Abstract
Purpose
Radiographic changes of brain metastases after stereotactic radiosurgery (SRS) can signify tumor recurrence and/or radiation necrosis (RN); however, standard imaging modalities cannot easily distinguish between these two entities. We investigated whether 18F-Fluorocholine uptake in surgical samples of the resected lesions correlates with pathologic evidence of recurrent tumor and PET imaging.
Methods
About 14 patients previously treated with SRS that developed radiographic changes were included. All patients underwent a preoperative 40-min dynamic PET/CT concurrent with 392 ± 11 MBq bolus injection of 18F-Fluorocholine. 18F-Fluorocholine pharmacokinetics were evaluated by standardized uptake value (SUV), graphical analysis (Patlak plot; KiP) and an irreversible two-compartment model (K1, k2, k3, and Ki). 12 out of 14 patients were administered an additional 72 ± 14 MBq injection of 18F-Fluorocholine 95 ± 26 minutes prior to surgical resection. About 113 resected samples from 12 patients were blindly reviewed by a neuropathologist to assess the viable tumor and necrotic content, microvascular proliferation, reactive gliosis, and mono- and polymorphonuclear inflammatory infiltrates. Correlation between these metrics 18F-Fluorocholine SUV was investigated with a linear mixed model. Comparison of survival distributions of two groups of patients (population median split of PET SUVmax) was performed with the log-rank test.
Results
Exactly 10 out of 12 patients for which surgical samples were acquired exhibited pathologic recurrence. Strong correlation was observed between SUVmax as measured from a surgically removed sample with highest uptake and by PET (Pearson’s r = 0.66). Patients with 18F-Fluorocholine PET SUVmax > 6 experienced poor survival. Surgical samples with viable tumor had higher 18F-fluorocholine uptake (SUV) than those without tumor (4.5 ± 3.7 and 2.6 ± 3.0; p = 0.01). 18F-fluorocholine count data from surgical samples is driven not only by the percentage viable tumor but also by the degree of inflammation and reactive gliosis (p ≤ 0.02; multivariate regression).
Conclusions
18F-Fluorocholine accumulation is increased in viable tumor; however, inflammation and gliosis may also lead to elevated uptake. Higher 18F-Fluorocholine PET uptake portends worse prognosis. Kinetic analysis of dynamic 18F-Fluorocholine PET imaging supports the adequacy of the simpler static SUV metric.
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Introduction
The incidence of brain metastases (BM) has been rising due to improved imaging techniques, which aid early diagnosis, and systemic therapies which prolong life [1]. Stereotactic radiosurgery (SRS) is an effective treatment for patients with a limited number of BM. Its advantages over surgery and whole brain radiation therapy include short treatment time and limited side effects that allow preservation of quality of life. Up to 40% of BM treated with SRS will eventually develop either radionecrosis (RN) or tumor recurrence [2]. These two entities can occur within the same time interval after SRS with similar frequency [1, 3] and have similar architectural appearance on a magnetic resonance imaging (MRI) scan. Both result in similar symptoms (such as headaches, cognitive or motor difficulties, and seizures), but they require different therapeutic management and impact prognosis differently. RN can often be managed conservatively, reducing the need for surgical intervention and associated risk, whereas tumor recurrence needs to be managed with surgery, repeat radiation, and possibly systemic agents. Standard imaging techniques such as MRI perfusion, MR spectroscopy, or 18F-Fluorodeoxyglucose (18F-FDG) positron emission tomography/computed tomography (PET/CT) cannot easily distinguish between these two entities.
