Clinical Evaluation of Zero-Echo-Time Attenuation Correction for Brain ¹⁸F-FDG PET/MRI: Comparison with Atlas Attenuation Correction

DISCUSSION

In this study, we evaluated the clinical feasibility of an attenuation-correction method based on prototype proton-density-weighted ZTE by comparing it to the default atlas-based AC method currently used by the SIGNA PET/MR. Clinical data from PET/CT patients volunteering for an additional PET/MR acquisition were used for this study.

The overall ¹⁸F-FDG uptake bias of ZTE-AC was 25% lower than that of atlas-AC. This improvement was achieved by the improved registration and assignment of correct attenuation values for the skull. Especially in central structures and insula and cingulate areas, a significant improvement with ZTE-AC was found in comparison to clinical atlas-AC. On the other hand, ZTE-AC was found to misclassify some of the nasal and mastoid areas as bone, which caused overestimation of ¹⁸F-FDG uptake in the temporal lobe and cerebellum.

In our study, the relative error and absolute relative error of ZTE-AC across all 670 VOIs were −0.09% ± 2.26% and 1.77% ± 1.41%, respectively, which are generally comparable to other studies (9,22–24). Previously reported absolute relative percentage errors of PET images range from 1.38% ± 4.52% to 2.55% ± 0.86% (9,22–24), though care should be taken when comparing these studies and the present study, because of analysis variations. Also, the use of TOF in our study has a potential to compensate the AC inconsistencies, causing the bias in the reconstructed PET images to spread over a larger area (13,18,25,26).

Previous studies with 15 clinical datasets—acquired with a PET/CT + MR trimodality setup—concluded that skull-bone identification based on a ZTE sequence is expected to have sufficient anatomic accuracy for PET AC (17). Though the acquisition time is accelerated in this study (172 s → 48 s) with lower spatial resolution (1.4 × 1.4 × 1.4 → 1.17 × 1.17 × 2.78 mm) to meet clinical requirements, accurate segmentation was also obtained in the current study, as shown in Figure 2A, in which the average and the SD of bone attenuation error from all 10 patients were much smaller than with atlas-AC. The improvement with ZTE-AC was noticeable in the inferior cerebrum, which reflects the correct estimation of temporal bone. The thin temporal bone causes misclassification and systematic underestimation by atlas-AC, which leads to the underestimation of ¹⁸F-FDG uptake in the same axial slices, along those lines of response (5). These results are consistent with the expectations for ZTE-based AC, and in particular its feature of providing measurement-based bone density information, rather than estimates based on a priori models.

In contrast, the misclassification and systematic overestimation of nasal and mastoid areas were observed (third row, Fig. 2A), leading to the overestimation of uptake in the cerebellum and temporal lobes. This issue should definitely be addressed, because the cerebellum is sometimes used as a reference for the normalization of the whole brain and the temporal lobes are one of the most important regions when dementia studies are performed. This is a known issue, caused by the discontinuous mapping of ZTE intensities to attenuation values. It affects primarily interfaces between soft tissue and air, in which partial-volume effects lead to averaged values that fall within the intensity range assigned to bone (16,17).

To improve this drawback, there are several options. One is the investigation of acceleration techniques allowing the saved scan time to be invested in improving the spatial resolution, hence reducing partial-volume effects. A second option is the use of more advanced segmentation approaches, capable of using local neighborhood information to identify partial-volume effects (e.g., machine-learning method (27)). Alternatively, with knowledge-based approaches, anatomic priors can be used to drive dedicated classification approaches in different anatomic regions (28). One potential drawback of such hybrid methods—aside from the increased computational cost—is losing the ability to adapt to off-norm anatomies, one of the main advantages of measurement-based methods over model-based ones. Further study is needed to improve the sinus and mastoid areas, to take full advantage of ZTE-based AC.

Following are additional features of the ZTE-AC methods. First, there was systematic underestimation of the superior cranium, which caused subtle underestimation of ¹⁸F-FDG uptake close to these areas. We assume that this problem is due to the partial-volume effect of the thin cortical bone in these regions. Second, ZTE requires minimal gradient switching, which can reduce eddy current effect. This might be some advantage when compared with the UTE-AC, which is one of the most popular segmentation-based methods in clinical head PET/MR study (8). The artifact sometimes causes the error in the calculation of T2 relaxation time on UTE-AC because of reduced signal intensities in the first UTE echo just after switching (9,29). There is no fair-comparison study between UTE-AC and ZTE-AC in the clinical setting because each method has been developed by a different vendor. Third, the absence of preparation pulses or multiple echoes makes ZTE a time-efficient acquisition (i.e., most of the repetition time is used to acquire data) and suitable for routine clinical use. Indeed, on PET/MR, the total MR acquisition time is generally longer than that of PET, and any options to minimize or accelerate MR acquisition time should be considered (30). Fourth, the current ZTE-AC has the capability of assigning continuous attenuation values to bone tissue, rather than discrete ones. Two previous studies estimate the negative effect of segmentation-based AC methods with discrete bone attenuation, using simulated CT images. Even if the classification of the bone/soft-tissue component is completely precise, the PET bias is within ±10% in one study and is 4.0% ± 3.7% in the other study (11,31). Also, several studies revealed that adding the continuous bone attenuation value calculated from T2 relaxation time using dual UTE sequences contributes to improve AC (9,10,31).

From the view of the comparison between atlas-/template-/model-based methods and segmentation methods, the former have 2 inherent limitations. One is that they cannot accurately detect the cavity of the sinus because there is wide interpatient variability. In our cohort, the sinus in the frontal bone is more precisely detected by ZTE-AC than atlas-AC (Figs. 1B and 2A). The other is that these methods are not suitable for patients with abnormal anatomy or surgical alterations. Though this topic is out of the scope for this study, ZTE-AC has the potential to detect these off-norm features precisely (16). On the other hand, segmentation-based methods are more sensitive to measurement artifacts, such as those caused by certain metallic implants. Ideally, both atlas-/template-/model-based methods and segmentation methods should be available in a clinical scanner.

Other additional features and advantages of this study are as follows.

First, we performed the assessment using real TOF PET/MR scanner data, not simulation data (e.g., combining PET/CT data with MRI data). In our study, we used a state-of-the-art TOF PET/MR system, consisting of silicon photomultipliers with less than 400-ps temporal resolution, enabling TOF acquisition (32). Evaluating the clinical feasibility of a new AC method is desirable in this realistic setting.

Second, we compared ZTE-AC with the atlas-AC currently used in clinical practice. If only 1 method were compared with the standard of reference in a small sample, the results may highly depend on interindividual variability. Hence, the comparison with current clinical methods on PET/MR scanners is mandatory.

Third, through the use of a widely available brain template (AAL), our results can be readily applied to another dataset or used in other centers (33).

A limitation of our study is the small number of patients considered. However, using automated methods and comparing 2 AC methods (atlas-AC and ZTE-AC) against a silver standard (CT-AC), we aimed to reduce bias. Also, the PET acquisition was not ideal for a brain PET scan: the scan duration was relatively short, 2 min, leading to a decrease in the signal to noise of the PET images. However, performing the analysis on a regional level (AAL VOI) reduced the sensitivity to the noise at the voxel level.