CC BY-NC-ND 4.0 · Journal of Gastrointestinal and Abdominal Radiology 2022; 05(02): 094-106
DOI: 10.1055/s-0042-1742432
Review Article

Dual-Energy Computed Tomography in Diffuse Liver Diseases

Uday Kumar Marri
1   Department of Radiodiagnosis and Interventional Radiology, All India Institute of Medical Sciences, New Delhi, India
,
Kumble Seetharama Madhusudhan
1   Department of Radiodiagnosis and Interventional Radiology, All India Institute of Medical Sciences, New Delhi, India
› Institutsangaben
 

Abstract

Dual-energy computed tomography (DECT) is an advancement in the field of CT, where images are acquired at two energies. Materials are identified and quantified based on their attenuation pattern at two different energy beams using various material decomposition algorithms. With its ability to identify and quantify materials such as fat, calcium, iron, and iodine, DECT adds great value to conventional CT and has innumerable applications in body imaging. Continuous technological advances in CT scanner hardware, material decomposition algorithms, and image reconstruction software have led to considerable growth of these applications. Among all organs, the liver is the most widely investigated by DECT, and DECT has shown promising results in most liver applications. In this article, we aim to provide an overview of the role of DECT in the assessment of diffuse liver diseases, mainly the deposition of fat, fibrosis, and iron and review the most relevant literature.


#

Introduction

Dual-energy computed tomography (DECT) is a significant advancement in the field of computed tomography (CT), where images are acquired at two different energies (kilovolts) and “material decomposition” algorithms are used to differentiate and quantify various materials with different effective atomic numbers such as water, fat, iron, and iodine in a given pixel. The concept of dual-energy acquisition and its potential benefits were first described in 1973 by Hounsfield in his original article on CT systems.[1] However, a lot of technical difficulties had to be overcome before his vision was realized when the first clinical DECT scanner was introduced in 2006.[2] Since then, all major CT manufacturers have introduced DECT scanners with different machine designs and image processing softwares.

Diffuse liver disease, particularly cirrhosis, is a growing public health problem worldwide and is associated with significant morbidity and mortality.[3] Liver biopsy is currently the gold standard for diagnosis (presence of inflammation, fibrosis, fat, iron) and staging of chronic liver parenchymal diseases.[4] However, it is invasive, associated with hemorrhagic complications, and subject to sampling errors and inter-observer variations.[5] [6] A repeat biopsy to monitor the course of the disease and assess response to treatment is unjustified and has low acceptance among patients. Hence, there is a need for a reliable, reproducible, and non-invasive alternative. Magnetic resonance imaging (MRI) with its versatile techniques and sequences is increasingly becoming a well-established and accurate imaging tool for the purpose of assessing fat, fibrosis, and iron deposition.[7] [8] [9] However, MRI is expensive, takes a long time to scan compared to CT or ultrasonography, and requires special sequences and hardware. Although the role of DECT in diffuse liver diseases is evolving, this article aims to review the most relevant literature on the use of DECT in the assessment of diffuse liver diseases, mainly the deposition of fat, fibrosis, and iron. We would also briefly discuss the basic principles of DECT image acquisition and image reconstruction with a focus on the areas that are relevant in the assessment of diffuse liver diseases.


#

Basic Principles of DECT

In CT, the photoelectric effect and Compton scattering are the dominant X-ray interactions influencing image formation.[10] The attenuation of X-rays in each voxel is a function of the linear attenuation coefficient of the medium and energy of incident X-rays. The linear attenuation coefficient in turn depends on the effective atomic number of the medium and its material density.[11] [12] On a single-energy CT (SECT), materials with different atomic numbers may have the same CT attenuation value (Hounsfield unit [HU]) if the material densities are different. Hence, SECT cannot differentiate them. In DECT, using a second X-ray spectrum, two image datasets are produced, one from low energy and the other from high energy. The degree of attenuation change (attenuation coefficient) with a change in X-ray energy is independent of material density and is material specific. Materials such as fat, iodine, and bone have different degrees of attenuation change and can be identified based on this difference ([Fig. 1]). With an appropriate software algorithm, these material-specific energy-dependent attenuation coefficients can also be used to quantify the mass density of two or three materials in a mixture of known material composition.[13] [14] Typically, the low-energy beam is 80 to 100 kVp (kilovoltage peak) and the high energy beam is 120 to 150 kVp. To generate the DECT image data, different approaches are followed, with modifications done either at the X-ray tube level or the detector level. These vendor-specific techniques of DECT scanners are described elsewhere in this issue.

Zoom Image
Fig. 1 Principle of dual-energy CT material decomposition algorithm to identify and quantify different materials. The graph shows a change in mass attenuation coefficients of iodine, bone (calcium), and fat at a wide range of X-ray energies. At specific X-ray energy, mass attenuation coefficient (linear attenuation coefficient/density) is only dependent on the effective atomic number of the medium. A difference in this coefficient at two different energy X-rays (for example 80 kVp and 140 kVp as shown in the graph) depends on the effective atomic number of the medium and not the medium density.

Although the post-processing software of DECT is vendor-specific, in general, the workflows are not very different from each other. After the acquisition, the DECT images (either non-contrast or contrast-enhanced depending on the indication for which DECT is being performed) are transferred to the DECT workstation and loaded onto the dual-energy software provided by the vendors. Various material-specific algorithms are inbuilt in the DECT software. The technique of quantification of a material is usually simple ([Fig. 2]). The images are opened in the material-specific application and a region of interest (ROI) is drawn over the liver parenchyma avoiding major vessels. The ROI displays the concentration of the material, e.g., iodine or fat, being evaluated. Multiple ROIs may be drawn in different lobes and segments (at least three ROIs in each lobe) of the liver to get a mean of the values for reliable and reproducible results. Color-coded maps can also be generated for providing an overview of the distribution of the material in the liver parenchyma.

Zoom Image
Fig. 2 Overview of dual-source dual-energy computed tomography (DECT) post-processing software (Syngo.via, version VB10B, 2016; Siemens Healthineers). Based on the material being evaluated, an appropriate application profile (in the left upper corner box) is chosen. Liver virtual non-contrast (VNC) is selected in this image to measure liver iodine concentration on the delayed phase DECT, for fibrosis quantification. The region of interest placed on the axial image shows various parameters including Iodine density and fat fraction in that region. The same application can be used for liver fat quantification. Color-coded iodine maps are seen in three different planes.

#

Hepatic Steatosis

Hepatic steatosis (HS) or fatty liver, currently is most commonly associated with non-alcoholic fatty liver disease (NAFLD).[15] The other common causes of HS are alcohol consumption,[16] hepatitis C,[17] [18] and use of certain medications including many chemotherapeutic agents[19] [20] [21] and corticosteroids.[22] The estimated prevalence of HS is ∼25% worldwide.[23] NAFLD is frequently associated with metabolic syndrome, which comprises a set of risk factors for cardiovascular disease and type II diabetes that include obesity, hypertension, elevated triglycerides, and insulin resistance.[24] [25]

Quantification of hepatic fat is important in patients with HS, as increasing steatosis leads to the development of steatohepatitis and then to cirrhosis with increased risk for the occurrence of hepato-cellular carcinoma and associated with poor liver surgical outcomes.[26] [27] [28] However, with appropriate therapeutic strategies such as lifestyle modifications (dietary regulation and physical exercise) and drugs (pioglitazone and vitamin E), hepatic steatosis can be reversed along with the incidence of its metabolic complications.[29] Hence, we need a reliable non-invasive modality for diagnosis, prognostication, and treatment monitoring in patients with HS. Chemical shift relaxometry and spectroscopy on MRI and backscatter coefficients or controlled attenuation parameters on ultrasonography (USG) are various imaging methods that can be used for liver fat quantification.[30] MR spectroscopy (MRS) has proven to be the most accurate imaging tool and has the potential to replace biopsies.[31] However, MRS can only quantify fat in a small area at a time and multiple measurements to cover the entire liver is a time-consuming process. Because of these reasons, MRS has been replaced by chemical shift imaging-derived proton density fat fraction (PDFF) as an imaging gold standard for liver fat quantification.[9] [32] However, the higher cost of MRI scan is the major limiting factor for its routine use. Ultrasound elastography is dependent on reference phantoms, prone to measurement errors especially in overweight female patients, and does not measure fat accurately as the values are influenced by co-existing fibrosis.[33] However, the controlled attenuation parameter obtained on transient elastography (Fibroscan) has shown promising results in quantifying liver fat.[34] [35] In SECT, semiquantitative fat measurements can be performed using the attenuation value of the liver (HU), preferably on an unenhanced scan.[36] [37] However, absolute liver attenuation values can be affected by various factors such as CT acquisition parameters and the patient's cardiac and renal function. To overcome these, several authors have compared the attenuation of the liver to that of other abdominal organs and described various indices such as liver attenuation index (difference between liver and spleen attenuation)[38] [39] [40] and L/S ratio (ratio of liver to spleen attenuation),[39] [41] which produced better results. However, attenuation values on SECT are still influenced by the presence of iodinated contrast material or liver iron. Further, SECT is less sensitive in the detection of early HS (sensitivity ranges from 52 to 62% in cases with 10 to 20% fat).[42]

In DECT, with the help of the “material decomposition” algorithm, it is possible to not only identify but also quantify the liver fat in a defined region ([Figs. 3] and [4]).[12] A few studies have evaluated the role of DECT in the detection and quantification of liver fat ([Table 1]).

Table 1

Brief details and summaries of results of studies evaluating dual-energy computed tomography in hepatic steatosis

Study (y)

Sample size

Cases/controls

Modality of comparison

DECT scanner type

DECT energies

Key results

Mendler et al

(1998)

16/11

DECT (non-contrast) versus USG and SECT

GE Pace-Plus

80, 140 kV

• Good correlation between liver –spleen attenuation difference on SECT and histology (r = 0.74)

• No significant correlation between ∆HU on DECT and histology

• USG superior to SECT and DECT in diagnosing fatty liver

Zheng et al.

