Diagnostic performance of apparent diffusion coefficient values for the differentiation of intrahepatic cholangiocarcinoma from gastrointestinal adenocarcinoma liver metastases

Intrahepatic cholangiocarcinoma (IHCC) is the second most common primary malignant lesion of the liver after hepatocellular cancer and estimated 15% of primary liver cancer worldwide. The incidence of IHCC has been increasing recently.¹ According to macroscopic appearance, cholangiocarcinoma (CC) is divided into three types: mass forming type, periductal infiltrative type and intraductal growing type.^1-2 Mass forming type CC is the most common type with a rate of 60%.³ Diffusion weighted image (DWI) usually is added to standard abdomen protocols, because it is a rapid technique and talented of detecting most liver masses in patients with supposed malignant disease. It may be difficult to differentiate between IHCC and gastrointestinal system (GIS)-derived adenocarcinoma even when contrast is given, and DWI can be helpful in differential diagnosis in these cases.⁴

DWI provides diagnostic value in differentiation of benign and malignant liver masses. It gives information about cellularity of tissues and integrity of cell membranes. DWI increases the sensitivity of detection for liver metastases when combined with dynamic contrast enhanced upper abdomen MRI. DWI has been used in characterization of metastatic and primary liver tumors.⁵ The sensitivity of using DWI in addition to routine imaging in detecting malignancy was reported as 94.9% and the specificity as 97.8%.⁶ To avoid unnecessary diagnostic and therapeutic interventions, differentiation between IHCC and metastases of adenocarcinomas is very significant, because they have different treatment options and prognosis. It would be valuable to precisely differentiate the liver metastases of GIS from IHCC based on apparent diffusion coefficient (ADC) values. Because it’s sometimes hard to differentiate even based on the histological analysis since all these tumors are adenocarcinomas. We aimed to investigate whether there is a difference between IHCC’s and adenocarcinoma liver metastases from GIS origin in terms of ADC values.

The goal of this study was to evaluate the value of DWI, using the mean ADC value for distinguishing IHCC from liver metastases of adenocarcinomas originating in the gastrointestinal tract.

IHCC was diagnosed in 10 patients with 10 lesions and adenocarcinoma was diagnosed in 53 patients with 53 liver metastases. There was no statistically significant difference between IHCC and adenocarcinoma in terms of age. Demographic features were summarized at Table 1.

ADC_mean values were significantly higher in the IHCC group compared to the adenocarcinoma group (p < 0.001) (Figure 4). These results are summarized in Table 2.

Figure 4

ROC curves method showed diagnostic accuracy for ADC_mean (AUC = 0.879). Cut-off value was < 1178 x 10^-6 mm²/s for ADC_mean (Sensitivity = 90.57%, Specificity = 70.0%, positive predictive value [PPV] = 94.1, negative predictive value [NPV] = 58.3) in differentiating adenocarcinoma metastases from IHCC’s with the 95% confidence interval (Figure 5). The AUC rates showed that ADC_mean values were statistically significant in differentiating the two groups (p < 0.0001).

Figure 5

Gastrointestinal cancer is from the most common malignant tumors worldwide with rising incidence.⁷ Surgery is now the primary treatment for gastrointestinal cancer. Liver metastasis occurs in approximately 45% of patients.⁸

IHCC originates from small intrahepatic bile ducts and grows through adjacent liver parenchyma. IHCC typically occurs as a large mass, which is difficult to differentiate from a metastatic focus of adenocarcinoma. The only curative treatment of IHCC is surgery and even with surgery its 5-year survival rates remain at 39–41%.⁹ In contrast there is no surgical treatment option for some metastatic GIS tumors.¹⁰

IHCC is hypointense on T1-weighted (T1W), and hyperintense on T2W imaging relative to liver parenchyma. The grade of hyperintensity on T2W imaging frequently depends on the quantity of fibrosis, necrosis, and mucin within the tumor.¹¹ The imaging features of IHCC have been further described, with the targetoid appearance being one of the most common characteristics.¹²

Magnetic resonance (MR) DWI is a technique that provides image contrast by free water molecule movement within tissue and the ADC (expressed in mm2/s), is a numerical parameter of DWI. ADC values give information about cellularity of tissues and integrity of cell membranes.¹² Biopsy is required before surgical or oncological treatment in cases where IHCC is considered by imaging.

