. 4]). It should be remembered that not all HCCs meet the stringent criteria of LR-5 and are considered atypical HCCs. LR-5 lesions require multidisciplinary discussion for consensus management.


Though the HCC is the commonest malignancy (∼90%) in cirrhotic liver, other non-HCC malignancies (∼10%) like intrahepatic cholangiocarcinoma (iCCA), combined hepatocellular cholangiocarcinoma (HCC-CCA), hepatic metastasis, and lymphoma are also seen in these patients. Category LR-M incorporates all those lesions that have high probability of malignancy not specific to HCC. LR-M category allows maintaining specificity of diagnosis of HCC without losing sensitivity for diagnosis of non-HCC malignancies. Targetoid morphology ([Fig. 5]) on dynamic post-contrast imaging, diffusion-weighted imaging (DWI) or HBP imaging is characteristic of iCCA and combined HCC-CCA.[15] The presence of peripheral vascularity surrounding the central fibrotic core forms the histological basis for targetoid imaging morphology. Targetoid morphology can also be seen in atypical HCC hence LR-M also includes HCC ([Fig. 5]). Up to 50% of LR-M lesions turn out to be atypical HCCs on histopathology. Unlike many other LI-RADS categories, LR-M does not have a set size criterion. It should be remembered that differentiation of LR-M into HCC and non-HCC malignancies has a bearing on prognostication and treatment planning. iCCA shows an early tendency for extrahepatic metastasis; hence, these patients are not considered transplant candidates in United States due to high-risk recurrence after transplant. LR-M lesions require multidisciplinary discussion for consensus management including biopsy.


LR-TIV denotes 100% certainty for malignancy with a tumor in vein in presence of definite enhancing soft tissue in vein, regardless of visualization of parenchymal mass ([Fig. 6]). Previous versions of LI-RADS used category LR-5V to denote venous thrombosis due to HCC that had certain limitations. As TIV is not always caused by HCC, LR-TIV category offers broader spectrum allowing tumoral thrombosis from malignant lesions beyond HCC like iCCA or combined HCC-CCA as well as those cases where no distinct parenchymal lesion is visualized. Features that are suggestive but not definite for a TIV include occluded vein with ill-defined walls, occluded vein with restricted diffusion, occluded or obscured vein contiguous with malignant parenchymal mass, and heterogeneous vein enhancement not attributable to the artifact.[16] Depending on the underlying primary lesion, radiologist should report LR-TIV as TIV due to LR-4/5 lesion or LR-M lesion. LR-TIV lesions require multidisciplinary discussion for consensus management including biopsy.


In general, pathologically proven lesions are not assigned the LI-RADS category to avoid confusion in communication, except for benign or premalignant HC lesions like regenerative or dysplastic nodules.
The diagnostic approach to nontreated observation is detailed Algorithm 1 and CT/MRI diagnostic table ([Table 6]).
Abbreviations: APHE, arterial phase hyperenhancement; CT, computed tomography; MRI, magnetic resonance imaging.
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Major Imaging Features of LI-RADS on CT and MRI
LI-RADS uses five major imaging features of HCC for assigning categories from LR-3 to LR-5 ([Figs. 2] [3] [4]) as detailed in the later part article. These features include nonrim APHE, nonperipheral washout, observation size, threshold growth, and enhancing capsule ([Table 7]).[17]
Abbreviations: APHE, arterial phase hyperenhancement; CT, computed tomography; DP, delayed phase; HBP, hepatobiliary phase; LI-RADS, Liver Imaging Reporting and Data System; MRI, magnetic resonance imaging; PVP, portal venous phase; TP, transitional phase.