The current reference standard for distinguishing tumor recurrence from radionecrosis is biopsy, where conclusive histopathologic diagnosis is achieved in > 99% of cases [4]. However, biopsy is invasive and has potential complications such as transient or permanent neurological deficits [5]. Furthermore, many treated BM are in deep or eloquent locations that are not amenable to biopsy. There is a need for a reliable noninvasive imaging technique enabling the accurate differentiation of recurrent tumor from radionecrosis
Choline is a precursor of phospholipids, major structural components of the plasma membrane, and is frequently overexpressed in malignancies [6]. It is predominantly transported into cells via high-affinity sodium-dependent choline transporters, phosphorylated by choline kinase, and utilized for the synthesis of essential lipid components of cell membranes (e.g., phosphatidylcholine and sphingomyelin), the production of potent lipid mediators (such as platelet-activation factor and lysophosphatidylcholine), and the synthesis of the cholinergic neurotransmitter acetylcholine. Intracellular choline is rapidly metabolized to phosphocholine or oxidized by choline dehydrogenase and betaine-aldehyde dehydrogenase to betaine. 18F-Fluorocholine, a 18F-substituted choline analog, is rapidly cleared from the circulation, with previous studies indicating that its biodistribution changes very slowly after 10-min post-injection [7]. Kwee and colleagues reported that high-grade gliomas, BM, and benign lesions can be distinguished based on their 18F-Fluorocholine uptake [8].
We hypothesized that PET imaging with 18F-Fluorocholine would reliably discriminate between RN and tumor recurrence. For that purpose, we performed 18F-Fluorocholine dynamic PET scans in patients with radiographic changes requiring surgery after SRS for BM. PET-derived imaging metrics were subsequently compared with the level of 18F-Fluorocholine radioactivity in tissue samples resected from the lesion and for which a detailed histopathologic assessment was available. We also explored whether pharmacokinetic modeling of dynamic 18F-Fluorocholine PET data provided added benefit.
Methods and materials
Study design and patient selection
A prospective nontherapeutic trial was performed with 18F-Fluorocholine PET imaging in patients with recurrent tumor and/or RN following SRS for BM. Human use of 18F-Fluorocholine was approved by our Institutional Radioactive Drug Research Council (RDRC). The RDRC rules permit research studies to be performed with novel radiotracers without an investigational new drug designation. The protocol was approved by the Institutional Review Board (Protocol # 13-199; registered under ClinicalTrials.gov Identifier NCT02037945), and all patients provided written informed consent regarding the examination and use of anonymous data for research and publication purposes. The trial was intended to investigate the localization of 18F-Fluorocholine within the irradiated brain using a PET/CT and was not used to assess treatment response or to change treatment decisions. The study enrolled patients who were scheduled to undergo surgical resection. Patients were also administered a second dose of 18F-Fluorocholine in the operating room at the time of surgery. Subject inclusion criteria were: (i) ability to provide written informed consent, (ii) ≥ 21 y old, and (iii) evolving brain lesions post SRS requiring neurosurgical resection (whether for symptomatic control or to establish pathology). Exclusion criteria were (i) inability to undergo a MRI or PET/CT scan and (ii) pregnant or nursing female. In total, 14 patients participated in the study.
18F-Fluorocholine radiosynthesis
18F-Fluorocholine was manufactured at the Memorial Sloan Kettering Radiochemistry and Molecular Imaging Probe Core Facility using a fully automated radiosynthesis method on the General Electric TracerLab MX module. 18F-Fluorocholine was synthesized by the 18F-fluoroalkylation of N,N-dimethylaminoethanol using 18F-fluorobromomethane as the fluoromethylating agent. 18F-Fluorobromomethane was produced by the reaction of dibromomethane with 18F-fluoride, assisted by Kryptofix 222. After purification on solid-phase extraction cartridges, the 18F-Fluorocholine was obtained with > 99% radiochemical purity.
PET/CT imaging
Dynamic PET scans were performed for a total of 40 min over a single field of view (15.7 cm axially) on the Discovery STE (for n = 3 patients), 690 (n = 4 patients), or 710 (n = 7 patients) PET/CT (GE Health Care, Inc.). Dynamic scans started upon injection of 392 ± 11 MBq of 18F-Fluorocholine. Images were acquired in list mode and binned into 6 × 5 s, 3 × 10 s, 4 × 60 sec, 2 × 150 s, 2 × 300 s, and 2 × 600 s. A CT scan (120 kV, 150 mA, and 3.8-mm slice thickness) was used for attenuation correction and anatomical localization. PET emission data were acquired in three-dimensional mode; corrected for attenuation, scatter, and random events; and iteratively reconstructed into a 256 × 256 × 47 matrix (voxel dimensions: 1.17 × 1.17 × 3.27 mm3) using the ordered subset expectation maximization algorithm provided by the manufacturer.
