Correction of scan time dependence of standard uptake values in oncological PET

Hoff, Joerg van den; Lougovski, Alexandr; Schramm, Georg; Maus, Jens; Oehme, Liane; Petr, Jan; Beuthien‐Baumann, Bettina; Kotzerke, J.; Hofheinz, Frank

doi:10.1186/2191-219x-4-18

Cited by 48 publications

(55 citation statements)

References 13 publications

(24 reference statements)

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“…In the latter case, it has only to be assumed that the AIF can be described by some power law starting early after bolus passage, which empirically is fulfilled to a good degree (14). For scan-time correction of SUV it is necessary to assume that all AIFs can be described with the same power law-that is, the exponent b in Equation 1 is identical for all AIFs and its value directly enters the correction formula Equation 1.…”

Section: Discussionmentioning

confidence: 99%

“…In the clinical context, variability of the uptake period is unavoidable, which directly translates into a corresponding variability of the measured tracer uptake. But as has been shown recently, it is possible to reliably correct SUR (and somewhat less reliably SUV) for variations of the 18 F-FDG uptake period (14) by converting the measured uptake values to a preselected fixed scan time point. This scan-timenormalized SUR removes several of the shortcomings of SUV, leading to a much improved linear correlation between this uptake parameter and the actually targeted quantity, namely the metabolic rate of 18 F-FDG.…”

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confidence: 99%

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Prognostic Value of Pretherapeutic Tumor-to-Blood Standardized Uptake Ratio in Patients with Esophageal Carcinoma

et al. 2015

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Despite ongoing efforts to develop new treatment options, the prognosis for patients with inoperable esophageal carcinoma is still poor and the reliability of individual therapy outcome prediction based on clinical parameters is not convincing. The aim of this work was to investigate whether PET can provide independent prognostic information in such a patient group and whether the tumor-toblood standardized uptake ratio (SUR) can improve the prognostic value of tracer uptake values. Methods: 18 F-FDG PET/CT was performed in 130 consecutive patients (mean age ± SD, 63 ± 11 y; 113 men, 17 women) with newly diagnosed esophageal cancer before definitive radiochemotherapy. In the PET images, the metabolically active tumor volume (MTV) of the primary tumor was delineated with an adaptive threshold method. The blood standardized uptake value (SUV) was determined by manually delineating the aorta in the low-dose CT. SUR values were computed as the ratio of tumor SUV and blood SUV. Uptake values were scan-time-corrected to 60 min after injection. Univariate Cox regression and Kaplan-Meier analysis with respect to overall survival (OS), distant metastases-free survival (DM), and locoregional tumor control (LRC) was performed. Additionally, a multivariate Cox regression including clinically relevant parameters was performed. Results: In multivariate Cox regression with respect to OS, including T stage, N stage, and smoking state, MTV-and SUR-based parameters were significant prognostic factors for OS with similar effect size. Multivariate analysis with respect to DM revealed smoking state, MTV, and all SUR-based parameters as significant prognostic factors. The highest hazard ratios (HRs) were found for scan-time-corrected maximum SUR (HR 5 3.9) and mean SUR (HR 5 4.4). None of the PET parameters was associated with LRC. Univariate Cox regression with respect to LRC revealed a significant effect only for N stage greater than 0 (P 5 0.048). Conclusion: PET provides independent prognostic information for OS and DM but not for LRC in patients with locally advanced esophageal carcinoma treated with definitive radiochemotherapy in addition to clinical parameters. Among the investigated uptake-based parameters, only SUR was an independent prognostic factor for OS and DM. These results suggest that the prognostic value of tracer uptake can be improved when characterized by SUR instead of SUV. Further investigations are required to confirm these preliminary results.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

Prognostic Value of Pretherapeutic Tumor-to-Blood Standardized Uptake Ratio in Patients with Esophageal Carcinoma

et al. 2015

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“…12 Methods for modifying PET data to account for differences in 18F-FDG uptake time have been proposed. 10,[13][14][15][16] A straightforward method for comparing uptake values acquired at different times after injection was introduced by Beaulieu and colleagues. 10 Importantly, this method was developed and prospectively validated in a breast cancer patient population.…”

Section: Introductionmentioning

confidence: 99%

Comparison of prone versus supine 18F‐FDG‐PET of locally advanced breast cancer: Phantom and preliminary clinical studies

