Abstract
BackgroundThe aims of this study were to determine the optimal tracer kinetic model for [11C]-meta-hydroxyephedrine ([11C]HED) and to evaluate the performance of several simplified methods.MethodsThirty patients underwent dynamic 60-min [11C]HED scans with online arterial blood sampling. Single-tissue and both reversible and irreversible two-tissue models were fitted to the data using the metabolite-corrected arterial input function. For each model, reliable fits were defined as those yielding outcome parameters with a coefficient of variation (CoV) <25%. The optimal model was determined using Akaike and Schwarz criteria and the F-test, together with the number of reliable fits. Simulations were performed to study accuracy and precision of each model. Finally, quantitative results obtained using a population-averaged metabolite correction were evaluated, and simplified retention index (RI) and standardized uptake value (SUV) results were compared with quantitative volume of distribution (VT) data.ResultsThe reversible two-tissue model was preferred in 75.8% of all segments, based on the Akaike information criterion. However, VT derived using the single-tissue model correlated highly with that of the two-tissue model (r2 = 0.94, intraclass correlation coefficient (ICC) = 0.96) and showed higher precision (CoV of 24.6% and 89.2% for single- and two-tissue models, respectively, at 20% noise). In addition, the single-tissue model yielded reliable fits in 94.6% of all segments as compared with 77.1% for the reversible two-tissue model. A population-averaged metabolite correction could not be used in approximately 20% of the patients because of large biases in VT. RI and SUV can provide misleading results because of non-linear relationships with VT.ConclusionsAlthough the reversible two-tissue model provided the best fits, the single-tissue model was more robust and results obtained were similar. Therefore, the single-tissue model was preferred. RI showed a non-linear correlation with VT, and therefore, care has to be taken when using RI as a quantitative measure.Electronic supplementary materialThe online version of this article (doi:10.1186/s13550-014-0052-4) contains supplementary material, which is available to authorized users.
Highlights
The aims of this study were to determine the optimal tracer kinetic model for [11C]-meta-hydroxyephedrine ([11C]HED) and to evaluate the performance of several simplified methods
Recently, non-invasive imaging of sympathetic innervation of the myocardium using PET [1,2,3,4,5] or SPECT [6,7,8] has gained interest based on its ability to predict life-threatening ventricular arrhythmias [9,10,11] and to assess whether implantable cardioverter defibrillator (ICD) therapy is appropriate [12,13]
retention index (RI) has never been validated using a direct comparison with quantitative results obtained from a full tracer kinetic analysis
Summary
The aims of this study were to determine the optimal tracer kinetic model for [11C]-meta-hydroxyephedrine ([11C]HED) and to evaluate the performance of several simplified methods. Quantitative results obtained using a population-averaged metabolite correction were evaluated, and simplified retention index (RI) and standardized uptake value (SUV) results were compared with quantitative volume of distribution (VT) data. Analysis of [11C]HED and [11C] epinephrine data often has been performed using the retention index (RI) [5], a semiquantitative parameter that can be derived relatively easy. It is obtained by normalizing late activity concentrations to the integral of the blood timeactivity curve. Another semiquantitative measure, standardized uptake value (SUV), could provide a further simplification relative to RI, as it does not require measurement of blood time-activity curves, nor dynamic scanning
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