APHE is due to neoangiogenesis in the progressed HCC leading to increase in the hepatic arterial blood flow. APHE can be of rim and nonrim subtypes. Nonrim APHE is major features of HCC, while rim APHE is LR-M feature. Nonrim APHE is defined as nonrim-like enhancement of lesion (in whole or in part) in arterial phase unequivocally more than the liver. It reflects angiogenesis within the lesion. Late arterial phase is preferred as it allows optimal assessment of APHE. Early HCC may not show APHE and can appear iso or hypoenhancing due to insufficient arterialization and decreased portal flow.[18]
Nonperipheral “washout” is defined as nonperipheral reduction in the enhancement of observation from earlier to later phase resulting in hypoenhancement relative to the liver. For extracellular contrast agents and gadobenate, hypoenhancement in PVP, delayed phase (DP), or both are indicative of washout. For gadoxetate, washout is defined only on PVP and not on transitional phase as apparent hypointensity on transitional phase may be due to relative hyperenhancement of the liver parenchyma rather than a true lesional washout.[19] Nonperipheral washout may be homogeneous or heterogeneous; if heterogeneous, it may be focal, scattered (patchy, spotty), nodule-in-nodule, or mosaic. Different mechanisms contributing to washout appearance include reduction in portal venous flow, early venous drainage, tumoral high cellularity, and expanded extracellular space of the surrounding fibrotic liver.[20] Visual qualitative assessment of lesion enhancement relative to the liver is usually enough and does not require quantitative measurements. Lesions that lack enhancement do not qualify for washout assessment. Fade should not be interchangeably used with washout as it represents reduction in the enhancement of observation relative to the liver from hyperenhancement in an earlier phase to isoenhancement or minimal hyperenhancement in all later phases.
Enhancing “capsule” is defined as enhancing smooth, uniform, sharp border around most or all of observation, which is either thicker or more conspicuous than fibrotic tissue associated with chronic liver disease. It is assessed PVP, DP, or transitional phase but not on arterial phase. Imaging appearance of capsule can be due to true capsule or pseudocapsule. Histologically, true fibrous capsule is a feature of progressed HCC and is not seen in early HCC, dysplastic nodules, or regenerative nodules. Some of HCCs do not have a true fibrous capsule and instead are surrounded by prominent histopathological hepatic sinusoids and/or peritumoral fibrosis that is termed as pseudocapsule. Imaging alone cannot differentiate between a true capsule and pseudocapsule of HCC.[21]
Size is measured as the largest outer-edge-to-outer-edge dimension of observation. Enhancing capsule should be included in final size of the lesion. Size measurements should be avoided in the arterial phase (pitfall from perilesional enhancement) and DWI sequence (pitfall from distortion) particularly if lesion margins are well visible in the rest of the sequences. Arterial phase measurement can be erroneous due to presence of perilesional enhancement. DWI is prone for distortion; hence, measurement can be unreliable. Current LI-RADS algorithm allows assessment of observations below 10 mm as well as above 10 mm in size.
Interval in size of lesion is usually feature of malignancy and is not specific for HCC.
An increase in size of a mass by more than or equal to 50% in less than 6 months is termed as threshold growth. Subthreshold growth is termed as size increase in a mass less than threshold growth.
Subthreshold growth can be any of one the following: size increase of less than 50% over any period, or any size increase over a time interval more than 6 months, or a new mass of any size. Change in size of lesion due to intralesional hemorrhage or due to error in measurement owing to technical differences does not qualify for growth. Comparison with previous CT/MRI but not US or CEUS is allowed for the assessment of growth. Measurement of the lesion should be done on the same phase, sequence, and plane on serial exams if possible.
In isolation, major imaging features are not specific for HCC but combination of these features provides higher specificity as shown in categories LR-3 to LR-5. If a radiologist is unsure about the presence of any major imaging feature, then that feature is considered as absent.
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Ancillary Imaging Features of LI-RADS on CT and MRI
Ancillary features are helpful in improving detection and diagnostic confidence of radiologist. Unlike major features, the ancillary features are optional and can be used at the radiologist's discretion. Ancillary imaging features can be grouped under three broad groups favoring malignancy in general, favoring HCC in particular, or benignity as enlisted in [Table 8].[12] The presence of one or more ancillary feature of benignity allows downgradation of a lesion by 1 category from higher category. The presence of one or more ancillary feature of malignancy allows upgradation of lesions by 1 category from lower category up to LR-4. LI-RADS does not allow use of any ancillary feature to upgrade lesion from LR-4 to LR-5 category due to lack of their specificity for diagnosing HCC. If any lesion exhibits ambiguous ancillary features favoring both malignancy and benignity, then a change in category is not allowed. The absence of ancillary features should not be used to upgrade or downgrade a category. If a radiologist is unsure about the presence of any ancillary imaging feature, then that feature is considered as absent.[22] Key aspect of ancillary imaging features are detailed in [Tables 9], [10], and [11].
Abbreviations: CT, computed tomography; HCC, hepatocellular carcinoma; LI-RADS, Liver Imaging Reporting and Data System; MRI, magnetic resonance imaging; US, ultrasound.
