Abstract
Purpose
The aim of this study was to assess and compare the arterial uptake of the inflammatory macrophage targeting PET tracer [64Cu]Cu-DOTATATE in patients with no or known cardiovascular disease (CVD) to investigate potential differences in uptake.
Methods
Seventy-nine patients who had undergone [64Cu]Cu-DOTATATE PET/CT imaging for neuroendocrine neoplasm disease were retrospectively allocated to three groups: controls with no known CVD risk factors (n = 22), patients with CVD risk factors (n = 24), or patients with known ischemic CVD (n = 33). Both maximum, mean of max and most-diseased segment (mds) standardized uptake value (SUV) and target-to-background ratio (TBR) uptake metrics were measured and reported for the carotid arteries and the aorta. To assess reproducibility between different reviewers, Bland–Altman plots were made.
Results
For the carotid arteries, SUVmax (P = .03), SUVmds (0.05), TBRmax (P < .01), TBRmds (P < .01), and mean-of-max TBR (P = .01) were overall shown to provide a group-wise difference in uptake. When measuring uptake values in the aorta, a group-wise difference was only observed with TBRmds (P = .04). Overall, reproducibility of the reported uptake metrics was excellent for SUVs and good to excellent for TBRs for both the carotid arteries and the aorta.
Conclusion
Using [64Cu]Cu-DOTATATE PET imaging as a marker of atherosclerotic inflammation, we were able to demonstrate differences in some of the most frequently reported uptake metrics in patients with different degrees of CVD. Measurements of the carotid artery as either maximum uptake values or most-diseased segment analysis showed the best ability to discriminate between the groups.
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Introduction
Despite advances in medical and interventional therapies in recent decades, morbidity and mortality due to ischemic disease like myocardial infarction and stroke remain high.[1,2]
Today, clinically applied non-invasive measures of the atherosclerotic burden like computed tomography (CT) calcium scoring offers improved risk stratification and selection of treatment strategy.[3] Positron emission tomography (PET) imaging has the distinct advantage of being able to selectively image and quantify, depending on tracer choice, ongoing physiological processes, e.g., inflammation, hypoxia, or calcification.[4] In the context of inflammation and atherosclerosis, macrophages are of special interest because of their essential role in the development of atherosclerosis.[5] The majority of previous research in this context has been done using [18F]-fluoro-deoxyglucose ([18F]FDG), a marker for tissue metabolism and glycolysis, measuring ongoing inflammation as increase in arterial wall glucose metabolism.[6,7,8] This has offered the opportunity to noninvasively quantify the effect of interventions on vascular inflammation.[9,10]
Other, more specific radiotracers aimed at investigating macrophage activity and inflammation are continually being developed and evaluated. Inflammatory M1 macrophages have been shown to express the G-protein-coupled receptor somatostatin receptor subtype-2 (SST2), which is the target of [1,4,7,10-tetraazacyclododecane-N,N′, N″,N′′′-tetraacetic acid]-D-Phe1, Tyr3-octreotate (DOTATATE), a SST2 ligand. DOTATATE labeled with either copper-64 (64Cu) or gallium-68 (68Ga) is used clinically in the diagnostic evaluation of neuroendocrine neoplastic disease (NEN), but is also being increasingly adopted in research as a marker of atherosclerotic inflammation. Both preclinical and clinical trials have demonstrated that PET imaging of vascular inflammation using radioactive-labeled DOTATATE is feasible.[11,12,13,14,15] 64Cu labeling has distinct advantages that are of particular importance when imaging atherosclerosis, this being a shorter positron range (64Cu: ~ 1 mm vs 68Ga: ~ 4 mm), allowing for improved PET image resolution, as well as longer half-life (12.7 hours), which offers the possibility for image acquisition at later time points.[16,17,18] However, information about (1) the most appropriate method to quantify [64Cu]Cu-DOTATATE uptake in atherosclerosis and (2) optimal cut-point values to distinguish between patients with no known cardiovascular disease (CVD) and those with known disease. This information is vital when designing clinical studies using [64Cu]Cu-DOTATATE as a tool to quantify arterial inflammation.
The purpose of this study was to retrospectively assess arterial uptake of [64Cu]Cu-DOTATATE in the aorta and carotid arteries and compare commonly used PET metrics. To do so, a cohort of patients was divided into 3 distinct groups, based on differences in cardiovascular risk profile at time of imaging: (1) patients with no known cardiovascular risk factors, (2) patients with risk factors for CVD, and (3) patients with a history of a previous ischemic event (myocardial infarction, transient ischemic attack, or ischemic stroke). We also aimed to assess the reproducibility of the [64Cu]Cu-DOTATATE PET uptake metrics most commonly used in atherosclerosis research.