Blood sample analysis
Radioactivity in whole blood and plasma specimens was radioassayed with a calibrated well counter (1480 Wallac Wizard 3 Automatic Gamma Counter (Perkin Elmer, Inc.)) [9]. Briefly, four venous blood samples were obtained at approximately 1-min, 5-min, 10-min, and 30-min post-injection. Plasma radioactivity was integrated by trapezoidal method as area under curve. The measured radioactivity concentrations were converted to percentage injected dose per liter (%ID/L).
Image analysis
All image processing was performed in PMOD v3.604 (PMOD Software, RRID:SCR_016547). Lesions were identified by a physician with experience in nuclear medicine. Volumes of interest (VOIs) were manually drawn over the identified lesions to derive time-activity curves (TACs) and to measure the mean standardized uptake value within the VOI corrected by body weight (SUVbw). Maximum SUV values were determined on the last 10-min dynamic frame. For each patient, analysis was also performed for spherical VOIs placed over normal brain tissue (5 VOIs each with 10 mm radius). Motion correction techniques were not applied, because patient immobilization resulted in minimal motion and PET-CT mismatch.
The input function (IF) was image-derived by defining a VOI over the internal carotid artery on the early frame that allowed for the best visualization. For each patient, whole-blood IF TACs were defined using the available temporal data, corrected for partial-volume effect [10], scaled by the whole-blood activity concentration as measured from blood samples, and finally corrected to account for the fraction of 18F-Fluorocholine in plasma. Metabolite counts were not analyzed; instead, a population-based metabolite correction derived from 11C-Choline dynamic PET studies was applied, with the percentage of activity due to unmetabolized 18F-Fluorocholine being 90%, 60%, 40%, and 19% at 1-, 5-, 10-, and 30-min after injection, respectively [11, 12].
Both reversible one-compartment (1T2K) and irreversible and reversible two-compartment (2T3K and 2T4K, respectively) pharmacokinetic models with a blood volume fraction component (vB) were implemented to calculate kinetic rate constants K1, k2, k3, and k4. A unidirectional uptake rate constant (KiC) was also calculated, defined as
In addition to pharmacokinetic modeling, Patlak graphical analysis was performed to calculate net influx rate of the radiotracer (KiP [13, 14]).
Contrast-enhanced MRI was performed before or after PET, with a mean of ± 3 days (range 0–13). When compared to the first MRI after completion of SRS, there was a ≥ 20% increase in the median longest diameter (33 mm; range 21–61 mm). Although qualifying for progressive disease according to the proposed Response Assessment in Neuro-Oncology brain metastasis (RANO-BM) criteria [15], this change does not distinguish between viable disease vs RN.
Histopathology
Patients were reinjected with 72 ± 14 MBq (range, 55.5–107.3 MBq) of 18F-Fluorocholine 95 ± 26 min (range, 55–152 min) prior to surgical resection and 2 ± 1 days (range, 1–4 days) after the 18F-Fluorocholine PET. Multiple tissue samples were collected for each lesion. Each sample was placed in separate 10% formalin-containing vials, re-weighted, and immediately counted in a calibrated Wallac gamma-ray spectrometer (located outside the operating room). Decay-corrected radioactivity of each sample was determined. Multiple samples ranging from high to low radioactivity were blindly reviewed by a neuropathologist for presence of viable tumor and necrosis content, microvascular proliferation, reactive gliosis, and mono- and polymorphonuclear inflammatory infiltrates, using a semiquantitative system (scale between 0 [not a feature] and 3 [most conspicuous]). The tissue sections were evaluated based on the percentage of viable tumor and necrosis content using 20% increments.
For each sample, 18F-Fluorocholine SUV was calculated as the measured radioactivity in the sample (determined by measuring the decay-corrected net count rate and applying a calibration factor that relates the counts per minute to kBq/cc), divided by the injected activity and patient body mass.