Abbreviations: CT, computed tomography; DWI, diffusion-weighted imaging; HCC, hepatocellular carcinoma; LI-RADS, Liver Imaging Reporting and Data System; MRI, magnetic resonance imaging; T1WI, T1-weighted imaging.
Abbreviations: CT, computed tomography; LI-RADS, Liver Imaging Reporting and Data System; MRI, magnetic resonance imaging; T2WI, T2-weighted imaging.
Abbreviations: APHE, arterial phase hyperenhancement; CT, computed tomography; LI-RADS, Liver Imaging Reporting and Data System; MRI, magnetic resonance imaging; TIV, tumor in vein.
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Tie-Breaking Rule of LI-RADS on CT and MRI
If radiologist is unsure to select between the two categories, then choose the one reflecting lower certainty. In case of doubtful benign lesions, choose a higher category like LR-2/LR-3. In case of doubtful malignant lesions, choose a lower category like LR-3/ LR-4 to maintain specificity. If unsure about the presence of TIV, then avoid the LR-TIV category.
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Final Check
Scrutiny of all the imaging findings is necessary to allot the final category of any observation. All the nodules need similar optimal assessment for appropriate management recommendations.
Key points in the structured reporting of nontreated observation using CT/MRI LI-RADS are detailed in [Table 11].
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Summary
LI-RADS provides unified approach for categorization of liver imaging findings in at-risk patients using standardized lexicon, technique, management, and reporting guidelines. 2018 version of LI-RADS achieved integration with AASLD 2018 HCC clinical practice guidance by adopting the criteria for small (10–19 mm) LR-5 observations and simplifying the definition for threshold growth. In authors experience, knowledge of key concepts of LI-RADS diminishes the errors in reporting, reduces interobserver variability, facilitates communication between radiologists and other clinicians. Details of post-treatment LI-RADS are beyond scope of this article and hence not discussed.


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Conflict of Interest
None declared.
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References
- 1 Paik JM, Golabi P, Younossi Y, Mishra A, Younossi ZM. Changes in the global burden of chronic liver diseases from 2012 to 2017: the growing impact of NAFLD. Hepatology 2020; 72 (05) 1605-1616
- 2 Ferlay J, Ervik M, Lam F. et al. Global Cancer Observatory: Cancer Today. Lyon: International Agency for Research on Cancer; 2020
- 3 Rosiak G, Podgorska J, Rosiak E, Cieszanowski A. Comparison of LI-RADS v.2017 and ESGAR guidelines imaging criteria in HCC diagnosis using MRI with hepatobiliary contrast agents. BioMed Res Int 2018; 2018: 7465126
- 4 Marks RM, Masch WR, Chernyak V. LI-RADS: past, present, and future, from the AJR special series on radiology reporting and data systems. AJR Am J Roentgenol 2021; 216 (02) 295-304
- 5 Marrero JA, Kulik LM, Sirlin CB. et al. Diagnosis, staging, and management of hepatocellular carcinoma: 2018 practice guidance by the American Association for the Study of Liver Diseases. Hepatology 2018; 68 (02) 723-750
- 6 Schwarze V, Marschner C, Völckers W. et al. Diagnostic value of contrast-enhanced ultrasound versus computed tomography for hepatocellular carcinoma: a retrospective, single-center evaluation of 234 patients. J Int Med Res 2020; 48 (06) 300060520930151
- 7 Chernyak V, Fowler KJ, Kamaya A. et al. Liver Imaging Reporting and Data System (LI-RADS) version 2018: imaging of hepatocellular carcinoma in at-risk patients. Radiology 2018; 289 (03) 816-830
- 8 Corwin MT, Fananapazir G, Jin M, Lamba R, Bashir MR. Differences in Liver Imaging and Reporting Data System categorization between MRI and CT. AJR Am J Roentgenol 2016; 206 (02) 307-312