(2013)

32/20

DECT versus USG and SECT

GE Discovery CT 750 HD

80, 140 kV

• Good correlation between DECT fat percentage and liver spleen attenuation difference on SECT (r = 0.98)

• DECT superior to SECT, with its distinct mono-energetic spectral curves with different steatosis grades and ability to delineate areas of fat infiltration on subtraction images

Patel et al

(2013)

107/229

DECT (late arterial phase) and SECT

GE Discovery CT 750 HD

80, 140 kV

• Good correlation between liver spleen attenuation difference on SECT and DECT fat fraction (r = 0.74, p < 0.001)

• Fat quantification on contrast enhanced DECT accurate (AUROC = 0.85)

Kramer et al

(2017)

50/0

DECT (non-contrast), MR-PDFF, USG and elastography versus MRS

GE Discovery CT 750 HD

80, 140 kV

• Moderate correlation between DECT fat fraction and MRS (r 2 = 0.42 for anterior liver segments, r2 = 0.26 for posterior liver segments)

• Excellent correlation between SECT attenuation and MR-PDFF with MRS (r 2 = 0.86 and 0.99, respectively)

• Ultrasound elastography showed poor correlation with MRS (r 2 = 0.004)

Hyodo et al

(2017)

29/4

DECT (late arterial, portal venous, and delayed phases) versus histology and MRS

GE Discovery CT 750 HD

80, 140 kV

• DECT (unenhanced and contrast-enhanced) correlated well with histology

• No significant difference in DECT fat fraction of unenhanced, arterial, portal venous, and delayed phases (not more than 2%)

• In differentiating steatosis grade 0 from 1–3, AUROC for DECT and MRS were 0.88 and 0.89, respectively.

Corrias et al

(2021)

39/0

DECT (late arterial phase) versus MR-PDFF

GE Discovery CT 750 HD

80, 140 kV

• No significant difference in DECT fat fraction and MRI-PDFF (two readers with correlation coefficients, 0.84 and 0.85, p < 0.05)

• Good inter-reader agreement for both techniques. (kappa coefficient - 0.88 for MRI-PDFF, 0.97 for DECT-FF, p < 0.05)

Abbreviations: ∆HU, difference in attenuation between low- and high-energy images; AUROC, area under receiver operating characteristic; DECT, dual-energy computed tomography; MR-PDFF, magnetic resonance proton density fat fraction; MRS, magnetic resonance spectroscopy; r, correlation coefficient; r 2, correlation of determination; SECT, single energy CT; USG, ultrasonography.


Zoom Image
Fig. 3 Measurement of hepatic fat content on dual-source dual-energy computed tomography. (A, B) Axial virtual non-contrast (VNC) image of a patient (A) with normal liver parenchyma with two circular regions of interest (ROIs) drawn on the liver show close to zero fat fraction and corresponding color-coded fat map (B) shows almost no fat in the liver parenchyma. (C, D) Axial VNC image (C) of another patient with non-alcoholic fatty liver disease with two ROIs show 20% of fat fraction and corresponding color-coded fat map (D) shows the distribution of fat in the liver parenchyma.
Zoom Image
Fig. 4 Measurement of hepatic fat content on rapid switching dual-energy computed tomography. (A) Axial, contrast-enhanced image of the patient with fatty liver. (B) Virtual unenhanced image at the same level with two circular regions of interest. Mean attenuation was 32 HU and fat fraction was 15.5%. (C) The corresponding color-coded fat map shows the distribution of fat in the liver parenchyma.

The oldest study was by Mendler et al that showed that DECT-∆HU (∆HU–difference in attenuation between low-energy and high-energy images) generated using the sequential technique, is inferior to both SECT liver–spleen attenuation difference and ultrasound.[43] Hyodo et al reported that the area under the receiver operating characteristic (ROC) curve of DECT was 0.88 (95% confidence interval: 0.74–0.98) in the detection of fatty liver with more than 5% fat in needle biopsy tissue.[44] This was comparable to MRS (area under the ROC curve = 0.89). A study by Kramer et al showed that non-contrast DECT had a moderate correlation with MRS (r 2 = 0.423), whereas SECT had an excellent correlation with MRS (r 2 = 0.856) in the quantification of hepatic fat.[31] The authors concluded that non-contrast DECT does not improve the accuracy of fat quantification over conventional SECT. The reason for this was that material decomposition is less accurate in the differentiation of fat and water on non-contrast DECT compared with iodine and water on contrast-enhanced DECT. Corrias et al compared DECT and PDFF on MRI in quantifying fat in patients with post-chemotherapy HS.[45] They found no statistically significant difference between these two modalities in fat quantification and showed an excellent inter-reader agreement of DECT (kappa = 0.97, p < 0.05). Patel et al evaluated liver fat density on contrast-enhanced DECT using spleen–liver attenuation difference < 1 HU on non-contrast SECT as the reference standard for steatosis. The DECT fat measurement correlated well with the reference standard, with an r-value of 0.74 (p < 0.001) and area under receiver operator curve of 0.847.[46] The role of DECT in fat quantification was also evaluated in several phantom studies and animal studies with mixed results.[47] [48] [49] [50] [51] [52] [53]

Recent studies have shown that, unlike SECT, material decomposition on DECT can accurately quantify liver fat even on contrast-enhanced images.[44] [45] [46] This is also supported by other studies which have shown high fidelity of HU values measured on virtual non-contrast (VNC) images compared with unenhanced CT within the liver and other abdominal organs.[54] [55] [56] [57] This is invaluable because most fatty livers are incidental on post-contrast images and plain scans are not acquired routinely. Hyodo et al suggested that among contrast phases, an equilibrium phase is the best alternative to non-contrast CT in liver fat quantification on DECT.[44]

DECT is a valid technique in quantifying liver fat and can be used reliably in all suspected cases of hepatic steatosis. It can be seamlessly integrated into abdomen CT scan protocols for liver fat quantification. Although a non-contrast scan is preferred, with the use of the latest multi-material algorithms, fat can be reliably quantified even on contrast-enhanced CT scans.


#

Liver Fibrosis

Liver fibrosis is the common underlying pathological process in chronic liver diseases, regardless of the cause. This results from the excessive accumulation of the extracellular matrix.[58] Progression of liver fibrosis parallels with the increase in portal pressure, which worsens the prognosis due to the associated complications.[58] Hence, assessment of the severity of liver fibrosis has direct implications on the treatment, follow-up planning, and risk stratification in patients with chronic liver disease.[3] [59] For instance, in chronic viral hepatitis, the presence of bridging fibrosis on histology is a strong factor for the recommendation of antiviral therapy, whereas the presence of cirrhosis calls for an endoscopy for esophageal varices and also screening for hepatocellular carcinoma.[4] This clinical significance of detection and grading of liver fibrosis has led to an active search for a non-invasive modality to quantify fibrosis in these patients.

Ultrasound elastography (transient and shear-wave elastography) techniques are simple, inexpensive, and accurate. However, their measurements are affected by the presence of ascites, obesity, biliary obstruction, acute inflammation, fatty liver, and narrow intercostal spaces.[60] [61] [62] MR elastography is the most accurate non-invasive modality in quantifying liver fibrosis and correlates closest to the histological staging.[60] [63] Nonetheless, in spite of these advantages, the high cost, lack of accessibility, the requirement of dedicated hardware, and confounding effects by coexisting iron accumulation preclude its routine use.

DECT cannot directly detect or quantify fibrosis in the liver on non-contrast CT as it shows a similar attenuation pattern as the rest of the parenchyma. Several studies have attempted to quantify fibrosis by measuring extracellular volume fraction using liver attenuation values on contrast-enhanced delayed phase SECT with good correlation with histology.[64] [65] [66] [67] The timing of the delayed phase CT in these studies was heterogeneous, ranging from 3 to 30 minutes. This is based on the hypothesis that fibrotic areas in the liver retain more contrast material in the delayed phase due to the increased extracellular space due to matrix deposition and reduced perfusion.[66] [68] This contrast retention is reflected by the concentration of iodine in the liver that can be readily measured on DECT. Therefore, the concentration of the iodine in the liver on delayed phase DECT directly correlates to the concentration of fibrous tissue in the liver. Lv et al[69] evaluated the role of portal venous phase (obtained 30 seconds after the arterial phase was acquired by bolus triggering) DECT in 38 patients with cirrhotic livers (Child-Pugh class A/B/C: n = 10/14/14) and 43 patients with healthy livers. In differentiating healthy liver from a cirrhotic liver, a cut-off value of 0.52 of the normalized iodine concentration (normalized iodine concentration [NIC], which is the ratio of iodine concentration of liver to that of the aorta) in the portal venous phase showed high sensitivity (95%), but relatively lower specificity (61%). The iodine concentration (IC) ratio (iodine concentration of liver in the arterial phase to that in the portal vein phase) with a cut-off at 0.3 showed high sensitivity (79%) but low specificity (49%). However, a combination of these two parameters showed high sensitivity (77%) and specificity (87%).

Lamb et al[12] found that NIC of liver on a 3-minute delayed phase DECT strongly correlated with Ishak fibrosis stage (p < 0.05). Fuentes et al,[70] in their retrospective study on 12 participants, showed a strong correlation between NIC in the delayed phase and Ishak fibrosis stage (r = 0.77, p < 0.01). Sofue et al[71] in a 47-patient cohort showed that NIC had a good correlation with the METAVIR fibrosis stage (r  =  0.65, p < 0.001). The area under the receiver operating curve (AUROC) ranged from 0.79 to 0.86 in discriminating each liver fibrosis stage (≥F1–F4). The NIC cut-off values for the diagnosis of METAVIR stages ≥F1, ≥F2, ≥ F3 and =F4 were found to be 0.270, 0.274, 0.286, and 0.299 with accuracies of 74.5%, 78.7%, 78.7%, and 76.6%, respectively. In a recent prospective study evaluating 107 patients of chronic liver disease by Marri et al[68] in our institute, the NIC on the 5-minute delayed phase DECT was compared with the METAVIR stage on histology ([Fig. 5]). The NIC showed a high positive correlation with METAVIR fibrosis stage (r = 0.81; p < 0.0001). The AUROC for the NIC in the right lobe of the liver with respect to each METAVIR stage ranged from 0.86 to 0.96. The cut-off values (with sensitivity and specificity) of NIC for different fibrosis stages were ≥F1 = 0.243 (85.1%, 83.3%), ≥F2 = 0.289 (83.7%, 81.4%), ≥F3 = 0.343 (86.9%, 86.8%), =F4 = 0.401 (93.3%, 84.7%), respectively. A 5-minute delayed DECT was used in this study in contrast to the previous studies, where a 3-minute delay was used. This longer delay had resulted in a better performance of DECT in fibrosis quantification and fewer overlapping NIC cut-offs for the METAVIR stages. DECT performance was also compared with elastography in this study. NIC showed good agreement with liver stiffness as measured with transient elastography and shear-wave elastography (Spearman r = 0.60 and 0.64, respectively; p <0.001). An overview of some of the studies is shown in [Table 2].