Statistical analysis
The correlation strength between the investigated indices was analyzed using Pearson´s correlation coefficient r. p < 0.05 was assumed to represent statistical significance. Kaplan-Meier method was implemented to visualize the survival curves of two groups of patients split based on the population median of 18F-Fluorocholine PET SUVmax. The mean follow-up time was 31 ± 21 months (range, 2–68 months). Observations were censored if the patient was alive at the time of last follow-up or deceased from a cause other than progressing brain metastases. Log-rank test was performed to test whether the two survival curves were significantly different.
Correlation between five pathology metrics derived from resected tissue samples (i.e., viable tumor, necrosis content, microvascular proliferation, reactive gliosis, and inflammatory infiltrates) and 18F-Fluorocholine SUV was investigated with a linear mixed model to incorporate the random effects due to clustering (i.e., each patient is a cluster), using the R package lme4 as described previously [16]. Both univariate and multivariate regression models were run. Significant covariates in univariate analysis (p < 0.05) were included in the multivariate analysis. Assigned weights for 18F-Fluorocholine SUV were inversely proportional to the coefficient of variation from the decay-corrected net counts per minute. Statistical significance level of the fixed effects based on linear mixed model results was approximated by t-test with Satterthwaite degrees of freedom using the lmerTest package.
Results
18F-Fluorocholine PET was performed in 14 patients with 22 treated BM between January 2014 and May 2016, including patients with lung cancer (n = 3), melanoma (n = 3), and breast cancer (n = 2), and one patient with colorectal cancer, ovarian cancer, testicular germ cell tumor, renal carcinoma, endocrine carcinoma, and leiomyosarcoma (Table 1). No reactions or adverse events associated with 18F-Fluorocholine were observed in any of the patients. Exactly 10 out of 12 patients in whom surgical samples were acquired exhibited pathologic recurrence. (The confirmation of RN in two remaining patients was determined clinically on subsequent MRI scans performed 32 and 36 months later, respectively.) For two patients, dynamic PET images could not be analyzed due to the absence of attenuation-corrected dynamic data and slow influx of activity through the major vessels into the head, possibly due to less than optimal tracer bolus. However, there were no indications of tracer extravasation at the injection site. In another two patients, research tissue samples were not acquired. About 20 lesions were identified in 12 patients with evaluable PET scans, measuring 7.9 ± 8.7 cm3 (range, 0.4–33.3 cm3).
The percentage of activity due to 18F-Fluorocholine in plasma was 67 ± 11%, 65 ± 9%, 65 ± 7%, and 64 ± 7% at 1, 5, 10, and 30 min after injection. Intratumor 18F-Fluorocholine uptake reached 80% and 90% of the total activity at 3 ± 4 and 7 ± 6 minutes (median, 1 and 6 minutes) post-injection, respectively. Total tumor 18F-Fluorocholine was measured at 40 minutes. 18F-Fluorocholine uptake was low in the normal brain parenchyma; average brain background SUV values were 0.2 ± 0.1. The average SUVmax and SUVmean for all 20 lesions studied were 6.2 ± 3.3 and 3.0 ± 1.8, respectively (Table 2).
According to Akaike Information Criterion (AIC), 2-tissue compartment model was preferred over 1-tissue compartment model (both including a blood component) in 16 out of 20 cases. Mean AIC values in all 20 cases were 138 ± 44, 116 ± 36, and 115 ± 36 for 1C2K, 2C3K, and 2C4K models, respectively. Including the blood component vB improved the AIC values. 2T3K model resulted in lower AIC values compared to 2T4K model in 13 out of 20 cases. In the remaining seven cases, 2T4K model was preferred due to nonnegative k4 (0.008 ± 0.009 min-1). 2C3K model resulted in lowest AIC values when fitting normal brain tissue (109 ± 22, 105 ± 21, and 109 ± 21 for 1C2K, 2C3K, and 2C4K models, respectively).
