Feasibility of state of the art PET/CT systems performance harmonisation

Four PET/CT systems equipped with both ToF and PSF capabilities from three major vendors (General Electric (GE), Siemens and Philips) were selected for this study. Systems included were the Siemens Biograph mCT (Siemens system 1), the Siemens Biograph mCT Flow (Siemens system 2), the GE Discovery 710 (GE system) and the Philips Ingenuity TF 128 (Philips system). The equipment was calibrated in accordance with the corresponding manufacturer’s instructions. In addition, all systems were participating and accredited in the EANM/EARL 18F–FDG PET/CT accreditation program. Detailed specifications for the systems can be found in supplemental Table 1 and references [47‐51].

The phantoms and filling procedures used complied with the EANM/EARL guidelines for Image Quality QC measurements which need to be performed annually as part of the EANM/EARL accreditation program [35]. The NEMA NU2–2007 body phantom was used, which is a plastic cylinder in the form of a fillable torso cavity, to act as a background compartment. It has a 5 cm diameter cylindrical lung insert in the centre and six fillable spheres with internal diameters of 10, 13, 17, 22, 28 and 37 mm, positioned coaxially around the lung insert. The lung insert is filled with polystyrene beads in order to mimic lung tissue. The phantom background compartment and the spherical inserts were filled with 18F–FDG solutions aimed at activity concentrations of 2 kBq/mL and 20 kBq/mL, respectively, at the start of the measurements, resulting in a sphere to background activity concentration ratio of 10:1.

In accordance with current EANM/EARL guidelines for 18F–FDG Image Quality QC phantom imaging [35], a low dose CT acquisition, followed by an emission scan consisting of two bed positions with an acquisition time of 5 min per bed position is to be acquired for the “image quality” dataset to assess contrast recovery performance. In this study, acquisition time of 5 min per bed position was selected as the reference for high count statistics. In order to investigate the effect of reduced count statistics on contrast recovery, data acquired with shorter acquisition times, respectively 2 and 1 min per bed position, were collected. The GE and Philips systems had list mode data acquisition capability available, which meant that only the 5 min/bed position emission scans were acquired and reconstructions with shorter acquisition times were generated retrospectively from the list mode data. On the Siemens systems included in this study, multiple shorter emission scans were acquired with the phantom left in an unchanged position. In order to facilitate the Siemens Flow system’s (Siemens system 2) possibility of performing scanning with continuous table movement, instead of a specific bed position scanning duration, table feed speeds of 0.5 mm/s, 1 mm/s and 2 mm/s were selected, resulting in similar acquisition times as with the other scanners.

Reconstructions were performed using the software available on each of the PET/CT systems. TOF, PSF, normalisation, randoms, scatter and attenuation corrections were applied and the reconstruction parameters were selected to increase overall contrast recovery, meanwhile aiming at achieving comparable recovery values across systems (for each sphere). In addition, we also considered achieving comparable recovery values between the spheres to minimise severe partial volume effects as well as large Gibbs overshoots. Clinically used and vendor recommended reconstruction parameters were applied and varied. Three iterations with 21 subsets were used for Siemens 1 (Biograph mCT) and two iterations with 21 subsets for Siemens 2 (mCT Flow) reconstruction. For GE - B, D, F and G (Discovery 710) - two iterations with 24 subsets and the VPFXS reconstruction method were used, while for GE - A, C and E - the QCFX reconstruction method, with an unknown number of iterations and subsets, was used. For the Philips systems the iterations/subsets were 3/33 but these could not be selected prior to scanning, with no values retrieved from the DICOM header of the images; so the BLOB OS TF reconstruction method was used. Different Gaussian filters and pixel sizes within clinically relevant ranges were also investigated in order to study their effects on contrast recovery. Additionally, for the GE system, a proprietary reconstruction method, the “Q.Clear”, which uses a Bayesian penalised-likelihood reconstruction algorithm, was investigated using different penalization factors (β) and its effect on quantitative image quality was evaluated. Due to differences among vendors and models, the available reconstruction parameters and their ranges were limited based on availability and/or user selectability. In total, 15 reconstruction parameter sets (reconstruction modes) were used to assess and compare the quantitative performance of the investigated systems. Each reconstruction mode was applied on three different scans, acquired with long (~4 min/bed for the Siemens Flow system; ~5 min/bed for all other systems), with medium (~2 min/bed) and short (~1 min/bed) frame durations. A summary of the acquisition and reconstruction settings of the 15 reconstruction modes is presented in Table 1.