Table 2

Brief details and summaries of results of studies evaluating dual-energy CT in hepatic fibrosis

Study (year)

Sample size

Cases/control

Modality of comparison

DECT Scanner type

DECT energies

Key results

Lv et al

(2012)

38/43

DECT - Portal venous phase NIC and IC ratio with Child-Pugh score

GE Discovery CT 750 HD

80, 140 kV

• NIC cut-off of 0.52: high sensitivity (95%) but relatively low specificity (61%).

• IC ratio with cut-off of 0.3: high sensitivity (79%) but low specificity (49%).

• High sensitivity (77%) and specificity (87%) for combination of NIC and IC ratio in differentiating healthy liver from the cirrhotic liver.

Lamb et al

(2015)

7/5

DECT - 3-minute delayed phase liver NIC with histology

GE Discovery CT 750 HD

80, 140 kV

• NIC on DECT correlated with histology and allowed statistically significant stratification of patients by severity of fibrosis (p < 0.05 for all stages)

• On two different time point scans, NIC showed a high degree of repeatability (r 2 = 0.93)

Sofue et al

(2018)

47/0

DECT - 3-minute delayed phase liver NIC with histology

GSI, GE Discovery CT 750 HD

80, 140 kV

• NIC showed moderate correlation with METAVIR stage (r = 0.63, p < 0.001)

• In discriminating each fibrosis stage, AUROC for NIC ranged from 0.80 to 0.86

Marri et al

(2021)

107/50

DECT - 5-minute delayed phase liver NIC and sonoelastography with histology

SOMATOM DF, Siemens

100, 140 kV

• NIC showed strong correlation with METAVIR stage (r = 0.81, p < 0.001)

• In discriminating each fibrosis stage, AUROC for NIC ranged from 0.86 to 0.96

• NIC showed good agreement with liver stiffness as measured with transient elastography and shear wave elastography (r = 0.60 and 0.64, respectively, p < 0.001)

• 5-minute delayed phase showed better sensitivity and specificity compared with 3-minute delay, which was used in previous studies

Abbreviations: ∆HU, difference in attenuation between low- and high-energy images; AUROC, area under receiver operating characteristic; DECT, dual-energy CT; GSI, gemstone imaging; IC, iodine concentration; NIC, normalized iodine concentration; r, correlation coefficient; r 2, correlation of determination.


Zoom Image
Fig. 5 Assessment of hepatic fibrosis on dual-source dual-energy computed tomography (DECT) in a 40-year-old man with chronic hepatitis B cirrhosis. (A) Axial 5-minute delayed phase DECT image with circular regions of interest (ROIs) in both lobes of the liver. Normalized iodine concentration (NIC) in the right and left lobes were 0.571 and 0.539, respectively. (B) The iodine map of the delayed phase shows heterogeneous iodine uptake in the liver. (C) Histology of the biopsy sample showed a METAVIR stage of F4. The NIC values were consistent with cut-offs suggested by a recent study by Marri et al.

A significant number of patients with chronic liver disease routinely undergo multiphase CT scans of the abdomen as part of hepatocellular carcinoma surveillance. The possibility of grading the severity of fibrosis on the same scan would be invaluable. The addition of dual-energy acquisition in the contrast-enhanced delayed phase, preferably 5-minute, is suggested for this purpose ([Fig. 6]). This could reduce the number of biopsies and related complications in these patients. Simultaneously, larger studies are needed to formulate a uniform CT acquisition protocol, delayed phase timing, and NIC cut-off values in each fibrosis stage in these patients.

Zoom Image
Fig. 6 Assessment of hepatic fibrosis on rapid switching dual-energy computed tomography (DECT) in a 46-year-old man with alcoholic cirrhosis. (A) Axial 5-minute delayed-phase DECT image with circular regions of interest (ROIs) in both lobes of the liver. Normalized iodine concentration in the right and left lobes were 0.490 and 0.513, respectively, suggesting a stage of F4, according to Marri et al. (B) Iodine map from the delayed phase shows heterogeneous iodine uptake in the liver.

#

Hepatic Iron

Liver iron deposition and chronic liver disease are interrelated. Deposition of iron in the liver parenchyma can be due to increased total body iron as seen in hereditary hemochromatosis or transfusion-related hemosiderosis.[72] Conversely, liver diseases such as chronic viral hepatitis, alcoholic liver disease, and non-alcoholic steatohepatitis (NASH) also promote iron deposition in the liver.[73] [74] Increasing iron deposition in the hepatocytes causes liver damage by oxidative stress, eventually leading to cirrhosis and the possibility of the development of hepatocellular carcinoma (HCC).[75] Hepatic iron deposition in chronic liver disease is also independently associated with increased mortality.[76] Hence, liver iron detection and quantification are crucial for the management of these patients.

MRI is widely considered the primary modality for non-invasive liver iron quantification. Chemical shift imaging, the signal intensity of liver relative to spleen on fast-spin echo T2-weighted sequence, liver to muscle signal intensity ratio on multi-echo gradient recalled echo (GRE) sequence, and R2 and R2* relaxometry are the various MRI techniques used in accurate estimation of liver iron content.[77] [78] Among these, R2 relaxometry is the most validated and often considered as the gold standard.[77] However, R2* relaxometry is more practical because the GRE sequence is faster, results are reliable, and simultaneous acquisition of fat and iron is possible in a single breath-hold.[78] Apart from the high cost and inaccessibility to MRI machine and post-processing software, the variability of the results in the presence of high concentrations of liver iron is a limitation.

On DECT, unenhanced CT is preferred for iron quantification. Liver iron is quantified either by using the attenuation difference of the liver between the low- and high-energy CT images (∆HU) or using an iron-specific material decomposition algorithm, which gives virtual iron content based on the attenuation difference ([Table 3]; [Fig. 7]). Joe et al in their retrospective study showed that DECT-∆HU (difference of liver attenuation between 80 and 140 kVp) correlates well with the degree of iron accumulation (r = 0.43, p < 0.001).[79] The mean ΔH was 13.53 in patients with clinically important (≥ 10%) iron accumulation compared with 7.39 in normal patients. The DECT-∆HU showed similar excellent performance in diagnosing iron overload compared with MRI. The concurrent presence of liver fat did not affect the DECT performance in this study. Luo et al found that virtual iron concentration on DECT showed a significant correlation with R2* and MRI measured liver iron content (r = 0.89 and 0.87, respectively; p < 0.001).[80] This study also suggested that DECT has similar diagnostic performance as MRI. A study by Werner et al showed a strong correlation between virtual iron content on DECT and serum ferritin in patients of transfusional hemosiderosis (r = 0.62, p < 0.001).[81] In a retrospective study by Ma et al, the authors showed a strong correlation between liver DECT-∆HU and R2* values in MRI (r = 0.83, p < 0.001).[52]

Zoom Image
Fig. 7 Assessment of liver iron content on dual-source dual-energy computed tomography in a 19-year-old male patient with β thalassemia. (A, B) Axial high energy (A, 140 kVp) and low energy (B, 80 kVp) non-contrast images show a mean difference in attenuation of liver between the two energies (ΔHU) of 14.1 HU, suggesting iron deposition. (C) Axial multi-echo gradient MR images from a 3T machine show a gradual decrease in liver signal with an increase in TE. The T2* value was 10.3 milliseconds and R2* was 163/s suggestive of moderate iron deposition.
Table 3

Brief details and summaries of results of studies evaluating dual-energy computed tomography in hepatic iron deposition

 Study (year)

Sample size

Cases/controls

Modality of comparison

DECT Scanner type

DECT energies

Key results

Joe et al.

(2011)

87/0

DECT-∆HU and MRI (T1 IP and OP, and HASTE) with histology

SOMOTOM D,

Siemens

80, 140 kV

• Significant correlation of DECT-∆HU with degree of liver iron accumulation (r = 0.43, p < 0.01)

• AUROC for clinically significant iron accumulation with DECT and MRI were 0.88 and 0.89, respectively.

Luo et al.

(2015)

56/0

DECT- material decomposition (VIC) with R2 and R2* technique

SOMATOM DF, Siemens

80, 140 kV

• Significant correlation between iron content on DECT and R2* & R2 MRI (r = 0.89 and 0.87, respectively; p < 0.001)

• At liver iron content > 3.2 mg/g of dry tissue, DECT and MRI R2* similar (AUROC, 0.96 vs. 0.99, respectively; p = 0.30)

Werner et al.

(2019)

99/48

DECT - VIC with serum ferritin and estimated transfused iron

SOMATOM DF, Siemens

100, 140 kV

• Good correlation between DECT iron content and serum ferritin (r = 0.62, p < 0.001)

Ma et al.

(2020)

31/0

DECT-∆HU and MRI (R2* technique)

IQon, Philips

Tube voltage 120 kVp

with dual-layer spectral detector

• Good correlation of DECT-∆HU with MRI liver R2* (r = - 0.83, p < 0.001)

Abbreviations: ∆HU, difference in attenuation between low- and high-energy images; AUROC, area under receiver operating characteristic; DECT, dual-energy computed tomography; HASTE, half Fourier single-shot turbo spin echo; IP, in-phase; OP, opposed phase; r = correlation coefficient; VIC, virtual iron content.


Unlike SECT, which underestimates fat in the presence of iron and vice versa, several phantom and animal studies have shown that DECT can accurately quantify iron, even in the presence of fat[52] [82] [83] and vice versa.[52] [83] [84] In contrast, several other studies have suggested that iron and fat affect the measurement of each other on DECT.[85] [86] [87] A recent study also suggested that the phase of contrast-enhanced scan (arterial, portal venous, and delayed) significantly affects the hepatic iron measurements on DECT.[88] These confounding factors need to be studied further, and iron-specific algorithms, which are immune to these confounding effects, have to be developed before DECT can be recommended for routine use in this setting.

A summary of suggestions for practical applications of DECT in the quantification of hepatic fat, fibrosis, and iron content is given in [Table 4].

Table 4

Summary of suggestions for practical application of DECT in diffuse liver diseases

Dual-energy computed tomography: practical considerations

 • Most of the current published literature on the role of DECT in diffuse liver diseases has used a single-source DECT scanner with tube energies 80 kV and 140 kV. There are not enough data comparing single-source DECT and dual-source DECT or different tube energies to prefer one over the other.

 • When the iodinated contrast agent is used, the contrast volume, injection rate, and CT acquisition timings for DECT are the same as for conventional SECT. For liver fibrosis quantification, only a delayed phase CT (variably at 3 to 5 minutes) may be acquired in the dual-energy mode to avoid unnecessary data overload.

 • For measuring any material density on DECT, we recommend drawing at least three circular regions of interest (ROIs) with a diameter measuring 2 cm in each liver lobe, avoiding major vessels or focal lesions, to account for the heterogeneous distribution and for reproducible results.

