Towards standardization of 18F-FET PET imaging: do we need a consistent method of background activity assessment?

Unterrainer, Marcus; Vettermann, Franziska; Brendel, Matthias; Holzgreve, Adrien; Lifschitz, Michael; Zähringer, Matthias; Suchorska, Bogdana; Wenter, Vera; Illigens, Ben; Bartenstein, Peter; Albert, Nathalie L.

doi:10.1186/s13550-017-0295-y

Cited by 92 publications

(117 citation statements)

References 24 publications

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“…Out of a series of patients with suspicious brain lesions who were admitted for 18 F-FET PET to the Institute of Neuroscience and Medicine in Jülich (Germany) from February 2010 to April 2017, 107 scans which revealed no abnormality in 18 F-FET PET and which had been rated in the medical reports as “negative scans” with respect to tumour diagnosis, were retrospectively identified by two experienced nuclear physicians (AV and GS). Negative scans were defined as showing 18 F-FET uptake in the suspected lesion area (identified by corresponding MR images) to be indistinguishable from that of the normal brain within a TBR max range of 0.9–1.1, which is in line with the expectable background SUV changes (± 8%) in the brain for this radiopharmaceutical ( Unterrainer et al, 2017 ). Other inclusion criteria for further data evaluation were age > 18 years, no pre-treatment with radio- or chemotherapy or received therapy with dexamethasone, and complete coverage of the brain by the PET acquisition which was essential for data analysis.…”

Section: Methodsmentioning

confidence: 98%

“…In the majority of studies, however, tracer uptake in the tumour was quantified by the ratio of SUV max or SUV mean in the tumour to the SUV mean in a background region in the contralateral hemisphere expressed as maximal and mean tumour-to-brain ratios (TBR max and TBR mean ) ( Jansen et al, 2012 , Jansen et al, 2015 , Mehrkens et al, 2008 , Misch et al, 2015 , Pauleit et al, 2005 , Pöpperl et al, 2007 , Rapp et al, 2013 , Stockhammer et al, 2008 ). This method is based on the assumption that 18 F-FET uptake in the normal brain is relatively homogeneous although there is some discussion about the optimal positioning of the region of interest in the normal brain ( Unterrainer et al, 2017 ). Nevertheless, it cannot be excluded that physiological variations of SUV mean of 18 F-FET uptake in background could influence TBRs and the results of semi-quantitative analysis.…”

Section: Introductionmentioning

confidence: 99%

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Evaluation of factors influencing 18F-FET uptake in the brain

Verger

Stegmayr

Galldiks

et al. 2018

NeuroImage: Clinical

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PET using the amino-acid O-(2-18F-fluoroethyl)-l-tyrosine (18F-FET) is gaining increasing interest for brain tumour management. Semi-quantitative analysis of tracer uptake in brain tumours is based on the standardized uptake value (SUV) and the tumour-to-brain ratio (TBR). The aim of this study was to explore physiological factors that might influence the relationship of SUV of 18F-FET uptake in various brain areas, and thus affect quantification of 18F-FET uptake in brain tumours. Negative 18F-FET PET scans of 107 subjects, showing an inconspicuous brain distribution of 18F-FET, were evaluated retrospectively. Whole-brain quantitative analysis with Statistical Parametric Mapping (SPM) using parametric SUV PET images, and volumes of interest (VOIs) analysis with fronto-parietal, temporal, occipital, and cerebellar SUV background areas were performed to study the effect of age, gender, height, weight, injected activity, body mass index (BMI), and body surface area (BSA). After multivariate analysis, female gender and high BMI were found to be two independent factors associated with increased SUV of 18F-FET uptake in the brain. In women, SUVmean of 18F-FET uptake in the brain was 23% higher than in men (p < 0.01). SUVmean of 18F-FET uptake in the brain was positively correlated with BMI (r = 0.29; p < 0.01). The influence of these factors on SUV of 18F-FET was similar in all brain areas. In conclusion, SUV of 18F-FET in the normal brain is influenced by gender and weakly by BMI, but changes are similar in all brain areas.

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Section: Methodsmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Evaluation of factors influencing 18F-FET uptake in the brain

Verger

Stegmayr

Galldiks

et al. 2018

NeuroImage: Clinical

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“…summation images [ 15 , 27 ]. Background (BG) values were derived from a crescent-shaped volume of interest (VOI) as described previously [ 28 ]. VOIs were defined within the PMOD View tool (version 3.5, PMOD Technologies, Zurich, Switzerland).…”