Data reconstructed on the PET/CT were exported to a PC for further analysis using the EARL semi-automatic tool [35] designed for quantitative analysis of images of the NEMA NU2–2007 body phantom, filled conforming to EANM/EARL guidelines for 18F–FDG Image Quality QC phantom imaging. The software tool requires phantom images in DICOM format and filling data as input, and extracts SUV recovery for the spheres, a calibration factor for the background compartment and standard deviation and coefficients of variation from uniform images of the background. The SUV recovery coefficient (RC) is defined as the ratio between measured and expected activity concentration in each spherical insert. RC values were calculated based on 50% background corrected isocontour VOI (RC_SUVmean), maximum voxel value included in VOI (RC_SUVmax) and spherical VOI with a diameter of 12 mm, positioned so to yield the highest uptake (RC_SUVpeak) [35, 39, 52].

Prior to further analysis, all data were corrected for system calibration bias in order to be able to compare the various reconstruction modes’ impact on RCs and not to be effected by inter-scanner calibration errors. For this purpose, to all RCs a correction factor, defined as the ratio between expected and measured activity concentration in the corresponding uniform background compartment, was applied. For the 15 initial reconstruction modes, inter-scanner global correction factors ranged from 0.88 to 1.12, with the mean and standard deviation being 0.98 and 0.055, respectively. Intra-scanner changes were below 1%. For the 23 additional reconstructions, the inter-scanner global correction factors ranged from 0.93 to 1.10 (one system, however, showed a correction factor of 0.8), with the mean and standard deviation values of 0.99 and 0.055, respectively.

The primary objective of this study was to find reconstruction modes providing high, yet uniform contrast recoveries within the spheres of the NEMA NU2–2007 body phantom, which could be matched across all generations of PET/CT systems currently used in clinical practice – which would result in quantitative harmonisation of PET/CT systems.

RC_SUVmean, RC_SUVmax and RC_SUVpeak curves for all reconstructed phantom images were plotted against sphere diameters (Fig. 1) and characterised using visual and quantitative analysis, for which the applied metrics are summarised in Table 2. Reconstruction modes with higher RCs than current EARL specifications, as well as tightly grouped and stable RC_SUVmean and RC_SUVmax curves, were sought for harmonisation purposes.

The harmonising reconstruction modes were selected by simultaneously analysing quantitative characteristics of the reconstruction modes along with visual appearance of the RC curves. The following considerations were kept in mind while determining feasible reconstruction modes – (1) the proposed harmonising specifications should provide an increase over the current EARL compliant RC values, (2) the bandwidth of RCs should be similar to the current Earl specification limits and (3) the harmonising RC curves should not demonstrate major overshoots (=upward bias) due to Gibbs artefacts. While the harmonising reconstruction modes were selected based on the abovementioned considerations, quantitative cut-off criteria were retrospectively determined and stated in Table 9 based on the bandwidth and characteristics of harmonising reconstruction modes. Performances of the candidate reconstruction modes were compared with the initial group of reconstructions as well as current EARL accreditation specifications.

In order to prospectively evaluate the reproducibility and inter-scanner variability of the proposed reconstruction modes for harmonisation, 16 EARL accredited facilities, equipped with current generation PET/CT systems, participated in the study and provided the requested reconstructions from independent phantom acquisitions applying acquisition and reconstruction parameters (supplemental Table 2) identical or similar to the reconstructions proposed for harmonisation purposes. Data received from the centres was analysed in the same way as the reconstructions in the pilot study.

Analysis of the initial 15 reconstruction modes resulted in five reconstruction modes, which produced the highest uniform contrast recoveries and were feasible for all of the investigated systems considering SUVmean and SUVmax (Philips - B, GE – E, GE - F, Siemens 1 – D and Siemens 2 – A), to be considered for harmonisation. In order to accommodate unavoidable inter-scanner variability and reproducibility errors due to equipment calibration and user inaccuracy, all of the RC ranges were expanded to be proportional (i.e., using the same bandwidth of performance, but taking into account increased contrast recovery) to current EARL specifications for sphere recoveries. Bandwidths for proposed and current EARL specifications as well as the RC curves derived from the five reconstruction modes are presented in Fig. 2. For the provisional SUVpeak specifications, average sphere recoveries of the five reconstruction modes and a bandwidth of ±2 standard deviations was used. Additionally, recovery coefficients are plotted as a function of background noise for each sphere and per SUVmetric (presented in supplemental Figs. 4–6). Axial slices of the phantom data from the five harmonising reconstructions are shown in supplemental Fig. 7.