Fat quantification

Iron quantification

Fibrosis quantification

• Non-contrast scan preferred although fat quantification can also be done on contrast-enhanced DECT.

• ΔHU (difference in the attenuation between low and high energy images) or fat-specific material decomposition algorithms are useful.

• Non-contrast scan is preferred although iron quantification can also be done on contrast-enhanced DECT.

• ΔHU (difference in the attenuation between low and high energy images) or iron-specific material decomposition algorithms are useful.

• Contrast-enhanced delayed phase scan is preferred.

• Although data are lacking on the optimum time of delay for fibrosis quantification, in our experience 5-minute delayed scan provides accurate results.

• Normalized iodine concentration (ratio of iodine concentration of liver to iodine concentration of aorta) provides better results.


#

Limitations

There are a few limitations to the routine use of DECT in diffuse liver diseases. The major limitation is the high cost of the scanners, additional software required for post-processing, and the need for larger data storage capacity. However, with the increasing number of installations, demands, and awareness of its considerable clinical utilities, the cost is expected to gradually reduce. Another limitation is the difference in the technique of DECT between different vendors. There are not enough studies comparing intervendor and interscanner variability with respect to the application of DECT in diffuse liver diseases. This may limit the uniformity of the study results. When DECT was first introduced, radiation dose was the main concern. However, later multiple studies have shown that DECT does not increase radiation dose compared with conventional CT and it is well within the ACR standard reference upper limit of 25 mGy for abdominal CT.[89] [90] [91] [92] [93] The presence of multiple material elements in the same area could affect the measurement of fat, iodine, or iron. It is still not clear whether the presence of fat and iron in the same voxel results in reduced performance of DECT. Active inflammation in the parenchyma, which is a key component of NASH and other chronic liver diseases,[94] [95] [96] [97] [98] [99] [100] [101] [102] is difficult to evaluate with an imaging modality such as DECT. Hence, a complete assessment will have to involve imaging in conjunction with other tests for inflammation.


#

Conclusion

Dual-energy CT is still in its infancy and most of its applications are still in the research phase and not yet in wide clinical use. With exponential technological advances in scanner hardware, material decomposition algorithms, and image reconstruction software, the role of DECT will continue to grow in body imaging, and diffuse liver diseases is not an exception. However, MRI and its applications will remain the imaging gold standard for quantifying liver fat, iron, and fibrosis. The results from a majority of preliminary studies on the role of DECT in diffuse liver diseases are promising. However, larger cohort studies are needed to further validate these results before they come into routine clinical practice. Optimum application of DECT in routine abdominal CT protocols would not only give additional information for better patient management but could also potentially prevent unnecessary biopsies.


#
#

Conflict of Interest

None declared.