- 9 Kambadakone AR, Fung A, Gupta RT. et al. LI-RADS technical requirements for CT, MRI, and contrast-enhanced ultrasound. [published correction appears in Abdom Radiol (NY). 2018 Jan;43(1):240] Abdom Radiol (NY) 2018; 43 (01) 56-74
- 10 Choi JY, Lee JM, Sirlin CB. CT and MR imaging diagnosis and staging of hepatocellular carcinoma: part II. Extracellular agents, hepatobiliary agents, and ancillary imaging features. Radiology 2014; 273 (01) 30-50
- 11 Krishan S, Dhiman RK, Kalra N. et al. Joint consensus statement of the Indian National Association for study of the liver and Indian radiological and imaging association for the diagnosis and imaging of hepatocellular carcinoma incorporating liver imaging reporting and data system. J Clin Exp Hepatol 2019; 9 (05) 625-651
- 12 American College of Radiology website. CT/MRI Liver Imaging Reporting and Data System version 2018. . Available at: Accessed August 22, 2023 at: www.acr.org/Clinical-Resources/Reporting-and-Data-Systems/LI-RADS/CT-MRI-LI-RADS-v2018
- 13 Chernyak V, Santillan CS, Papadatos D, Sirlin CB. LI-RADS® algorithm: CT and MRI. Abdom Radiol (NY) 2018; 43 (01) 111-126
- 14 Choi JY, Cho HC, Sun M, Kim HC, Sirlin CB. Indeterminate observations (liver imaging reporting and data system category 3) on MRI in the cirrhotic liver: fate and clinical implications. AJR Am J Roentgenol 2013; 201 (05) 993-1001
- 15 Fowler KJ, Potretzke TA, Hope TA, Costa EA, Wilson SR. LI-RADS M (LR-M): definite or probable malignancy, not specific for hepatocellular carcinoma. Abdom Radiol (NY) 2018; 43 (01) 149-157
- 16 Catania R, Chupetlovska K, Borhani AA, Maheshwari E, Furlan A. Tumor in vein (LR-TIV) and liver imaging reporting and data system (LI-RADS) v2018: diagnostic features, pitfalls, prognostic and management implications. Abdom Radiol (NY) 2021; 46 (12) 5723-5734
- 17 Tang A, Bashir MR, Corwin MT. et al; LI-RADS Evidence Working Group. Evidence supporting LI-RADS major features for CT- and MR imaging-based diagnosis of hepatocellular carcinoma: a systematic review. Radiology 2018; 286 (01) 29-48
- 18 International Consensus Group for Hepatocellular NeoplasiaThe International Consensus Group for Hepatocellular Neoplasia. Pathologic diagnosis of early hepatocellular carcinoma: a report of the international consensus group for hepatocellular neoplasia. Hepatology 2009; 49 (02) 658-664
- 19 Kielar AZ, Chernyak V, Bashir MR. et al. LI-RADS 2017: an update. J Magn Reson Imaging 2018; 47 (06) 1459-1474
- 20 Efremidis SC, Hytiroglou P. The multistep process of hepatocarcinogenesis in cirrhosis with imaging correlation. Eur Radiol 2002; 12 (04) 753-764
- 21 Santillan C, Fowler K, Kono Y, Chernyak V. LI-RADS major features: CT, MRI with extracellular agents, and MRI with hepatobiliary agents. Abdom Radiol (NY) 2018; 43 (01) 75-81
- 22 Cerny M, Chernyak V, Olivié D. et al. LI-RADS version 2018 ancillary features at MRI. Radiographics 2018; 38 (07) 1973-2001
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Publication History
Article published online:
31 August 2023
© 2023. The Author(s). This is an open access article published by Thieme under the terms of the Creative Commons Attribution License, permitting unrestricted use, distribution, and reproduction so long as the original work is properly cited. (https://creativecommons.org/licenses/by/4.0/)
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References
- 1 Paik JM, Golabi P, Younossi Y, Mishra A, Younossi ZM. Changes in the global burden of chronic liver diseases from 2012 to 2017: the growing impact of NAFLD. Hepatology 2020; 72 (05) 1605-1616
- 2 Ferlay J, Ervik M, Lam F. et al. Global Cancer Observatory: Cancer Today. Lyon: International Agency for Research on Cancer; 2020
- 3 Rosiak G, Podgorska J, Rosiak E, Cieszanowski A. Comparison of LI-RADS v.2017 and ESGAR guidelines imaging criteria in HCC diagnosis using MRI with hepatobiliary contrast agents. BioMed Res Int 2018; 2018: 7465126