Williams

Rani

et al. 2015

Medical Physics

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Purpose: Previous studies have demonstrated how imaging of the breast with patients lying prone using a supportive positioning device markedly facilitates longitudinal and/or multimodal image registration. In this contribution, the authors' primary objective was to determine if there are differences in the standardized uptake value (SUV) derived from [ 18 F]fluorodeoxyglucose (18F-FDG) positron emission tomography (PET) in breast tumors imaged in the standard supine position and in the prone position using a specialized positioning device. Methods: A custom positioning device was constructed to allow for breast scanning in the prone position. Rigid and nonrigid phantom studies evaluated differences in prone and supine PET. Clinical studies comprised 18F-FDG-PET of 34 patients with locally advanced breast cancer imaged in the prone position (with the custom support) followed by imaging in the supine position (without the support). Mean and maximum values (SUV peak and SUV max , respectively) were obtained from tumor regions-of-interest for both positions. Prone and supine SUV were linearly corrected to account for the differences in 18F-FDG uptake time. Correlation, Bland-Altman, and nonparametric analyses were performed on uptake time-corrected and uncorrected data. Results: SUV from the rigid PET breast phantom imaged in the prone position with the support device was 1.9% lower than without the support device. In the nonrigid PET breast phantom, prone SUV with the support device was 5.0% lower than supine SUV without the support device. In patients, the median (range) difference in uptake time between prone and supine scans was 16.4 min (13.4-30.9 min), which was significantly-but not completely-reduced by the linear correction method. SUV peak and SUV max from prone versus supine scans were highly correlated, with concordance correlation coefficients of 0.91 and 0.90, respectively. Prone SUV peak and SUV max were significantly lower than supine in both original and uptake time-adjusted data across a range of index times (P << 0.0001, Wilcoxon signed rank test). Before correcting for uptake time differences, Bland-Altman analyses revealed proportional bias between prone and supine measurements (SUV peak and SUV max ) that increased with higher levels of FDG uptake. After uptake time correction, this bias was significantly reduced (P < 0.01). Significant prone-supine differences, with regard to the spatial distribution of lesions relative to isocenter, were observed between the two scan positions, but this was poorly correlated with the residual (uptake time-corrected) prone-supine SUV peak difference (P = 0.78).Conclusions: Quantitative 18F-FDG-PET/CT of the breast in the prone position is not deleteriously affected by the support device but yields SUV that is consistently lower than those obtained in the standard supine position. SUV differences between scans arising from FDG uptake time differences can be substantially reduced, but not removed entirely, with the current correction method. SUV from the two sca...

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“…This theoretical prediction has in fact been verified in patient data [9,11]. Two causes (beyond the elimination of all calibration related issues that is the principal advantage of any ratio method) are operational here: SUR corrects for the inherent variability of actual arterial tracer supply (present even after SUV normalization of the image data) [9] as well as for the practically unavoidable substantial variability of uptake time prior to scanning [8].…”

Section: Methodological Aspects Of Quantificationmentioning

confidence: 88%

“…So far, in oncological PET, especially the tumour to liver ratio (TLR) has been used (one example of this approach is the work of Huang et al [7]). More recently, we have proposed the imagederived tumour to arterial blood standard uptake ratio (SUR) as a promising alternative [8,9] and investigated its properties and performance compared to SUV [5,10,11]. We also addressed the question to what extent the healthy liver parenchyma might act as a substitute for actual arterial tracer supply [12].…”

Section: Methodological Aspects Of Quantificationmentioning

confidence: 99%

Quantification: there is more to worry about than good scanner hardware and reliable calibration

Kotzerke

Hoff

2017

Eur J Nucl Med Mol Imaging

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Positron emission tomography (PET) is Ban analytical imaging technology developed to use compounds labelled with positron-emitting radioisotopes as molecular probes to image and measure biochemical processes of mammalian biology in vivo^ [1]. One outstanding feature of the PET technology is the ability to perform absolute quantification of regional perfusion, metabolism, and function [2]. There are clinical demands for quantification regarding description of biodistribution, dosimetry, intra-and inter-individual comparisons, and setup of age-and gender-specific (normal) databases. Notably, FDG PET allows diagnosis, differential diagnosis, assessment of prognosis, and patient stratification in malignant disease. Moreover, image guided therapy has been proven to improve tumour delineation and irradiation field definition regarding protection of normal tissue and dose escalation on tumour tissue [3]. After initial assessment, followup investigations describe the effect of therapy and influence therapeutic management regarding continuation or change of modality and intensification or de-escalation of therapy. In addition to qualitative description and quantification of tracer uptake or uptake changes during follow-up, more sophisticated kinetic modelling and analysis may be applied. However, reliability and significance of all derived numbers is influenced by technical factors and biological processes. Methodological aspects of quantificationFormally, the principal goal in quantitative oncological FDG PET is to measure a surrogate of the tumour's metabolic rate of glucose consumption. Ideally, the surrogate parameter should be proportional to the latter quantity but, of course, a more general (linear or nonlinear) monotonic relation between surrogate and target parameter would suffice, too. But in any case, the respective relation has to be universally valid (i.e., invariant) across different scans, scanners, and patients. Otherwise, comparisons between different investigations are affected by spurious variability of the measured surrogate that is unrelated to actual changes in tumour metabolism.Currently, the standardized uptake value (SUV) is accepted as a suitable surrogate parameter derivable from static investigations, although it is widely recognized that its properties are far from ideal. Consequently, much effort has been invested to improve the reliability of SUV measurements by means of addressing the recognized technical issues, e.g., by focusing on strict calibration procedures and SOPs on how to perform measurement and data evaluation [4].Despite the unquestionable value of these efforts, test-retest stability of SUV remains rather unsatisfactory: even under highly controlled study conditions with nearly perfectly observed constant uptake times, test-retest variability is of the order of ±(30-40)% [5,6]. Consequently, SUV is not able to reliably detect (or exclude) moderate changes of the tumours' metabolic rate.In this context it is interesting to observe that there exist assorted reports of superior p...

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Correction of scan time dependence of standard uptake values in oncological PET

Cited by 48 publications

References 13 publications

Prognostic Value of Pretherapeutic Tumor-to-Blood Standardized Uptake Ratio in Patients with Esophageal Carcinoma

Prognostic Value of Pretherapeutic Tumor-to-Blood Standardized Uptake Ratio in Patients with Esophageal Carcinoma

Comparison of prone versus supine 18F‐FDG‐PET of locally advanced breast cancer: Phantom and preliminary clinical studies

Quantification: there is more to worry about than good scanner hardware and reliable calibration

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