  • References

  • 1 Hounsfield GN. Computerized transverse axial scanning (tomography). 1. Description of system. Br J Radiol 1973; 46 (552) 1016-1022
  • 2 Flohr TG, McCollough CH, Bruder H. et al. First performance evaluation of a dual-source CT (DSCT) system. Eur Radiol 2006; 16 (02) 256-268
  • 3 Sebastiani G. Non-invasive assessment of liver fibrosis in chronic liver diseases: implementation in clinical practice and decisional algorithms. World J Gastroenterol 2009; 15 (18) 2190-2203
  • 4 Bravo AA, Sheth SG, Chopra S. Liver biopsy. N Engl J Med 2001; 344 (07) 495-500
  • 5 Baranova A, Lal P, Birerdinc A, Younossi ZM. Non-invasive markers for hepatic fibrosis. BMC Gastroenterol 2011; 11: 91
  • 6 Chin JL, Pavlides M, Moolla A, Ryan JD. Non-invasive markers of liver fibrosis: adjuncts or alternatives to liver biopsy?. Front Pharmacol 2016; 7: 159 https://www.frontiersin.org/articles/10.3389/fphar.2016.00159/full cited 2020May10 [Internet]
  • 7 Olson MC, Reeder SB, Venkatesh SK. Quantitative MRI biomarkers of diffuse liver disease. Adv Clin Radiol. 2019; 1: 55-69
  • 8 Curtis WA, Fraum TJ, An H, Chen Y, Shetty AS, Fowler KJ. Quantitative MRI of diffuse liver disease: current applications and future directions. Radiology 2019; 290 (01) 23-30
  • 9 Bannas P, Kramer H, Hernando D. et al. Quantitative magnetic resonance imaging of hepatic steatosis: validation in ex vivo human livers. Hepatology 2015; 62 (05) 1444-1455
  • 10 Rutherford RA, Pullan BR, Isherwood I. Measurement of effective atomic number and electron density using an EMI scanner. Neuroradiology 1976; 11 (01) 15-21
  • 11 Kruger RA, Riederer SJ, Mistretta CA. Relative properties of tomography, K-edge imaging, and K-edge tomography. Med Phys 1977; 4 (03) 244-249
  • 12 Lamb P, Sahani DV, Fuentes-Orrego JM, Patino M, Ghosh A, Mendonça PRS. Stratification of patients with liver fibrosis using dual-energy CT. IEEE Trans Med Imaging 2015; 34 (03) 807-815
  • 13 McCollough CH, Leng S, Yu L, Fletcher JG. Dual- and multi-energy CT: principles, technical approaches, and clinical applications. Radiology 2015; 276 (03) 637-653
  • 14 Patino M, Prochowski A, Agrawal MD. et al. Material separation using dual-energy CT: current and emerging applications. Radiographics 2016; 36 (04) 1087-1105
  • 15 Wilkins T, Tadkod A, Hepburn I, Schade RR. Nonalcoholic fatty liver disease: diagnosis and management. Am Fam Physician 2013; 88 (01) 35-42
  • 16 Fuster D, Samet JH. Alcohol use in patients with chronic liver disease. N Engl J Med 2018; 379 (13) 1251-1261
  • 17 Abenavoli L, Masarone M, Peta V. et al. Insulin resistance and liver steatosis in chronic hepatitis C infection genotype 3. World J Gastroenterol 2014; 20 (41) 15233-15240
  • 18 Shigefuku R, Takahashi H, Nakano H. et al. Correlations of hepatic hemodynamics, liver function, and fibrosis markers in nonalcoholic fatty liver disease: comparison with chronic hepatitis related to hepatitis C virus. Int J Mol Sci 2016; 17 (09) E1545 https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5037819/ cited 2021Jun13 [Internet]
  • 19 Satapathy SK, Kuwajima V, Nadelson J, Atiq O, Sanyal AJ. Drug-induced fatty liver disease: an overview of pathogenesis and management. Ann Hepatol 2015; 14 (06) 789-806
  • 20 Ogawa Y, Murata Y, Nishioka A, Inomata T, Yoshida S. Tamoxifen-induced fatty liver in patients with breast cancer. Lancet 1998; 351 (9104): 725
  • 21 Wakatsuki A, Ogawa Y, Saibara T, Okatani Y, Fukaya T. Size and oxidative susceptibility of low-density lipoprotein particles in breast cancer patients with tamoxifen-induced fatty liver. 6
  • 22 Woods CP, Hazlehurst JM, Tomlinson JW. Glucocorticoids and non-alcoholic fatty liver disease. J Steroid Biochem Mol Biol 2015; 154: 94-103
  • 23 Younossi ZM, Koenig AB, Abdelatif D, Fazel Y, Henry L, Wymer M. Global epidemiology of nonalcoholic fatty liver disease-Meta-analytic assessment of prevalence, incidence, and outcomes. Hepatology 2016; 64 (01) 73-84
  • 24 Marchesini G, Bugianesi E, Forlani G. et al. Nonalcoholic fatty liver, steatohepatitis, and the metabolic syndrome. Hepatology 2003; 37 (04) 917-923
  • 25 Alberti KGMM, Eckel RH, Grundy SM. et al; International Diabetes Federation Task Force on Epidemiology and Prevention, Hational Heart, Lung, and Blood Institute, American Heart Association, World Heart Federation, International Atherosclerosis Society, International Association for the Study of Obesity. Harmonizing the metabolic syndrome: a joint interim statement of the International Diabetes Federation Task Force on Epidemiology and Prevention; National Heart, Lung, and Blood Institute; American Heart Association; World Heart Federation; International Atherosclerosis Society; and International Association for the Study of Obesity. Circulation 2009; 120 (16) 1640-1645
  • 26 Caldwell SH, Crespo DM. The spectrum expanded: cryptogenic cirrhosis and the natural history of non-alcoholic fatty liver disease. J Hepatol 2004; 40 (04) 578-584
  • 27 d'Assignies G, Fayard C, Leitao H. et al. Liver steatosis assessed by preoperative MRI: an independent risk factor for severe complications after major hepatic resection. Surgery 2016; 159 (04) 1050-1057
  • 28 Degasperi E, Colombo M. Distinctive features of hepatocellular carcinoma in non-alcoholic fatty liver disease. Lancet Gastroenterol Hepatol 2016; 1 (02) 156-164
  • 29 Majumdar A, Verbeek J, Tsochatzis EA. Non-alcoholic fatty liver disease: Current therapeutic options. Curr Opin Pharmacol 2021; 61: 98-105
  • 30 Ferraioli G, Soares Monteiro LB. Ultrasound-based techniques for the diagnosis of liver steatosis. World J Gastroenterol 2019; 25 (40) 6053-6062
  • 31 Kramer H, Pickhardt PJ, Kliewer MA. et al. Accuracy of liver fat quantification with advanced CT, MRI, and ultrasound techniques: prospective comparison with MR spectroscopy. Am J Roentgenol 2017; 208 (01) 92-100
  • 32 Reeder SB, Hu HH, Sirlin CB. Proton density fat-fraction: a standardized MR-based biomarker of tissue fat concentration. J Magn Reson Imaging 2012; 36 (05) 1011-1014
  • 33 Petta S, Maida M, Macaluso FS. et al. The severity of steatosis influences liver stiffness measurement in patients with nonalcoholic fatty liver disease. Hepatology 2015; 62 (04) 1101-1110
  • 34 Sasso M, Miette V, Sandrin L, Beaugrand M. The controlled attenuation parameter (CAP): a novel tool for the non-invasive evaluation of steatosis using Fibroscan. Clin Res Hepatol Gastroenterol 2012; 36 (01) 13-20
  • 35 Kumar M, Rastogi A, Singh T. et al. Controlled attenuation parameter for non-invasive assessment of hepatic steatosis: does etiology affect performance?. J Gastroenterol Hepatol 2013; 28 (07) 1194-1201
  • 36 Zhang YN, Fowler KJ, Hamilton G. et al. Liver fat imaging-a clinical overview of ultrasound, CT, and MR imaging. Br J Radiol 2018; 91 (1089): 20170959
  • 37 Li Q, Dhyani M, Grajo JR, Sirlin C, Samir AE. Current status of imaging in nonalcoholic fatty liver disease. World J Hepatol 2018; 10 (08) 530-542
  • 38 Sagir Kahraman A, Karakas HM, Kirimlioglu H, Kahraman B, Yilmaz S, Kirimlioglu V. The assessment of hepatosteatosis in living-donor liver transplant: comparison of liver attenuation index and histopathologic results. Exp Clin Transplant 2017; 15 (01) 69-77
  • 39 Park SH, Kim PN, Kim KW. et al. Macrovesicular hepatic steatosis in living liver donors: use of CT for quantitative and qualitative assessment. Radiology 2006; 239 (01) 105-112
  • 40 Lee SW, Park SH, Kim KW. et al. Unenhanced CT for assessment of macrovesicular hepatic steatosis in living liver donors: comparison of visual grading with liver attenuation index. Radiology 2007; 244 (02) 479-485
  • 41 Iwasaki M, Takada Y, Hayashi M. et al. Noninvasive evaluation of graft steatosis in living donor liver transplantation. Transplantation 2004; 78 (10) 1501-1505
  • 42 Bohte AE, van Werven JR, Bipat S, Stoker J. The diagnostic accuracy of US, CT, MRI and 1H-MRS for the evaluation of hepatic steatosis compared with liver biopsy: a meta-analysis. Eur Radiol 2011; 21 (01) 87-97
  • 43 Mendler MH, Bouillet P, Le Sidaner A. et al. Dual-energy CT in the diagnosis and quantification of fatty liver: limited clinical value in comparison to ultrasound scan and single-energy CT, with special reference to iron overload. J Hepatol 1998; 28 (05) 785-794
  • 44 Hyodo T, Yada N, Hori M. et al. Multimaterial decomposition algorithm for the quantification of liver fat content by using fast-kilovolt-peak switching dual-energy CT: clinical evaluation. Radiology 2017; 283 (01) 108-118
  • 45 Corrias G, Erta M, Sini M. et al. Comparison of multimaterial decomposition fat fraction with DECT and proton density fat fraction with IDEAL IQ MRI for quantification of liver steatosis in a population exposed to chemotherapy. Dose Response 2021; 19 (02) 1559325820984938
  • 46 Patel BN, Kumbla RA, Berland LL, Fineberg NS, Morgan DE. Material density hepatic steatosis quantification on intravenous contrast-enhanced rapid kilovolt (peak)-switching single-source dual-energy computed tomography. J Comput Assist Tomogr 2013; 37 (06) 904-910
  • 47 Artz NS, Hines CDG, Brunner ST. et al. Quantification of hepatic steatosis with dual-energy computed tomography: comparison with tissue reference standards and quantitative magnetic resonance imaging in the ob/ob mouse. Invest Radiol 2012; 47 (10) 603-610
  • 48 Sun T, Lin X, Chen K. Evaluation of hepatic steatosis using dual-energy CT with MR comparison. Front Biosci 2014; 19: 1377-1385
  • 49 Hur BY, Lee JM, Hyunsik W. et al. Quantification of the fat fraction in the liver using dual-energy computed tomography and multimaterial decomposition. J Comput Assist Tomogr 2014; 38 (06) 845-852
  • 50 Noh H, Song X, Heo S. et al. Comparative study of ultrasonography, computed tomography, magnetic resonance imaging, and magnetic resonance spectroscopy for the diagnosis of fatty liver in a rat model. J Korean Soc Radiol 2017; 76: 14
  • 51 Wang Q, Shi G, Qi X, Fan X, Wang L. Quantitative analysis of the dual-energy CT virtual spectral curve for focal liver lesions characterization. Eur J Radiol 2014; 83 (10) 1759-1764
  • 52 Ma J, Song Z-Q, Yan F-H. Separation of hepatic iron and fat by dual-source dual-energy computed tomography based on material decomposition: an animal study. PLoS One 2014; 9 (10) e110964
  • 53 Cao Q, Shang S, Han X, Cao D, Zhao L. Evaluation on heterogeneity of fatty liver in rats: a multiparameter quantitative analysis by dual energy CT. Acad Radiol 2019; 26 (05) e47-e55
  • 54 Toepker M, Moritz T, Krauss B. et al. Virtual non-contrast in second-generation, dual-energy computed tomography: reliability of attenuation values. Eur J Radiol 2012; 81 (03) e398-e405
  • 55 De Cecco CN, Darnell A, Macías N. et al. Virtual unenhanced images of the abdomen with second-generation dual-source dual-energy computed tomography: image quality and liver lesion detection. Invest Radiol 2013; 48 (01) 1-9
  • 56 De Cecco CN, Buffa V, Fedeli S. et al. Dual energy CT (DECT) of the liver: conventional versus virtual unenhanced images. Eur Radiol 2010; 20 (12) 2870-2875
  • 57 Sahni VA, Shinagare AB, Silverman SG. Virtual unenhanced CT images acquired from dual-energy CT urography: accuracy of attenuation values and variation with contrast material phase. Clin Radiol 2013; 68 (03) 264-271
  • 58 Schuppan D, Afdhal NH. Liver cirrhosis. Lancet 2008; 371 (9615): 838-851
  • 59 Friedman SL. Liver fibrosis – from bench to bedside. J Hepatol 2003; 38 (Suppl. 01) S38-S53
  • 60 Barr RG, Ferraioli G, Palmeri ML. et al. Elastography assessment of liver fibrosis: Society of Radiologists in Ultrasound Consensus Conference Statement. Radiology 2015; 276 (03) 845-861
  • 61 Ferraioli G, Tinelli C, Dal Bello B, Zicchetti M, Filice G, Filice C. Liver Fibrosis Study Group. Accuracy of real-time shear wave elastography for assessing liver fibrosis in chronic hepatitis C: a pilot study. Hepatology 2012; 56 (06) 2125-2133
  • 62 Sandrin L, Fourquet B, Hasquenoph JM. et al. Transient elastography: a new noninvasive method for assessment of hepatic fibrosis. Ultrasound Med Biol 2003; 29 (12) 1705-1713
  • 63 Huwart L, Sempoux C, Vicaut E. et al. Magnetic resonance elastography for the noninvasive staging of liver fibrosis. Gastroenterology 2008; 135 (01) 32-40
  • 64 Guo SL, Su LN, Zhai YN. et al. The clinical value of hepatic extracellular volume fraction using routine multiphasic contrast-enhanced liver CT for staging liver fibrosis. Clin Radiol 2017; 72 (03) 242-246
  • 65 Yoon JH, Lee LM, Klotz E, Jeon JH, Lee KB, Han JK. et al. Estimation of hepatic extracellular volume fraction using multiphasic liver computed tomography for hepatic fibrosis grading. Invest Radiol 2015; 50 (04) 290-296
  • 66 Bandula S, Punwani S, Rosenberg WM. et al. Equilibrium contrast-enhanced CT imaging to evaluate hepatic fibrosis: initial validation by comparison with histopathologic sampling. Radiology 2015; 275 (01) 136-143
  • 67 Zissen MH, Wang ZJ, Yee J, Aslam R, Monto A, Yeh BM. Contrast-enhanced CT quantification of the hepatic fractional extracellular space: correlation with diffuse liver disease severity. Am J Roentgenol 2013; 201 (06) 1204-1210
  • 68 Marri UK, Das P, Shalimar. Kalaivani M, Srivastava DN, Madhusudhan KS. Noninvasive staging of liver fibrosis using 5-minute delayed dual-energy CT: comparison with US elastography and correlation with histologic findings. Radiology 2021; 298 (03) 600-608
  • 69 Lv P, Lin X, Gao J, Chen K. Spectral CT: preliminary studies in the liver cirrhosis. Korean J Radiol 2012; 13 (04) 434-442
  • 70 Fuentes J, Patino M, Hayano K, Andrabi Y, Agrawal M, Sahani D. Detection and stratification of liver fibrosis using dual energy CT (DECT) [Internet]. Scientific papers, Radiological Society of North America 2014 Scientific Assembly and Annual Meeting. 2014 [cited 2018 Dec 2]. Available at: http://archive.rsna.org/2014/14015323.html
  • 71 Sofue K, Tsurusaki M, Mileto A. et al. Dual-energy computed tomography for non-invasive staging of liver fibrosis: Accuracy of iodine density measurements from contrast-enhanced data. Hepatol Res 2018; 48 (12) 1008-1019
  • 72 Hilgard P, Gerken G. Liver cirrhosis as a consequence of iron overload caused by hereditary nonspherocytic hemolytic anemia. World J Gastroenterol 2005; 11 (08) 1241-1244
  • 73 Batts KP. Iron overload syndromes and the liver. Mod Pathol 2007; 20 (01, Suppl 1): S31-S39
  • 74 Abergel A, Ruivard M, Bonny C. [Iron overload and chronic liver diseases]. Rev Prat 2006; 56 (19) 2130-2134
  • 75 Milic S, Mikolasevic I, Orlic L. et al. The Role of Iron and Iron Overload in Chronic Liver Disease. Med Sci Monit 2016; 22: 2144-2151
  • 76 Ganne-Carrié N, Christidis C, Chastang C. et al. Liver iron is predictive of death in alcoholic cirrhosis: a multivariate study of 229 consecutive patients with alcoholic and/or hepatitis C virus cirrhosis: a prospective follow up study. Gut 2000; 46 (02) 277-282
  • 77 Henninger B, Alustiza J, Garbowski M, Gandon Y. Practical guide to quantification of hepatic iron with MRI. Eur Radiol 2020; 30 (01) 383-393
  • 78 Labranche R, Gilbert G, Cerny M. et al. Liver iron quantification with MR imaging: a primer for radiologists. Radiographics 2018; 38 (02) 392-412
  • 79 Joe E, Kim SH, Lee KB. et al. Feasibility and accuracy of dual-source dual-energy CT for noninvasive determination of hepatic iron accumulation. Radiology 2012; 262 (01) 126-135
  • 80 Luo XF, Xie XQ, Cheng S. et al. Dual-energy CT for patients suspected of having liver iron overload: can virtual iron content imaging accurately quantify liver iron content?. Radiology 2015; 277 (01) 95-103
  • 81 Werner S, Krauss B, Haberland U. et al. Dual-energy CT for liver iron quantification in patients with haematological disorders. Eur Radiol 2019; 29 (06) 2868-2877
  • 82 Fischer MA, Reiner CS, Raptis D. et al. Quantification of liver iron content with CT-added value of dual-energy. Eur Radiol 2011; 21 (08) 1727-1732
  • 83 Peng Y, Ye J, Liu C. et al. Simultaneous hepatic iron and fat quantification with dual-energy CT in a rabbit model of coexisting iron and fat. Quant Imaging Med Surg 2021; 11 (05) 2001-2012
  • 84 Fischer MA, Gnannt R, Raptis D. et al. Quantification of liver fat in the presence of iron and iodine: an ex-vivo dual-energy CT study. Invest Radiol 2011; 46 (06) 351-358
  • 85 Hyodo T, Hori M, Lamb P. et al. Multimaterial decomposition algorithm for the quantification of liver fat content by using fast-kilovolt-peak switching dual-energy CT: experimental validation. Radiology 2017; 282 (02) 381-389
  • 86 Xie T, Li Y, He G, Zhang Z, Shi Q, Cheng G. The influence of liver fat deposition on the quantification of the liver-iron fraction using fast-kilovolt-peak switching dual-energy CT imaging and material decomposition technique: an in vitro experimental study. Quant Imaging Med Surg 2019; 9 (04) 654-661
  • 87 Zheng X, Ren Y, Phillips WT. et al. Assessment of hepatic fatty infiltration using spectral computed tomography imaging: a pilot study. J Comput Assist Tomogr 2013; 37 (02) 134-141
  • 88 Basso L, Baldi D, Mannelli L, Cavaliere C, Salvatore M, Brancato V. Investigating dual-energy CT post-contrast phases for liver iron quantification: a preliminary study. Dose Response 2021;19(02):15593258211011359
  • 89 Foley WD, Shuman WP, Siegel MJ. et al. White Paper of the Society of Computed Body Tomography and Magnetic Resonance on Dual-Energy CT, Part 2: radiation dose and iodine sensitivity. J Comput Assist Tomogr 2016; 40 (06) 846-850
  • 90 Purysko AS, Primak AN, Baker ME. 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 (12) e538-e544
  • 91 Kulkarni NM, Pinho DF, Kambadakone AR, Sahani DV. Emerging technologies in CT- radiation dose reduction and dual-energy CT. Semin Roentgenol 2013; 48 (03) 192-202
  • 92 Jepperson MA, Cernigliaro JG, Ibrahim SH, Morin RL, Haley WE, Thiel DD. In vivo comparison of radiation exposure of dual-energy CT versus low-dose CT versus standard CT for imaging urinary calculi. J Endourol 2015; 29 (02) 141-146
  • 93 Henzler T, Fink C, Schoenberg SO, Schoepf UJ. Dual-energy CT: radiation dose aspects. AJR Am J Roentgenol 2012; 199 (5, Suppl) S16-S25
  • 94 Martínez-Esparza M, Tristán-Manzano M, Ruiz-Alcaraz AJ, García-Peñarrubia P. Inflammatory status in human hepatic cirrhosis. World J Gastroenterol 2015; 21 (41) 11522-11541
  • 95 Marra F. Chemokines in liver inflammation and fibrosis. Front Biosci 2002; 7: d1899-d1914
  • 96 Wang HJ, Gao B, Zakhari S, Nagy LE. Inflammation in alcoholic liver disease. Annu Rev Nutr 2012; 32: 343-368
  • 97 Gao B, Tsukamoto H. Inflammation in alcoholic and nonalcoholic fatty liver disease: friend or foe?. Gastroenterology 2016; 150 (08) 1704-1709
  • 98 Yeh MM, Brunt EM. Pathology of nonalcoholic fatty liver disease. Am J Clin Pathol 2007; 128 (05) 837-847
  • 99 Takahashi Y, Fukusato T. Histopathology of nonalcoholic fatty liver disease/nonalcoholic steatohepatitis. World J Gastroenterol 2014; 20 (42) 15539-15548
  • 100 Parthasarathy G, Revelo X, Malhi H. Pathogenesis of nonalcoholic steatohepatitis: an overview. Hepatol Commun 2020; 4 (04) 478-492
  • 101 Schuster S, Cabrera D, Arrese M, Feldstein AE. Triggering and resolution of inflammation in NASH. Nat Rev Gastroenterol Hepatol 2018; 15 (06) 349-364
  • 102 Farrell GC, van Rooyen D, Gan L, Chitturi S. NASH is an inflammatory disorder: pathogenic, prognostic and therapeutic Implications. Gut Liver 2012; 6 (02) 149-171