Section: Methodsmentioning

confidence: 99%

Voxel-wise analysis of dynamic 18F-FET PET: a novel approach for non-invasive glioma characterisation

et al. 2018

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BackgroundGlioma grading with dynamic 18F-FET PET (0–40 min p.i.) is typically performed by analysing the mean time-activity curve of the entire tumour or a suspicious area within a heterogeneous tumour. This work aimed to ensure a reader-independent glioma characterisation and identification of aggressive sub-volumes by performing a voxel-based analysis with diagnostically relevant kinetic and static 18F-FET PET parameters.One hundred sixty-two patients with a newly diagnosed glioma classified according to histologic and molecular genetic properties were evaluated. The biological tumour volume (BTV) was segmented in static 20–40 min p.i. 18F-FET PET images using the established threshold of 1.6 × background activity. For each enclosed voxel, the time-to-peak (TTP), the late slope (Slope15–40), and the tumour-to-background ratios (TBR5–15, TBR20–40) obtained from 5 to 15 min p.i. and 20 to 40 min p.i. images were determined. The percentage portion of these values within the BTV was evaluated with percentage volume fractions (PVFs) and cumulated percentage volume histograms (PVHs). The ability to differentiate histologic and molecular genetic classes was assessed and compared to volume-of-interest (VOI)-based parameters.ResultsAggressive WHO grades III and IV and IDH-wildtype gliomas were dominated by a high proportion of voxels with an early peak, negative slope, and high TBR, whereby the PVHs with TTP < 20 min p.i., Slope15–40 < 0 SUV/h, and TBR5–15 and TBR20–40 > 2 yielded the most significant differences between glioma grades. We found significant differences of the parameters between WHO grades and IDH mutation status, where the effect size was predominantly higher for voxel-based PVHs compared to the corresponding VOI-based parameters. A low overlap of BTV sub-volumes defined by TTP < 20 min p.i. and negative Slope15–40 with TBR5–15 > 2- and TBR20–40 > 2-defined hotspots was observed.ConclusionsThe presented approach applying voxel-wise analysis of dynamic 18F-FET PET enables an enhanced characterisation of gliomas and might potentially provide a fast identification of aggressive sub-volumes within the BTV. Parametric 3D 18F-FET PET information as investigated in this study has the potential to guide individual therapy instrumentation and may be included in future biopsy studies.Electronic supplementary materialThe online version of this article (10.1186/s13550-018-0444-y) contains supplementary material, which is available to authorized users.

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“…Standardized uptake values (SUV) were calculated from patient weight and injected activity. For background correction, a circular ROI was placed in gray and white matter of the non-tumor-bearing hemisphere by IV and BW [22].…”

Section: Image Processingmentioning

confidence: 99%

Imaging glioma biology: spatial comparison of amino acid PET, amide proton transfer, and perfusion-weighted MRI in newly diagnosed gliomas

Schön

Cabello

Liesche‐Starnecker

et al. 2020

Eur J Nucl Med Mol Imaging

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Purpose Imaging glioma biology holds great promise to unravel the complex nature of these tumors. Besides well-established imaging techniques such O-(2-[18F]fluoroethyl)-L-tyrosine (FET)-PET and dynamic susceptibility contrast (DSC) perfusion imaging, amide proton transfer-weighted (APTw) imaging has emerged as a promising novel MR technique. In this study, we aimed to better understand the relation between these imaging biomarkers and how well they capture cellularity and vascularity in newly diagnosed gliomas. Methods Preoperative MRI and FET-PET data of 46 patients (31 glioblastoma and 15 lower-grade glioma) were segmented into contrast-enhancing and FLAIR-hyperintense areas. Using established cutoffs, we calculated hot-spot volumes (HSV) and their spatial overlap. We further investigated APTw and CBV values in FET-HSV. In a subset of 10 glioblastoma patients, we compared cellularity and vascularization in 34 stereotactically targeted biopsies with imaging. Results In glioblastomas, the largest HSV was found for APTw, followed by PET and CBV (p < 0.05). In lower-grade gliomas, APTw-HSV was clearly lower than in glioblastomas. The spatial overlap of HSV was highest between APTw and FET in both tumor entities and regions. APTw correlated significantly with cellularity, similar to FET, while the association with vascularity was more pronounced in CBV and FET. Conclusions We found a relevant spatial overlap in glioblastomas between hotspots of APTw and FET both in contrast-enhancing and FLAIR-hyperintense tumor. As suggested by earlier studies, APTw was lower in lower-grade gliomas compared with glioblastomas. APTw meaningfully contributes to biological imaging of gliomas.

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Towards standardization of 18F-FET PET imaging: do we need a consistent method of background activity assessment?

Cited by 92 publications

References 24 publications

Evaluation of factors influencing 18F-FET uptake in the brain

Evaluation of factors influencing 18F-FET uptake in the brain

Voxel-wise analysis of dynamic 18F-FET PET: a novel approach for non-invasive glioma characterisation

Imaging glioma biology: spatial comparison of amino acid PET, amide proton transfer, and perfusion-weighted MRI in newly diagnosed gliomas

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