Determination of an Optimal Pharmacokinetic Model of <sup>18</sup>F-FET for Quantitative Applications in Rat Brain Tumors

Richard, Marie Anne; Fouquet, Jérémie P.; Lebel, Réjean; Lepage, Martin

doi:10.2967/jnumed.116.180612

Cited by 15 publications

(10 citation statements)

References 25 publications

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“…The three models were compared using two established statistical criteria for model selection for TACs: the corrected Akaike information criterion (AIC) and the F test (48,49). The AIC is defined by …”

Section: Methodsmentioning

confidence: 99%

Dynamic PET of human liver inflammation: impact of kinetic modeling with optimization-derived dual-blood input function

et al. 2018

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The hallmark of nonalcoholic steatohepatitis is hepatocellular inflammation and injury in the setting of hepatic steatosis. Recent work has indicated that dynamic 18F-FDG PET with kinetic modeling has the potential to assess hepatic inflammation noninvasively, while static FDG-PET is less promising. Because the liver has dual blood supplies, kinetic modeling of dynamic liver PET data is challenging in human studies. This paper aims to identify the optimal dual-input kinetic modeling approach for dynamic FDG-PET of human liver inflammation. Fourteen patients with nonalcoholic fatty liver disease were included. Each patient underwent 1-hour dynamic FDG- PET/CT scan and had liver biopsy within six weeks. Three models were tested for kinetic analysis: the traditional two-tissue compartmental model with an image-derived single-blood input function (SBIF), a model with population-based dual-blood input function (DBIF), and a new model with optimization-derived DBIF through a joint estimation framework. The three models were compared using Akaike information criterion (AIC), F test and histopathologic inflammation score. Results showed that the optimization-derived DBIF model improved liver time activity curve fitting and achieved lower AIC values and higher F values than the SBIF and population-based DBIF models in all patients. The optimization-derived model significantly increased FDG K1 estimates by 101% and 27% as compared with traditional SBIF and population-based DBIF. K1 by the optimization-derived model was significantly associated with histopathologic grades of liver inflammation while the other two models did not provide a statistical significance. In conclusion, modeling of DBIF is critical for dynamic liver FDG-PET kinetic analysis in human studies. The optimization-derived DBIF model is more appropriate than SBIF and population- based DBIF for dynamic FDG-PET of liver inflammation.

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Section: Methodsmentioning

confidence: 99%

Dynamic PET of human liver inflammation: impact of kinetic modeling with optimization-derived dual-blood input function

et al. 2018

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“…Recently, pharmacokinetic modeling of 18 F-FET tracer kinetics in a syngeneic orthotopic preclinical model was reported by injecting F98 glioblastoma cells into the right hemisphere of Fisher rats 39 . They found a favorable performance of the 2TCM in terms of model selection criteria AIC, F test and residual plots.…”

Section: Discussionmentioning

confidence: 99%

Feasibility and robustness of dynamic 18F-FET PET based tracer kinetic models applied to patients with recurrent high-grade glioma prior to carbon ion irradiation

Debus

Afshar‐Oromieh

Floca

et al. 2018

Sci Rep

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The aim of this study was to analyze the robustness and diagnostic value of different compartment models for dynamic 18F-FET PET in recurrent high-grade glioma (HGG). Dynamic 18F-FET PET data of patients with recurrent WHO grade III (n:7) and WHO grade IV (n: 9) tumors undergoing re-irradiation with carbon ions were analyzed by voxelwise fitting of the time-activity curves with a simplified and an extended one-tissue compartment model (1TCM) and a two-tissue compartment model (2TCM), respectively. A simulation study was conducted to assess robustness and precision of the 2TCM. Parameter maps showed enhanced detail on tumor substructure. Neglecting the blood volume VB in the 1TCM yields insufficient results. Parameter K1 from both 1TCM and 2TCM showed correlation with overall patient survival after carbon ion irradiation (p = 0.043 and 0.036, respectively). The 2TCM yields realistic estimates for tumor blood volume, which was found to be significantly higher in WHO IV compared to WHO III (p = 0.031). Simulations on the 2TCM showed that K1 yields good accuracy and robustness while k2 showed lowest stability of all parameters. The 1TCM provides the best compromise between parameter stability and model accuracy; however application of the 2TCM is still feasible and provides a more accurate representation of tracer-kinetics at the cost of reduced robustness. Detailed tracer kinetic analysis of 18F-FET PET with compartment models holds valuable information on tumor substructures and provides additional diagnostic and prognostic value.

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“…Standard dynamic PET imaging often uses a moderate temporal resolution of 10-40 s (or poorer) per time frame (see [123], [140] for example). This is aimed at reaching a balance between image noise and the necessary temporal resolution for kinetic modeling.…”

Section: E High-temporal Resolution Kinetic Modeling and Parametric mentioning

confidence: 99%

PET Parametric Imaging: Past, Present, and Future

Wang

Rahmim

Gunn

2020

IEEE Trans. Radiat. Plasma Med. Sci.

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Positron emission tomography (PET) is actively used in a diverse range of applications in oncology, cardiology, and neurology. The use of PET in the clinical setting focuses on static (single time frame) imaging at a specific time-point post radiotracer injection and is typically considered as semi-quantitative; e.g., standardized uptake value (SUV) measures. In contrast, dynamic PET imaging requires increased acquisition times but has the advantage that it measures the full spatiotemporal distribution of a radiotracer and, in combination with tracer kinetic modeling, enables the generation of multiparametric images that more directly quantify underlying biological parameters of interest, such as blood flow, glucose metabolism, and receptor binding. Parametric images have the potential for improved detection and for more accurate and earlier therapeutic response assessment. Parametric imaging with dynamic PET has witnessed extensive research in the past four decades. In this article, we provide an overview of past and present activities and discuss emerging opportunities in the field of parametric imaging for the future.

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Determination of an Optimal Pharmacokinetic Model of ¹⁸F-FET for Quantitative Applications in Rat Brain Tumors

Cited by 15 publications

References 25 publications

Dynamic PET of human liver inflammation: impact of kinetic modeling with optimization-derived dual-blood input function

Dynamic PET of human liver inflammation: impact of kinetic modeling with optimization-derived dual-blood input function

Feasibility and robustness of dynamic 18F-FET PET based tracer kinetic models applied to patients with recurrent high-grade glioma prior to carbon ion irradiation

PET Parametric Imaging: Past, Present, and Future

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Determination of an Optimal Pharmacokinetic Model of 18F-FET for Quantitative Applications in Rat Brain Tumors

Cited by 15 publications

References 25 publications

Dynamic PET of human liver inflammation: impact of kinetic modeling with optimization-derived dual-blood input function

Dynamic PET of human liver inflammation: impact of kinetic modeling with optimization-derived dual-blood input function

Feasibility and robustness of dynamic 18F-FET PET based tracer kinetic models applied to patients with recurrent high-grade glioma prior to carbon ion irradiation

PET Parametric Imaging: Past, Present, and Future

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Determination of an Optimal Pharmacokinetic Model of ¹⁸F-FET for Quantitative Applications in Rat Brain Tumors