Address for correspondence

Kumble Seetharama Madhusudhan, MD, FRCR
Department of Radiodiagnosis and Interventional Radiology, All India Institute of Medical Sciences
New Delhi 110029
India   

Publikationsverlauf

Artikel online veröffentlicht:
08. Februar 2022

© 2022. Indian Society of Gastrointestinal and Abdominal Radiology. This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commercial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/)

Thieme Medical and Scientific Publishers Pvt. Ltd.
A-12, 2nd Floor, Sector 2, Noida-201301 UP, India

  • References

  • 1 Hounsfield GN. Computerized transverse axial scanning (tomography). 1. Description of system. Br J Radiol 1973; 46 (552) 1016-1022
  • 2 Flohr TG, McCollough CH, Bruder H. et al. First performance evaluation of a dual-source CT (DSCT) system. Eur Radiol 2006; 16 (02) 256-268
  • 3 Sebastiani G. Non-invasive assessment of liver fibrosis in chronic liver diseases: implementation in clinical practice and decisional algorithms. World J Gastroenterol 2009; 15 (18) 2190-2203
  • 4 Bravo AA, Sheth SG, Chopra S. Liver biopsy. N Engl J Med 2001; 344 (07) 495-500
  • 5 Baranova A, Lal P, Birerdinc A, Younossi ZM. Non-invasive markers for hepatic fibrosis. BMC Gastroenterol 2011; 11: 91
  • 6 Chin JL, Pavlides M, Moolla A, Ryan JD. Non-invasive markers of liver fibrosis: adjuncts or alternatives to liver biopsy?. Front Pharmacol 2016; 7: 159 https://www.frontiersin.org/articles/10.3389/fphar.2016.00159/full cited 2020May10 [Internet]
  • 7 Olson MC, Reeder SB, Venkatesh SK. Quantitative MRI biomarkers of diffuse liver disease. Adv Clin Radiol. 2019; 1: 55-69
  • 8 Curtis WA, Fraum TJ, An H, Chen Y, Shetty AS, Fowler KJ. Quantitative MRI of diffuse liver disease: current applications and future directions. Radiology 2019; 290 (01) 23-30
  • 9 Bannas P, Kramer H, Hernando D. et al. Quantitative magnetic resonance imaging of hepatic steatosis: validation in ex vivo human livers. Hepatology 2015; 62 (05) 1444-1455
  • 10 Rutherford RA, Pullan BR, Isherwood I. Measurement of effective atomic number and electron density using an EMI scanner. Neuroradiology 1976; 11 (01) 15-21
  • 11 Kruger RA, Riederer SJ, Mistretta CA. Relative properties of tomography, K-edge imaging, and K-edge tomography. Med Phys 1977; 4 (03) 244-249
  • 12 Lamb P, Sahani DV, Fuentes-Orrego JM, Patino M, Ghosh A, Mendonça PRS. Stratification of patients with liver fibrosis using dual-energy CT. IEEE Trans Med Imaging 2015; 34 (03) 807-815
  • 13 McCollough CH, Leng S, Yu L, Fletcher JG. Dual- and multi-energy CT: principles, technical approaches, and clinical applications. Radiology 2015; 276 (03) 637-653
  • 14 Patino M, Prochowski A, Agrawal MD. et al. Material separation using dual-energy CT: current and emerging applications. Radiographics 2016; 36 (04) 1087-1105
  • 15 Wilkins T, Tadkod A, Hepburn I, Schade RR. Nonalcoholic fatty liver disease: diagnosis and management. Am Fam Physician 2013; 88 (01) 35-42
  • 16 Fuster D, Samet JH. Alcohol use in patients with chronic liver disease. N Engl J Med 2018; 379 (13) 1251-1261
  • 17 Abenavoli L, Masarone M, Peta V. et al. Insulin resistance and liver steatosis in chronic hepatitis C infection genotype 3. World J Gastroenterol 2014; 20 (41) 15233-15240
  • 18 Shigefuku R, Takahashi H, Nakano H. et al. Correlations of hepatic hemodynamics, liver function, and fibrosis markers in nonalcoholic fatty liver disease: comparison with chronic hepatitis related to hepatitis C virus. Int J Mol Sci 2016; 17 (09) E1545 https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5037819/ cited 2021Jun13 [Internet]
  • 19 Satapathy SK, Kuwajima V, Nadelson J, Atiq O, Sanyal AJ. Drug-induced fatty liver disease: an overview of pathogenesis and management. Ann Hepatol 2015; 14 (06) 789-806
  • 20 Ogawa Y, Murata Y, Nishioka A, Inomata T, Yoshida S. Tamoxifen-induced fatty liver in patients with breast cancer. Lancet 1998; 351 (9104): 725
  • 21 Wakatsuki A, Ogawa Y, Saibara T, Okatani Y, Fukaya T. Size and oxidative susceptibility of low-density lipoprotein particles in breast cancer patients with tamoxifen-induced fatty liver. 6
  • 22 Woods CP, Hazlehurst JM, Tomlinson JW. Glucocorticoids and non-alcoholic fatty liver disease. J Steroid Biochem Mol Biol 2015; 154: 94-103
  • 23 Younossi ZM, Koenig AB, Abdelatif D, Fazel Y, Henry L, Wymer M. Global epidemiology of nonalcoholic fatty liver disease-Meta-analytic assessment of prevalence, incidence, and outcomes. Hepatology 2016; 64 (01) 73-84
  • 24 Marchesini G, Bugianesi E, Forlani G. et al. Nonalcoholic fatty liver, steatohepatitis, and the metabolic syndrome. Hepatology 2003; 37 (04) 917-923
  • 25 Alberti KGMM, Eckel RH, Grundy SM. et al; International Diabetes Federation Task Force on Epidemiology and Prevention, Hational Heart, Lung, and Blood Institute, American Heart Association, World Heart Federation, International Atherosclerosis Society, International Association for the Study of Obesity. Harmonizing the metabolic syndrome: a joint interim statement of the International Diabetes Federation Task Force on Epidemiology and Prevention; National Heart, Lung, and Blood Institute; American Heart Association; World Heart Federation; International Atherosclerosis Society; and International Association for the Study of Obesity. Circulation 2009; 120 (16) 1640-1645
  • 26 Caldwell SH, Crespo DM. The spectrum expanded: cryptogenic cirrhosis and the natural history of non-alcoholic fatty liver disease. J Hepatol 2004; 40 (04) 578-584
  • 27 d'Assignies G, Fayard C, Leitao H. et al. Liver steatosis assessed by preoperative MRI: an independent risk factor for severe complications after major hepatic resection. Surgery 2016; 159 (04) 1050-1057
  • 28 Degasperi E, Colombo M. Distinctive features of hepatocellular carcinoma in non-alcoholic fatty liver disease. Lancet Gastroenterol Hepatol 2016; 1 (02) 156-164
  • 29 Majumdar A, Verbeek J, Tsochatzis EA. Non-alcoholic fatty liver disease: Current therapeutic options. Curr Opin Pharmacol 2021; 61: 98-105
  • 30 Ferraioli G, Soares Monteiro LB. Ultrasound-based techniques for the diagnosis of liver steatosis. World J Gastroenterol 2019; 25 (40) 6053-6062
  • 31 Kramer H, Pickhardt PJ, Kliewer MA. et al. Accuracy of liver fat quantification with advanced CT, MRI, and ultrasound techniques: prospective comparison with MR spectroscopy. Am J Roentgenol 2017; 208 (01) 92-100
  • 32 Reeder SB, Hu HH, Sirlin CB. Proton density fat-fraction: a standardized MR-based biomarker of tissue fat concentration. J Magn Reson Imaging 2012; 36 (05) 1011-1014
  • 33 Petta S, Maida M, Macaluso FS. et al. The severity of steatosis influences liver stiffness measurement in patients with nonalcoholic fatty liver disease. Hepatology 2015; 62 (04) 1101-1110
  • 34 Sasso M, Miette V, Sandrin L, Beaugrand M. The controlled attenuation parameter (CAP): a novel tool for the non-invasive evaluation of steatosis using Fibroscan. Clin Res Hepatol Gastroenterol 2012; 36 (01) 13-20
  • 35 Kumar M, Rastogi A, Singh T. et al. Controlled attenuation parameter for non-invasive assessment of hepatic steatosis: does etiology affect performance?. J Gastroenterol Hepatol 2013; 28 (07) 1194-1201
  • 36 Zhang YN, Fowler KJ, Hamilton G. et al. Liver fat imaging-a clinical overview of ultrasound, CT, and MR imaging. Br J Radiol 2018; 91 (1089): 20170959
  • 37 Li Q, Dhyani M, Grajo JR, Sirlin C, Samir AE. Current status of imaging in nonalcoholic fatty liver disease. World J Hepatol 2018; 10 (08) 530-542
  • 38 Sagir Kahraman A, Karakas HM, Kirimlioglu H, Kahraman B, Yilmaz S, Kirimlioglu V. The assessment of hepatosteatosis in living-donor liver transplant: comparison of liver attenuation index and histopathologic results. Exp Clin Transplant 2017; 15 (01) 69-77
  • 39 Park SH, Kim PN, Kim KW. et al. Macrovesicular hepatic steatosis in living liver donors: use of CT for quantitative and qualitative assessment. Radiology 2006; 239 (01) 105-112
  • 40 Lee SW, Park SH, Kim KW. et al. Unenhanced CT for assessment of macrovesicular hepatic steatosis in living liver donors: comparison of visual grading with liver attenuation index. Radiology 2007; 244 (02) 479-485
  • 41 Iwasaki M, Takada Y, Hayashi M. et al. Noninvasive evaluation of graft steatosis in living donor liver transplantation. Transplantation 2004; 78 (10) 1501-1505
  • 42 Bohte AE, van Werven JR, Bipat S, Stoker J. The diagnostic accuracy of US, CT, MRI and 1H-MRS for the evaluation of hepatic steatosis compared with liver biopsy: a meta-analysis. Eur Radiol 2011; 21 (01) 87-97
  • 43 Mendler MH, Bouillet P, Le Sidaner A. et al. Dual-energy CT in the diagnosis and quantification of fatty liver: limited clinical value in comparison to ultrasound scan and single-energy CT, with special reference to iron overload. J Hepatol 1998; 28 (05) 785-794
  • 44 Hyodo T, Yada N, Hori M. et al. Multimaterial decomposition algorithm for the quantification of liver fat content by using fast-kilovolt-peak switching dual-energy CT: clinical evaluation. Radiology 2017; 283 (01) 108-118
  • 45 Corrias G, Erta M, Sini M. et al. Comparison of multimaterial decomposition fat fraction with DECT and proton density fat fraction with IDEAL IQ MRI for quantification of liver steatosis in a population exposed to chemotherapy. Dose Response 2021; 19 (02) 1559325820984938
  • 46 Patel BN, Kumbla RA, Berland LL, Fineberg NS, Morgan DE. Material density hepatic steatosis quantification on intravenous contrast-enhanced rapid kilovolt (peak)-switching single-source dual-energy computed tomography. J Comput Assist Tomogr 2013; 37 (06) 904-910
  • 47 Artz NS, Hines CDG, Brunner ST. et al. Quantification of hepatic steatosis with dual-energy computed tomography: comparison with tissue reference standards and quantitative magnetic resonance imaging in the ob/ob mouse. Invest Radiol 2012; 47 (10) 603-610
  • 48 Sun T, Lin X, Chen K. Evaluation of hepatic steatosis using dual-energy CT with MR comparison. Front Biosci 2014; 19: 1377-1385