In lesions, Pearson’s r between kinetic rate constants derived from whole tumor VOIs and SUVmean was 0.74, 0.14, and −0.17 for K1, k2, and k3, respectively (K1 was not significantly correlated with neither k2 nor k3). The analysis was also repeated for small intratumor VOIs encompassing few voxels with the highest uptake of 18F-Fluorocholine (i.e., highest SUV on the last dynamic frame). Corresponding Pearson’s r between kinetic rate constants and SUVmax was 0.70, 0.00, and −0.01 for K1, k2, and k3, respectively. Net influx rate constant as calculated with a 2C3K model, KiC, closely matched the corresponding metric derived from Patlak graphical analysis, KiP (r = 0.98 and r = 0.94 for mean and max, respectively). Strong correlation was observed between max KiC and SUV (r = 0.83). For normal brain tissue, r between SUVmean and K1, k2, and k3 was 0.38, −0.20, and 0.17, respectively. K1 was significantly higher in lesions compared to normal brain tissue.
18F-fluorocholine PET-derived SUVmax was significantly correlated with the count-derived SUV from surgical samples in the most 18F-fluorocholine-avid tissue sample (r = 0.66, p < 0.01; Fig. 1A). Correlation with the count-derived SUVmax was also plotted for K1,maxC (Fig. 1B), K1,max (Fig. 1C), and k3,max (Fig. 1D). Of note, neurosurgeons attempted to resect tissue samples from PET avid regions, but accurate spatial colocalization was both difficult and approximate. Mean SUV across all tissue samples in a lesion was 4.8 ± 2.6, whereas SUVmax for the hottest tissue sample per lesion was 7.8 ± 4.1. Correlations were also calculated between Ki.max and K1,max and the static SUVmax (Fig. 2A, 2B), highlighting that 18F-fluorocholine uptake at 40-min post-injection is primarily dependent on K1. As expected, KiP and KiC were also found to be highly correlated (r = 0.94, p < 0.01; Fig. 2C).
About 113 surgical samples were collected from 14 resected lesions in 12 patients (8 ± 4 per lesion; weighing 0.16 ± 0.12 g). Exactly 10 out of 14 lesions (in 10 out of 12 patients) were positive for tumor recurrence, whereas the remaining 4 out of 14 lesions were negative. In ten lesions positive for tumor recurrence, 76 ± 34% of samples were positive (range, 9–100%). In total, evidence of viable tumor was present on 69 samples (61%), while 83 (76%) had necrosis, with 57 samples (53%) containing both. About 58 samples (55%) were positive for vascular proliferation, 61 (55%) had gliosis, and 45 (41%) had inflammation (not all 113 samples were scored for all). Mean tumor and necrosis content, averaged over all samples from the same lesion, were 29% ± 27% (range, 0–80%) and 23% ± 17% (range, 0–42%), respectively. Mean semiquantitative values for microvascular proliferation, mononuclear and polymorphonuclear inflammatory infiltrates, and reactive gliosis (scale between 0 and 3) were 0.5 ± 0.4, 0.6 ± 0.7, and 0.5 ± 0.4, respectively. Surgical samples with viable tumor had higher 18F-fluorocholine uptake than those without tumor (SUV of 4.5 ± 3.7 compared to 2.6 ± 3.0; p = 0.01). The analysis with a linear mixed model revealed that 18F-fluorocholine uptake in the surgical samples was driven by the degree of reactive gliosis (p = 0.011) and inflammation (p = 0.021); a multivariate regression analysis showed a significant correlation between resection tissue 18F-Fluorocholine SUV and reactive gliosis (p = 0.011), viable tumor (p = 0.015), and inflammation (p = 0.022). No correlation of 18F-fluorocholine uptake with proliferation and percentage necrosis was observed based on both analyses. There was no significant correlation between 18F-Fluorocholine SUV and sample processing time post-injection (r = 0.07) or sample net weight (r = 0.08).
18F-Fluorocholine SUVmax as a function of follow-up time is presented in Fig. 3A (date of last follow-up: October 7, 2019). The data was split into two groups according to median 18F-fluorocholine SUVmax value of 6. Survival distributions were visualized with Kaplan-Meier estimators (Fig. 3B). Patients with 18F-Fluorocholine SUVmax above the median value of 6 had worse prognosis; however, significance was not reached (log-rank test, p = 0.068). Observations were censored if the patient was alive at the time of last follow-up (blue diamonds on Fig. 3A) or deceased from cause other than progressing brain metastases (orange square on Fig. 3A).