Sixteen EARL accredited sites participated in the prospective evaluation of the newly proposed specifications for harmonisation and performed reconstructions according to instructions provided. Data received included 23 distinctive reconstructions from three GE Discovery 710 systems, two Philips Ingenuity systems, six Siemens mCT systems, three Siemens mCT Flow systems, one GE Discovery IQ system, two GE Discovery MI systems and one Philips Vereos system. RC curves derived from the 18 systems along with proposed new harmonising specifications can be seen in Fig. 3. For SUVmean, 16 out of 138 analysed spheres produced RC values outside of the suggested accreditation interval, while for SUVmax and SUVpeak, the number of outliers was 12. Quantitative results describing additional reconstructions can be found in Tables 10, 11 and 12. Specifications, based on the current findings, proposed for harmonisation along with current EARL specifications are presented in Table 13.

Quantification of PET images is affected by uncertainties derived from reconstruction settings as well as global system (cross-) calibration. In this study the experimental data were corrected for global calibration errors, but in clinical practice both effects should be taken into consideration. Therefore, an accurate system calibration remains of utmost importance for all PET/CT systems used for quantification in order to keep the uncertainties as low as possible.

The phantom experiments conducted were sensitive to measurement uncertainties of dose calibrators and human error during the phantom preparation phase. The uncertainties related to phantom filling procedure are not part of this study and may increase the bandwidth of achievable harmonisation.

All experiments on various PET/CT models were performed on appointed systems. The inter-system variability stemming from the individual differences among the systems of the same make and differences due to manufacturers allowed variability in well counter calibration factors, and may increase the bandwidth of achievable harmonisation even further, although the newly proposed harmonisation specification was set using the same bandwidth as current EARL, which was shown to be appropriate and feasible.

As the position of VOI-s used in the analysis and comparison of SUVmean data is based on PET images rather that CT data, it is to some extent affected by image noise and may induce a small additional uncertainty to the results. This, however, is reflective of the clinically used method of VOI positioning. When this strategy is followed, it is therefore important to also put a threshold on acceptable noise levels (in this paper background noise should be lower than 15%). Yet, use of CT-based VOI definition could be of interest in order to mitigate the effects of noise on VOI definition and subsequently on the measurement of the recovery coefficients. Another alternative could be the use of SUVpeak rather than SUVmax as a starting point for VOI definition, as was applied in Frings et al. [57]. These strategies may be considered when developing future standards.

Current study investigated harmonisation of PET/CT systems using ¹⁸F tracer based FDG. The results cannot be directly transferred to system performance harmonisation involving other PET isotopes such as ⁶⁸Ga or ⁸²Rb which have a substantially longer positron range. System performance harmonisation with positron emitting isotopes other then¹⁸F requires further investigation.

In this feasibility study we primarily made use of reconstruction methods and parameter settings that were predefined or could be easily set by the user on commercially released systems. Where the software permitted, we applied additional reconstructions to include at least PSF and TOF, and also tried other reconstruction parameter settings which were expected to yield higher recoveries than the current EARL specification. Yet, in this study we did not extensively explore a wide range of reconstruction settings as, e.g., iterations, subsets, matrix sizes, etc., since our aim was to investigate clinically available protocols which are accessible for the users. Moreover, the investigated reconstruction modes had similar, but still different, voxel sizes as well as the number of iterations/subsets between various systems which complicates direct comparison. In conclusion, the harmonisation investigated in this study should be considered as a first feasibility test aiming at improving the current EARL specifications. Of course, a higher level of harmonisation would also be possible by considering more parameters, but then the question will be the feasibly in clinical practice. Further work is also needed to more extensively explore the impact of PSF reconstructions, voxel size and number of iterations/subsets on the variability of quantitative metrics of clinical datasets. Some reports have already been published showing that the repeatability and ICC of SUVmax, SUVpeak and SUVmean are at an acceptable level [58].

To conclude, despite possible limitations, we have studied the feasibility of the harmonising state of the art PET/CT system performances, and the results suggest that an update of the EARL current specification is feasible and achievable in practice.