  • 49 Hur BY, Lee JM, Hyunsik W. et al. Quantification of the fat fraction in the liver using dual-energy computed tomography and multimaterial decomposition. J Comput Assist Tomogr 2014; 38 (06) 845-852
  • 50 Noh H, Song X, Heo S. et al. Comparative study of ultrasonography, computed tomography, magnetic resonance imaging, and magnetic resonance spectroscopy for the diagnosis of fatty liver in a rat model. J Korean Soc Radiol 2017; 76: 14
  • 51 Wang Q, Shi G, Qi X, Fan X, Wang L. Quantitative analysis of the dual-energy CT virtual spectral curve for focal liver lesions characterization. Eur J Radiol 2014; 83 (10) 1759-1764
  • 52 Ma J, Song Z-Q, Yan F-H. Separation of hepatic iron and fat by dual-source dual-energy computed tomography based on material decomposition: an animal study. PLoS One 2014; 9 (10) e110964
  • 53 Cao Q, Shang S, Han X, Cao D, Zhao L. Evaluation on heterogeneity of fatty liver in rats: a multiparameter quantitative analysis by dual energy CT. Acad Radiol 2019; 26 (05) e47-e55
  • 54 Toepker M, Moritz T, Krauss B. et al. Virtual non-contrast in second-generation, dual-energy computed tomography: reliability of attenuation values. Eur J Radiol 2012; 81 (03) e398-e405
  • 55 De Cecco CN, Darnell A, Macías N. et al. Virtual unenhanced images of the abdomen with second-generation dual-source dual-energy computed tomography: image quality and liver lesion detection. Invest Radiol 2013; 48 (01) 1-9
  • 56 De Cecco CN, Buffa V, Fedeli S. et al. Dual energy CT (DECT) of the liver: conventional versus virtual unenhanced images. Eur Radiol 2010; 20 (12) 2870-2875
  • 57 Sahni VA, Shinagare AB, Silverman SG. Virtual unenhanced CT images acquired from dual-energy CT urography: accuracy of attenuation values and variation with contrast material phase. Clin Radiol 2013; 68 (03) 264-271
  • 58 Schuppan D, Afdhal NH. Liver cirrhosis. Lancet 2008; 371 (9615): 838-851
  • 59 Friedman SL. Liver fibrosis – from bench to bedside. J Hepatol 2003; 38 (Suppl. 01) S38-S53
  • 60 Barr RG, Ferraioli G, Palmeri ML. et al. Elastography assessment of liver fibrosis: Society of Radiologists in Ultrasound Consensus Conference Statement. Radiology 2015; 276 (03) 845-861
  • 61 Ferraioli G, Tinelli C, Dal Bello B, Zicchetti M, Filice G, Filice C. Liver Fibrosis Study Group. Accuracy of real-time shear wave elastography for assessing liver fibrosis in chronic hepatitis C: a pilot study. Hepatology 2012; 56 (06) 2125-2133
  • 62 Sandrin L, Fourquet B, Hasquenoph JM. et al. Transient elastography: a new noninvasive method for assessment of hepatic fibrosis. Ultrasound Med Biol 2003; 29 (12) 1705-1713
  • 63 Huwart L, Sempoux C, Vicaut E. et al. Magnetic resonance elastography for the noninvasive staging of liver fibrosis. Gastroenterology 2008; 135 (01) 32-40
  • 64 Guo SL, Su LN, Zhai YN. et al. The clinical value of hepatic extracellular volume fraction using routine multiphasic contrast-enhanced liver CT for staging liver fibrosis. Clin Radiol 2017; 72 (03) 242-246
  • 65 Yoon JH, Lee LM, Klotz E, Jeon JH, Lee KB, Han JK. et al. Estimation of hepatic extracellular volume fraction using multiphasic liver computed tomography for hepatic fibrosis grading. Invest Radiol 2015; 50 (04) 290-296
  • 66 Bandula S, Punwani S, Rosenberg WM. et al. Equilibrium contrast-enhanced CT imaging to evaluate hepatic fibrosis: initial validation by comparison with histopathologic sampling. Radiology 2015; 275 (01) 136-143
  • 67 Zissen MH, Wang ZJ, Yee J, Aslam R, Monto A, Yeh BM. Contrast-enhanced CT quantification of the hepatic fractional extracellular space: correlation with diffuse liver disease severity. Am J Roentgenol 2013; 201 (06) 1204-1210
  • 68 Marri UK, Das P, Shalimar. Kalaivani M, Srivastava DN, Madhusudhan KS. Noninvasive staging of liver fibrosis using 5-minute delayed dual-energy CT: comparison with US elastography and correlation with histologic findings. Radiology 2021; 298 (03) 600-608
  • 69 Lv P, Lin X, Gao J, Chen K. Spectral CT: preliminary studies in the liver cirrhosis. Korean J Radiol 2012; 13 (04) 434-442
  • 70 Fuentes J, Patino M, Hayano K, Andrabi Y, Agrawal M, Sahani D. Detection and stratification of liver fibrosis using dual energy CT (DECT) [Internet]. Scientific papers, Radiological Society of North America 2014 Scientific Assembly and Annual Meeting. 2014 [cited 2018 Dec 2]. Available at: http://archive.rsna.org/2014/14015323.html
  • 71 Sofue K, Tsurusaki M, Mileto A. et al. Dual-energy computed tomography for non-invasive staging of liver fibrosis: Accuracy of iodine density measurements from contrast-enhanced data. Hepatol Res 2018; 48 (12) 1008-1019
  • 72 Hilgard P, Gerken G. Liver cirrhosis as a consequence of iron overload caused by hereditary nonspherocytic hemolytic anemia. World J Gastroenterol 2005; 11 (08) 1241-1244
  • 73 Batts KP. Iron overload syndromes and the liver. Mod Pathol 2007; 20 (01, Suppl 1): S31-S39
  • 74 Abergel A, Ruivard M, Bonny C. [Iron overload and chronic liver diseases]. Rev Prat 2006; 56 (19) 2130-2134
  • 75 Milic S, Mikolasevic I, Orlic L. et al. The Role of Iron and Iron Overload in Chronic Liver Disease. Med Sci Monit 2016; 22: 2144-2151
  • 76 Ganne-Carrié N, Christidis C, Chastang C. et al. Liver iron is predictive of death in alcoholic cirrhosis: a multivariate study of 229 consecutive patients with alcoholic and/or hepatitis C virus cirrhosis: a prospective follow up study. Gut 2000; 46 (02) 277-282
  • 77 Henninger B, Alustiza J, Garbowski M, Gandon Y. Practical guide to quantification of hepatic iron with MRI. Eur Radiol 2020; 30 (01) 383-393
  • 78 Labranche R, Gilbert G, Cerny M. et al. Liver iron quantification with MR imaging: a primer for radiologists. Radiographics 2018; 38 (02) 392-412
  • 79 Joe E, Kim SH, Lee KB. et al. Feasibility and accuracy of dual-source dual-energy CT for noninvasive determination of hepatic iron accumulation. Radiology 2012; 262 (01) 126-135
  • 80 Luo XF, Xie XQ, Cheng S. et al. Dual-energy CT for patients suspected of having liver iron overload: can virtual iron content imaging accurately quantify liver iron content?. Radiology 2015; 277 (01) 95-103
  • 81 Werner S, Krauss B, Haberland U. et al. Dual-energy CT for liver iron quantification in patients with haematological disorders. Eur Radiol 2019; 29 (06) 2868-2877
  • 82 Fischer MA, Reiner CS, Raptis D. et al. Quantification of liver iron content with CT-added value of dual-energy. Eur Radiol 2011; 21 (08) 1727-1732
  • 83 Peng Y, Ye J, Liu C. et al. Simultaneous hepatic iron and fat quantification with dual-energy CT in a rabbit model of coexisting iron and fat. Quant Imaging Med Surg 2021; 11 (05) 2001-2012
  • 84 Fischer MA, Gnannt R, Raptis D. et al. Quantification of liver fat in the presence of iron and iodine: an ex-vivo dual-energy CT study. Invest Radiol 2011; 46 (06) 351-358
  • 85 Hyodo T, Hori M, Lamb P. et al. Multimaterial decomposition algorithm for the quantification of liver fat content by using fast-kilovolt-peak switching dual-energy CT: experimental validation. Radiology 2017; 282 (02) 381-389
  • 86 Xie T, Li Y, He G, Zhang Z, Shi Q, Cheng G. The influence of liver fat deposition on the quantification of the liver-iron fraction using fast-kilovolt-peak switching dual-energy CT imaging and material decomposition technique: an in vitro experimental study. Quant Imaging Med Surg 2019; 9 (04) 654-661
  • 87 Zheng X, Ren Y, Phillips WT. et al. Assessment of hepatic fatty infiltration using spectral computed tomography imaging: a pilot study. J Comput Assist Tomogr 2013; 37 (02) 134-141
  • 88 Basso L, Baldi D, Mannelli L, Cavaliere C, Salvatore M, Brancato V. Investigating dual-energy CT post-contrast phases for liver iron quantification: a preliminary study. Dose Response 2021;19(02):15593258211011359
  • 89 Foley WD, Shuman WP, Siegel MJ. et al. White Paper of the Society of Computed Body Tomography and Magnetic Resonance on Dual-Energy CT, Part 2: radiation dose and iodine sensitivity. J Comput Assist Tomogr 2016; 40 (06) 846-850
  • 90 Purysko AS, Primak AN, Baker ME. 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 (12) e538-e544
  • 91 Kulkarni NM, Pinho DF, Kambadakone AR, Sahani DV. Emerging technologies in CT- radiation dose reduction and dual-energy CT. Semin Roentgenol 2013; 48 (03) 192-202
  • 92 Jepperson MA, Cernigliaro JG, Ibrahim SH, Morin RL, Haley WE, Thiel DD. In vivo comparison of radiation exposure of dual-energy CT versus low-dose CT versus standard CT for imaging urinary calculi. J Endourol 2015; 29 (02) 141-146
  • 93 Henzler T, Fink C, Schoenberg SO, Schoepf UJ. Dual-energy CT: radiation dose aspects. AJR Am J Roentgenol 2012; 199 (5, Suppl) S16-S25
  • 94 Martínez-Esparza M, Tristán-Manzano M, Ruiz-Alcaraz AJ, García-Peñarrubia P. Inflammatory status in human hepatic cirrhosis. World J Gastroenterol 2015; 21 (41) 11522-11541
  • 95 Marra F. Chemokines in liver inflammation and fibrosis. Front Biosci 2002; 7: d1899-d1914
  • 96 Wang HJ, Gao B, Zakhari S, Nagy LE. Inflammation in alcoholic liver disease. Annu Rev Nutr 2012; 32: 343-368
  • 97 Gao B, Tsukamoto H. Inflammation in alcoholic and nonalcoholic fatty liver disease: friend or foe?. Gastroenterology 2016; 150 (08) 1704-1709
  • 98 Yeh MM, Brunt EM. Pathology of nonalcoholic fatty liver disease. Am J Clin Pathol 2007; 128 (05) 837-847
  • 99 Takahashi Y, Fukusato T. Histopathology of nonalcoholic fatty liver disease/nonalcoholic steatohepatitis. World J Gastroenterol 2014; 20 (42) 15539-15548
  • 100 Parthasarathy G, Revelo X, Malhi H. Pathogenesis of nonalcoholic steatohepatitis: an overview. Hepatol Commun 2020; 4 (04) 478-492
  • 101 Schuster S, Cabrera D, Arrese M, Feldstein AE. Triggering and resolution of inflammation in NASH. Nat Rev Gastroenterol Hepatol 2018; 15 (06) 349-364
  • 102 Farrell GC, van Rooyen D, Gan L, Chitturi S. NASH is an inflammatory disorder: pathogenic, prognostic and therapeutic Implications. Gut Liver 2012; 6 (02) 149-171