18F-Fluorocholine PET/CT images together with tumor time-activity curves and surgical samples are shown for two representative patients with (Fig. 4) and without (Fig. 5) pathologic confirmation of tumor recurrence, illustrating different 18F-Fluorocholine pharmacokinetics between lesions.
Discussion
The aim of the current study was to determine whether PET imaging with 18F-Fluorocholine reliably discriminates between RN and tumor recurrence. For that purpose, we performed 18F-Fluorocholine dynamic PET scans in patients with radiographic changes requiring surgery after SRS for BM. Our cohort was skewed, as 10 out of 14 patients exhibited pathologic recurrence. PET-derived 18F-Fluorocholine SUVmax was significantly correlated with uptake in the most 18F-Fluorocholine-avid surgical sample. While the radiographic and outcome analyses are underpowered due to paucity of events, our results indicate that 18F-Fluorocholine may reflect the presence of viable tumor in patients with radiologic progression after SRS on microscopic (i.e., specimen activity) as well as macroscopic (i.e., PET) measures. Additionally, 18F-Fluorocholine PET SUVmax appears to allow for the identification of patients that have increased risk of death due to progressing brain metastases. Of note, in addition to percentage viable tumor, inflammation and reactive gliosis also resulted in elevated 18F-Fluorocholine SUV in resected tissue samples.
Other PET radiotracers have been investigated for differentiating tumor recurrence from radionecrosis in brain. 18F-Fluorodeoxyglucose (FDG) is avidly accumulated in inflammatory regions where white blood cells and macrophages have high rates of glycolysis. The high background level of FDG in normal brain tissue compromises its ability to distinguish progressive disease, and consequently FDG PET is not widely utilized for this purpose. The sensitivity and specificity of 18F-FDG PET to distinguish recurrent tumor from radiation necrosis were reported to be in the range of 65–86% and 22–94%, respectively [17,18,19]. On the other hand, radiolabeled amino acids such as 11C-methionine and O-(2-18F-fluoroethyl)-L-tyrosine (18F-FET) have relatively high tumor and low brain uptake, with studies showing promising results in differentiating RN from tumor recurrence in brain metastases [20, 21]. However, normal brain uptake of the amino acids was reported to be higher than that of 18F-Fluorocholine. Tumor uptake of 11C-Choline and 18F-Fluorocholine has been shown to be greater than 11C-methionine and other amino acids [22]. In a direct comparison of 11C-methionine with 11C-choline, Rottenburger et al. concluded that 11C-choline is a promising radiotracer for the imaging of brain metastases compared with 11C-methionine due to significantly higher tumor-to-blood ratios, without evidence for a lower specificity of 11C-choline uptake [23]. These findings are expected to be translatable to 18F-substituted choline analogs due to similar tumor uptake patterns [24]. Recent reports indicate that metabolic imaging with 6-18F-fluoro-L-dopa (18F-FDOPA) PET and analysis of semiquantitative uptake indices is a promising tool for differentiating recurrent or progressive brain metastases from late or delayed radiation injury [25, 26]. To best of our knowledge, a direct comparison study between 18F-Fluorocholine and 18F-FDOPA has not been performed.
Another goal of our study was to determine whether pharmacokinetic modeling of 18F-Fluorocholine uptake from dynamic PET acquisitions adds benefit, as has been shown for 18F-FET [20] and a-11Cmethyl-L-tryptophan [27]. In our study, a high correlation was observed between SUV and the net uptake rate constant Ki. This observation supports the use of static SUV at later times (e.g., 40 min) post-injection, once tumor uptake has plateaued. 18F-Fluorocholine uptake was rapid and sustained, as observed previously [12, 28,29,30], and appears to reach a plateau faster than 18F-FET [31]. In the irreversible two-compartment model, the K1 term may incorporate some of the “trapping” component (e.g., transport into tumor cells, rapid phosphorylation, etc.), in addition to lesion perfusion and vascular permeability. Since phosphorylation of choline is rapid [32], it may not be accurately identified as “k3” in the kinetic model. Although the k3 term is justified based on Akaike Information Criterion and reflects a slower process, it was not correlated with 18F-Fluorocholine SUVmax in the PET images. However, in a comparison between surgical samples and PET imaging metrics, k3 estimates and surgical sample-derived SUVmax values were correlated, although the PET voxels and surgical sample were not spatially colocalized with certainty.
