Comparison of whole-body 18F-FDG PET/CT and PET/MRI for distant metastases in patients with malignant tumors: a meta-analysis

Malignant tumors are common public health problems worldwide and lead to tumor-related complications and death. The presence of distant metastases is an important prognostic factor in patients with advanced malignant tumors. Accurate distant metastases staging is a critical initial step in choosing an appropriate therapeutic plan and predicting patient prognosis.

At present, available whole-body tumor staging tools clinically include computed tomography (CT), magnetic resonance imaging (MRI), fluorine-18 fluorodeoxyglucose (18F-FDG) positron emission tomography (PET)/CT, and PET/MRI. Although PET/CT is the conventional imaging procedure used to depict malignant lesions and perform tumor staging because of its high speed, high diagnostic accuracy, and availability, however, it has several limitations, such as ionizing radiation and the inability to detect sub-centimeter lesions in the liver and brain [1]. In contrast, PET/MRI has the advantage of combining the metabolic information provided by PET and the unique features of MRI, including avoidance of radiation exposure and high soft tissue contrast; therefore, PET/MRI is rapidly emerging as an important imaging modality for assessing tumor staging.

Several studies have reported on the diagnostic accuracy of 18F-FDG PET/MRI and PET/CT as promising imaging methods for the distant metastases staging, and the reported accuracies are variable, with a sensitivity ranging from 44 to 100% and a specificity ranging from 81 to 100% for PET/MRI, and with a sensitivity ranging from 44 to 100% and a specificity ranging from 75 to 100% for PET/CT [2‐15], that limited to oncologic management decisions. Furthermore, as some studies included only a small number of subjects, the power of individual studies is limited. In addition, the most common sites for distant metastases are the lung, liver, brain, and bone, 18F-FDG PET/MRI shows superiority over PET/CT in detecting liver, brain, and bone metastases, due to dynamic contrast-enhanced imaging, diffusion-weighted imaging (DWI), and signal intensity (SI) assessment [5, 10, 14]. Therefore, 18F-FDG PET/MRI may be superior to PET/CT for the diagnosis of distant metastases. It is timely and important to systematically determine the diagnostic accuracy of distant metastases of 18F-FDG PET/MRI and compare it with that of 18F-FDG PET/CT.

Despite improvements in treatment techniques, advanced cancer with distant metastases remains difficult to cure. When making decisions on advanced cancer therapy, it is necessary to have a precise assessment of possible distant metastases. With the development of imaging technology, the clinical application of whole-body 18F-FDG PET/MRI and PET/CT may make it possible for distant metastases to be effectively detected in patients with advanced cancer. The current meta-analysis demonstrated that 18F-FDG PET/MRI had a higher diagnostic accuracy for detecting distant metastases than PET/CT with a higher sensitivity (0.87 versus 0.81) and a higher AUC value (0.98 versus 0.95). Combining the evidence from the included studies in this meta-analysis, it can be concluded the following main reasons for that outcome.

The main reason for the higher sensitivity of 18F-FDG PET/MRI come from the MRI section of PET/MRI, MRI can provide additional enhancement properties, DWI, and relaxation time-dependent information such as signal intensity (SI) assessments. Ohno et al. [17] reported that the sensitivity of whole-body MRI with DWI for recurrence assessment of lung cancer was higher than that of whole-body MRI without DWI (88.2% versus 70.6%), indicating that the addition of DWI could improve the diagnostic accuracy of whole-body MRI. The diagnostic accuracy for M1 staging of malignant pleural mesothelioma of whole-body 18F-FDG PET/MRI with SI assessment (95.7%) was higher than that of PET/MRI without SI assessment (87.0%), indicating that SI assessment could provide additional information to improve the diagnostic accuracy of whole-body PET/MRI [11]. Moreover, Ohno Y [2] stated that whole-body PET/MRI with SI assessment can assist in accurately evaluating regional lymph node involvement, presence of distant metastatic specificity, and clinical stage in patients with lung cancer. Melsaether AN et al. [5] reported that 15 brain metastases in breast cancers were seen on contrast-enhanced T1-weights images of MRI, but no metabolic activity was measured in PET images and have resulted in FN results on PET/CT. The PET/MRI protocol of most studies included in this meta-analysis included gadolinium-containing contrast enhancement, DWI, and SI assessment, which might provide incremental value for the diagnosis of metastases.

Another important issue that attributed to improving the diagnostic performance of 18F-FDG PET/MRI is FDG avidity of PET data. 18F-FDG uptake affects diagnostic accuracy, on the one hand, non-FDG-avid lesions such as permeative osseous metastases and sub-centimeter hepatic, brain metastases are not visible on PET, but on MRI [8]. On the other hand, metastases lesions that are located in organs with high background FDG activity, such as the adrenal glands, which show variable physiologic FDG uptake, are missed on PET/CT and might result in FP, but are visible on MRI [18‐20]. It has become clear that the pattern of 18F-FDG kinetics and 18F-FDG uptake varies by different histology types and histology grading, causing differences in diagnosis accuracy [21]. Among invasive breast carcinomas, 18F-FDG uptake in “carcinoma in situ” is usually weak [22], invasive carcinomas with high Scarff-Bloom-Richardson grade exhibit higher 18F-FDG uptake than carcinomas of lower grade, and invasive ductal carcinoma exhibits higher 18F-FDG uptake than invasive lobular carcinoma [23]. In our inclusion studies, its available data were obtained with mixed subtypes of breast cancers, which has hampered the accuracy assessment of subtype-specific of breast cancer with 18F-FDG PET/CT and PET/MRI.