Zoom Image
Fig. 1 Principle of dual-energy CT material decomposition algorithm to identify and quantify different materials. The graph shows a change in mass attenuation coefficients of iodine, bone (calcium), and fat at a wide range of X-ray energies. At specific X-ray energy, mass attenuation coefficient (linear attenuation coefficient/density) is only dependent on the effective atomic number of the medium. A difference in this coefficient at two different energy X-rays (for example 80 kVp and 140 kVp as shown in the graph) depends on the effective atomic number of the medium and not the medium density.
Zoom Image
Fig. 2 Overview of dual-source dual-energy computed tomography (DECT) post-processing software (Syngo.via, version VB10B, 2016; Siemens Healthineers). Based on the material being evaluated, an appropriate application profile (in the left upper corner box) is chosen. Liver virtual non-contrast (VNC) is selected in this image to measure liver iodine concentration on the delayed phase DECT, for fibrosis quantification. The region of interest placed on the axial image shows various parameters including Iodine density and fat fraction in that region. The same application can be used for liver fat quantification. Color-coded iodine maps are seen in three different planes.
Zoom Image
Fig. 3 Measurement of hepatic fat content on dual-source dual-energy computed tomography. (A, B) Axial virtual non-contrast (VNC) image of a patient (A) with normal liver parenchyma with two circular regions of interest (ROIs) drawn on the liver show close to zero fat fraction and corresponding color-coded fat map (B) shows almost no fat in the liver parenchyma. (C, D) Axial VNC image (C) of another patient with non-alcoholic fatty liver disease with two ROIs show 20% of fat fraction and corresponding color-coded fat map (D) shows the distribution of fat in the liver parenchyma.
Zoom Image
Fig. 4 Measurement of hepatic fat content on rapid switching dual-energy computed tomography. (A) Axial, contrast-enhanced image of the patient with fatty liver. (B) Virtual unenhanced image at the same level with two circular regions of interest. Mean attenuation was 32 HU and fat fraction was 15.5%. (C) The corresponding color-coded fat map shows the distribution of fat in the liver parenchyma.
Zoom Image
Fig. 5 Assessment of hepatic fibrosis on dual-source dual-energy computed tomography (DECT) in a 40-year-old man with chronic hepatitis B cirrhosis. (A) Axial 5-minute delayed phase DECT image with circular regions of interest (ROIs) in both lobes of the liver. Normalized iodine concentration (NIC) in the right and left lobes were 0.571 and 0.539, respectively. (B) The iodine map of the delayed phase shows heterogeneous iodine uptake in the liver. (C) Histology of the biopsy sample showed a METAVIR stage of F4. The NIC values were consistent with cut-offs suggested by a recent study by Marri et al.
Zoom Image
Fig. 6 Assessment of hepatic fibrosis on rapid switching dual-energy computed tomography (DECT) in a 46-year-old man with alcoholic cirrhosis. (A) Axial 5-minute delayed-phase DECT image with circular regions of interest (ROIs) in both lobes of the liver. Normalized iodine concentration in the right and left lobes were 0.490 and 0.513, respectively, suggesting a stage of F4, according to Marri et al. (B) Iodine map from the delayed phase shows heterogeneous iodine uptake in the liver.
Zoom Image
Fig. 7 Assessment of liver iron content on dual-source dual-energy computed tomography in a 19-year-old male patient with β thalassemia. (A, B) Axial high energy (A, 140 kVp) and low energy (B, 80 kVp) non-contrast images show a mean difference in attenuation of liver between the two energies (ΔHU) of 14.1 HU, suggesting iron deposition. (C) Axial multi-echo gradient MR images from a 3T machine show a gradual decrease in liver signal with an increase in TE. The T2* value was 10.3 milliseconds and R2* was 163/s suggestive of moderate iron deposition.