In this cohort of patients, 18F-Fluorocholine uptake at 40-min post-injection is primarily driven by K1, as indicated by the differences between lesions with and without pathologic evidence of tumor as well as by the high correlation between K1 and SUV in lesions and the absence of corresponding correlation between k3 and SUV. Others have noted that 18F-Fluorocholine K1 and k3 may not be physiologically identifiable. The nonnegative k3 values in brain may reflect choline uptake that is utilized for synthesis of the neurotransmitter acetylcholine (18F-Fluorocholine SUV in normal brain increased by about 6–8% during the second half of the 40-min dynamic acquisition); however, accurate estimation of k3 in normal brain is compromised due to relatively low K1. Furthermore, a limitation of our analysis is that a population-based metabolite correction was used, derived from 11C-Choline data [11, 12]. Bansal and colleagues concluded that 18F-Fluorocholine mimics radiolabeled choline as a biochemical tracer, although metabolic rates to both lipid and oxidative metabolites were moderately attenuated for 18F-Fluorocholine relative to 14C-choline [32]. The same group reported that a small but appreciable fraction of 18F-Fluorobetaine (a metabolite of 18F-Fluorocholine) was observed in tumors of glioma-bearing rats [32], whereas the implemented pharmacokinetic model assumes that 18F-Fluorobetaine is not significantly accumulated in tumors. Slaets and colleagues concluded that the blood metabolism of 11C-Choline and 18F-Fluorocholine was similar in mice and that corrections for 18F-Fluorobetaine uptake were not mandatory [33]. When our analysis was repeated with a three-compartment pharmacokinetic model with two input functions that accounts for nonspecific uptake of radiometabolites (Supplementary Table S1), similar values were observed for K1, k2, and k3.
Conclusions
This is the first study to our knowledge in which the PET radiotracer 18F-Fluorocholine was injected perioperatively, allowing radiotracer uptake to be correlated with pathologic diagnosis in tissue samples obtained at surgery. Our findings suggest that 18F-Fluorocholine PET SUV correlates with pathologic evidence of recurrent tumor after SRS for BM. The strong correlation between 18F-Fluorocholine SUV and the net influx rate (Ki) supports the use of a simpler static PET acquisition, instead of requiring a dynamic or a dual-phase acquisition.
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This study was funded by the NIH grant 1R21 CA170289-01A1 (Principal Investigator, Kathryn Beal; corresponding, John L. Humm and Ronald G. Blasberg), R01 CA194321 (Principal Investigator: John L. Humm) and the MSK Radiochemistry & Molecular Imaging Probes Core, supported in part through the NIH/NCI Cancer Center Support Grant P30 CA008748 (Principal Investigator: Craig B. Thompson).
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RJY declares consulting and grant support from Agios and consulting for Puma, Icon, and NordicNeuroLab. Other authors declare no potential conflicts of interest.
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All procedures performed in studies involving human participants were in accordance with the ethical standards of the institutional and/or national research committee (Memorial Sloan Kettering Cancer Center’s Institutional Review Board, Protocol #13-199; registered under ClinicalTrials.gov Identifier NCT02037945) and with the 1964 Helsinki declaration and its later amendments or comparable ethical standards.
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Grkovski, M., Kohutek, Z.A., Schöder, H. et al. 18F-Fluorocholine PET uptake correlates with pathologic evidence of recurrent tumor after stereotactic radiosurgery for brain metastases. Eur J Nucl Med Mol Imaging 47, 1446–1457 (2020). https://doi.org/10.1007/s00259-019-04628-6
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DOI: https://doi.org/10.1007/s00259-019-04628-6