Besides, it is worth highlighting that 18F-FDG PET/MRI and PET/CT have different advantages for detecting metastatic organs. On the one hand, 18F-FDG PET/MRI may be superior for detecting subcutaneous, brain, liver, and bone metastases due to its high soft-tissue contrast, such as lymph node metastases or bone metastases is easy to visualize on short inversion time inversion recovery sequence, adrenal gland metastasis can be depicted on dual-phase T1-gradient echo sequence, brain and liver metastases can be seen on contrast-enhanced T1-weighted images. Lee SM et al. found that one brain metastasis was missed on PET/CT, which depicted the weakness of PET/CT in detecting brain metastases [4]. Available data show that PET/CT depicts 50–70% of known presumably symptomatic brain metastases [24]. Botsikas D et al. [10] showed that PET/MRI had a significantly higher sensitivity than PET/CT for detecting bone metastases. The reason for this difference is that the T1-weighted imaging sequence reveals bone metastatic lesions by identifying bone marrow infiltration, but a faint radiotracer uptake on PET that is not associated with a corresponding CT finding results in a negative on PET/CT. Beiderwellen et al. [25] found that PET/MRI provided superior ability to display lesion for bone metastases and enabled the delineation of more malignant lesions than PET/CT. Melsaether AN et al. [5] found that PET/MRI outperformed PET/CT for detecting bone and liver metastases in a lesion-based analysis. On the other hand, 18F-FDG PET/CT can be expected to be advantageous in the detection of small pulmonary metastases as sub-centimeter pulmonary nodules were seen on PET/CT images, but PET/MRI was less sensitive for detecting small nodules because they are not FDG avid [26]. However, this study did not compare the differences in accuracy in determining the organ-specific metastases between 18F-FDG PET/CT and PET/MRI because the data regarding organ-specific metastases could not be extracted from those studies.

In the subgroup analysis, 18F-FDG PET/MRI had a higher sensitivity and specificity than PET/CT for evaluating distant metastases of breast cancers. This is in accordance with the findings of another systematic review conducted by de Mooij et al. [27], who also concluded that 18F-FDG PET/MRI has achieved higher diagnostic accuracy than 18F-FDG PET/CT in the distant staging of patients with breast cancer. Botsikas D et al. [10] compared the whole-body PET/MRI with PET/CT in breast cancer and found no statistically significant difference in the sensitivity, specificity, PPV, or NPV of the two tools for detecting distant metastases in a patient-per-patient analysis. In breast cancer, the bone is a common site for distant metastases and occurs in 69% of patients with advanced disease. Previous studies have found that PET/MRI detected osseous metastases in significantly more patients with breast cancer than PET/CT [28]. Melsaether AN et al. [5] reported that PET/MRI showed higher sensitivity than PET/CT for detecting liver metastases in breast cancers owing to DWI. It seems that PET/MRI has higher diagnostic confidence likely due to the superiority over detected lesions in bone, and liver metastases, compared with PET/CT.

In another subgroup analysis, 18F-FDG PET/CT had a higher sensitivity and a lower specificity for detecting distant metastases of lung cancer than PET/MRI. PET/MRI detected slightly more bone and liver metastases than PET/CT [29], however, the detection of FDG-avid nodules is poorer with PET/MRI than with PET/CT [30]. Despite all this, PET/MRI has been suggested to match or surpass the accuracy of PET/CT for the staging and recurrence surveillance of multiple thoracic malignancies [15].

Based on the results summarized in this meta-analysis, 18F-FDG PET/CT has been demonstrated to achieve similar diagnostic performance in the distant staging of breast and lung cancer (sensitivity 0.87 versus 0.87). 18F-FDG PET/MRI has higher accuracy in the distant staging of breast cancer to lung cancer (sensitivity 0.95 versus 0.84).

This present meta-analysis has some limitations that should be considered. First, inadequate data was acquired from the included studies to separately evaluate the diagnostic accuracy based on per-lesion analysis. Second, pathological examinations from biopsies to confirm metastatic lesions were not obtained from every metastatic lesion. The imaging follow-up also used as the reference standard when a pathological examination was missing. Third, there was considerable heterogeneity between the studies, although we performed subgroup analyses. Fourth, different MRI protocols were taken in different studies, there are no standard MR sequence protocols in the included studies, plus DWI and a dedicated MRI of the breast were used in some studies.

This meta-analysis highlights that 18F-FDG PET/MRI and PET/CT both performed well as detectors of distant metastases in advanced patients with malignant tumors, and the former has higher sensitivity. The subgroup analysis highlights that 18F-FDG PET/MRI and PET/CT hold different advantages for distant metastases staging in the different tumors, PET/MRI has a higher accuracy in patients with breast cancer patients, while PET/CT has a higher accuracy in patients with lung cancer.