It is sometimes difficult to distinguish liver metastases from IHCC with routine abdominal MRI. It is not possible to differentiate especially in solitary or hypovascular metastases. DWI must be added to routine abdominal MR imaging since it is very sensitive to detect liver malignancies. ADC is a measure of the magnitude of diffusion within tissue and is commonly clinically calculated using DWI. ADC values reflect the structure of masses and vary in different tumor types. Lower ADC values may reflect the hypercellularity of these tumors, and decreased intra and extracellular space.

Mungai et al. reported mean ADC values of CC as 0.970 x 10^-3mm/sn² and metastases as 0.947 x 10^-3mm²/sn and these results were not statistically significant.⁴ This may be a result of evaluation of metastases arising from any origin and the evaluation of all subtypes of CC. In our study we have found median ADC value of IHCC 1293 x 10^-6mm²/ sn and mean ADC value of metastases of GIS 861 x 10^-6mm²/sn and this was statistically significant (p < 0.0001). Decreased ADC values in GIS liver metastases may be attributed to hypercellularity. However increased ADC values in IHCC may be the result of decreased cellularity due to fibrotic changes compared to metastases.

Drevelegas et al. demonstrated that mean ADC value in 12 patients with liver CC was 1.34 ± 0.27 x 10^-3mm²/s and 1.11 ± 0.295 x 10^-3mm²/s in 51 patients with secondary liver malignancy.¹³ They only concluded that primary liver tumors have higher ADC values than secondary ones. The result of this study supports our outcomes.

Namimoto et al. found the mean ADC value of 1.51 ± 0.47 x 10^-3mm²/s in IHCC and 1.23 ± 0.32 x 10^-3mm²/s in metastatic liver lesions. These results are in accordance with the results in our study.⁶

Lee et al. in their study on 91 patients, stated good prognosis and survival of IHCCs when areas with diffusion restriction are dominant.¹⁴ But they do not provide ADC values of masses in their study. Yamada et al. notified that low ADC value is associated with poor differentiation and prognosis which has rich fibrotic stroma. The researchers, who divided the patients into two groups as high or low ADC, showed that the prognosis was poor in the tumors with decreased ADC. This result conflicts with the results of previous studies by Lee et al.¹⁵

In our study, we did not make prognostic grouping of our IHCC patients. In our study, we found significantly higher ADC values in IHCC patients compared to GIS adenocarcinoma liver metastases. We distinguished these tumors with a cut off ADC_mean value of 1178 x 10–6 mm²/s and 90.57% sensitivity. We speculated that the rich desmoplastic stroma of IHCC is effective in revealing the ADC difference in the differentiation from liver metastases of GIS.

In a recent study, Kovac et al. investigated the contribution of ADC values in the differentiation between solitary hypovascular liver metastases and IHCC.¹⁶ They reported lower ADC values in the peripheral enhancing areas and higher in the central parts in IHCC compared to solitary hypovascular metastases. Authors explained that high ADC values in the central part of IHCC are related to rich fibrous tissue.¹⁶ In our study, ADC values were obtained from enhancing solid area and we found higher ADC values compared to GIS metastases. High ADC values in IHCC could be attributed to desmoplastic stromal changes and decreased cellularity within the tumor.

We thought that the reproducibility of ADC measurement may be limited or needs more effort in clinical practice, but it provides significant diagnostic clues in differential diagnosis of such liver malignancies.

There were several limitations in the current study. First this is a retrospective study and has relatively small sample size, especially for the IHCC group because of the rarity of these tumors. Second, the fibrous intensity and differentiation levels of tumors was not assessed by histopathologically. Furthermore, the manual placement of ROI, as a known limitation in all ROI-based studies, may have led to biased results. In addition, the histopathological confirmation of liver metastases was made from primary tumor localization. But this situation was ignored because of low probability of synchronous IHCC and GIS metastases.

As far as we know, this is the first study that particularly demonstrates the utility of ADC values in differentiation of IHCC from GIS adenocarcinoma liver metastases. Our study results suggest that ADC values have a potential role for differentiation between IHCC and GIS liver metastases which may be valuable for patient management. Further larger-scale studies are needed to establish the relationship between IHCC and different tumor origins in terms of ADC values.