- 4 Marks RM, Masch WR, Chernyak V. LI-RADS: past, present, and future, from the AJR special series on radiology reporting and data systems. AJR Am J Roentgenol 2021; 216 (02) 295-304
- 5 Marrero JA, Kulik LM, Sirlin CB. et al. Diagnosis, staging, and management of hepatocellular carcinoma: 2018 practice guidance by the American Association for the Study of Liver Diseases. Hepatology 2018; 68 (02) 723-750
- 6 Schwarze V, Marschner C, Völckers W. et al. Diagnostic value of contrast-enhanced ultrasound versus computed tomography for hepatocellular carcinoma: a retrospective, single-center evaluation of 234 patients. J Int Med Res 2020; 48 (06) 300060520930151
- 7 Chernyak V, Fowler KJ, Kamaya A. et al. Liver Imaging Reporting and Data System (LI-RADS) version 2018: imaging of hepatocellular carcinoma in at-risk patients. Radiology 2018; 289 (03) 816-830
- 8 Corwin MT, Fananapazir G, Jin M, Lamba R, Bashir MR. Differences in Liver Imaging and Reporting Data System categorization between MRI and CT. AJR Am J Roentgenol 2016; 206 (02) 307-312
- 9 Kambadakone AR, Fung A, Gupta RT. et al. LI-RADS technical requirements for CT, MRI, and contrast-enhanced ultrasound. [published correction appears in Abdom Radiol (NY). 2018 Jan;43(1):240] Abdom Radiol (NY) 2018; 43 (01) 56-74
- 10 Choi JY, Lee JM, Sirlin CB. CT and MR imaging diagnosis and staging of hepatocellular carcinoma: part II. Extracellular agents, hepatobiliary agents, and ancillary imaging features. Radiology 2014; 273 (01) 30-50
- 11 Krishan S, Dhiman RK, Kalra N. et al. Joint consensus statement of the Indian National Association for study of the liver and Indian radiological and imaging association for the diagnosis and imaging of hepatocellular carcinoma incorporating liver imaging reporting and data system. J Clin Exp Hepatol 2019; 9 (05) 625-651
- 12 American College of Radiology website. CT/MRI Liver Imaging Reporting and Data System version 2018. . Available at: Accessed August 22, 2023 at: www.acr.org/Clinical-Resources/Reporting-and-Data-Systems/LI-RADS/CT-MRI-LI-RADS-v2018
- 13 Chernyak V, Santillan CS, Papadatos D, Sirlin CB. LI-RADS® algorithm: CT and MRI. Abdom Radiol (NY) 2018; 43 (01) 111-126
- 14 Choi JY, Cho HC, Sun M, Kim HC, Sirlin CB. Indeterminate observations (liver imaging reporting and data system category 3) on MRI in the cirrhotic liver: fate and clinical implications. AJR Am J Roentgenol 2013; 201 (05) 993-1001
- 15 Fowler KJ, Potretzke TA, Hope TA, Costa EA, Wilson SR. LI-RADS M (LR-M): definite or probable malignancy, not specific for hepatocellular carcinoma. Abdom Radiol (NY) 2018; 43 (01) 149-157
- 16 Catania R, Chupetlovska K, Borhani AA, Maheshwari E, Furlan A. Tumor in vein (LR-TIV) and liver imaging reporting and data system (LI-RADS) v2018: diagnostic features, pitfalls, prognostic and management implications. Abdom Radiol (NY) 2021; 46 (12) 5723-5734
- 17 Tang A, Bashir MR, Corwin MT. et al; LI-RADS Evidence Working Group. Evidence supporting LI-RADS major features for CT- and MR imaging-based diagnosis of hepatocellular carcinoma: a systematic review. Radiology 2018; 286 (01) 29-48
- 18 International Consensus Group for Hepatocellular NeoplasiaThe International Consensus Group for Hepatocellular Neoplasia. Pathologic diagnosis of early hepatocellular carcinoma: a report of the international consensus group for hepatocellular neoplasia. Hepatology 2009; 49 (02) 658-664
- 19 Kielar AZ, Chernyak V, Bashir MR. et al. LI-RADS 2017: an update. J Magn Reson Imaging 2018; 47 (06) 1459-1474
- 20 Efremidis SC, Hytiroglou P. The multistep process of hepatocarcinogenesis in cirrhosis with imaging correlation. Eur Radiol 2002; 12 (04) 753-764
- 21 Santillan C, Fowler K, Kono Y, Chernyak V. LI-RADS major features: CT, MRI with extracellular agents, and MRI with hepatobiliary agents. Abdom Radiol (NY) 2018; 43 (01) 75-81
- 22 Cerny M, Chernyak V, Olivié D. et al. LI-RADS version 2018 ancillary features at MRI. Radiographics 2018; 38 (07) 1973-2001