Materials and methods
Patient cohort
All individuals who had undergone routine clinical [64Cu]Cu-DOTATATE PET/CT, at Department of Clinical Physiology, Nuclear Medicine and PET, University Hospital Rigshospitalet due to suspected or known NEN in the time period from November 2014 until February 2021 were retrospectively identified and assessed for eligibility for inclusion. The criteria for inclusion were as follows: Referral for suspected NEN diagnosis or staging of NEN, age > 50 years at time of PET/CT scan, [64Cu]Cu-DOTATATE whole-body PET/CT scan performed within the timeframe of the study approval and available for analysis, and no treatment with immune-modifying medication (glucocorticoids or conventional and biologic disease-modifying antirheumatic drugs) one year prior to the [64Cu]Cu-DOTATATE PET/CT scan (Figure 1).
In Denmark, all individuals are given a permanent unique personal identification number from the National Central Population Register at birth. All medical procedures, treatments, hospital admissions, and diagnoses are registered in relation to the patient’s unique personal identification number in an electronic medical record (EMR) system. Hospital admissions are registered with a primary, and if applicable, secondary diagnosis according to the 10th revision of the International Classification of Diseases (ICD-10).
Data regarding prior diagnoses, medical treatments, procedures, and diagnostic testing were collected from electronic medical records using the unique personal identification number.
Comorbidities occurring prior to the PET/CT scan were identified using primary and secondary diagnoses registered in the EMR system. Comorbidities registered were diabetes mellitus, hypertension, and hyperlipidemia. The use of antihypertensive or lipid-lowering drugs at the time of the PET/CT scan was used as a proxy for a diagnosis of hypertension and hyperlipidemia if no primary or secondary diagnosis was registered in the EMR. Other demographic variables of interest collected were age, body mass index (BMI), sex, and smoking history.
Included patients were allocated to one of three groups: (1) a group of control patients comprised patients with no registered cardiovascular risk factors (diabetes mellitus type 2, hypertension, or hyperlipidemia) or known treatment thereof. (2) An “At-Risk” group of patients with one or more of the previously mentioned risk factors, but no confirmed previous ischemic event (myocardial infarction requiring either percutaneous coronary intervention or coronary artery bypass graft surgery, transient ischemic attack, or ischemic stroke). Patients in the “At-Risk” group were selected for availability of laboratory recorded values of plasma total cholesterol, high-density lipoprotein cholesterol, and systolic blood pressure measurements performed in a period of up to 6 months prior to the PET/CT scan, to allow for calculation of the 10-year Framingham risk score for cardiovascular disease.[19] (3) A group consisting of patients who had previously, prior to the [64Cu]Cu-DOTATATE PET/CT scan, experienced a minimum of one confirmed ischemic event.
If more than one [64Cu]Cu-DOTATATE PET/CT was available, the earliest was used for assessment.
Approval for this study and the disclosure of personal medical record data without informed consent were given by the Danish Patient Safety Authority (approval no: 31-1521-152) and did not require individual consent from the patients included.
Image acquisition and analysis
All included patients had whole-body PET/CT scans performed on a Siemens Biograph mCT 64 True Point hybrid PET/CT medical imaging system available for analysis. PET images were acquired 60-minute post-injection of 200 MBq [64Cu]Cu-DOTATATE. Images were reconstructed using the same standard algorithm used clinically (Point spread function, TrueX; Siemens Medical Solutions) using 3 iterations, 21 subsets, and a 2-mm Gaussian filter for smoothing (full width at half maximum). PET images were reconstructed using a low-dose non-contrast-enhanced CT-based attenuation correction. Diagnostic quality venous phase CT scans (slice thickness 2 mm) using iodine intravenous contrast was performed in succession with the PET scan and used for region of interest (ROI) tracing of the aorta and carotid arteries.
All PET/CT scans were analyzed using the Osirix MD imaging software platform ver. 11.0 (Pixmeo, Bernex, Switzerland). ROI’s were drawn on axial slices of the aorta and the carotid arteries. ROI’s of the aorta were drawn on both the ascending and descending portions of the aorta. ROI’s were drawn from 1 slice cranial to the aortic valve to the branching of the right renal artery of the descending aorta. In the carotids, ROI’s were drawn from 5 slices cranial to the carotid bifurcation, on the internal carotid artery, and downward to the aorta or subclavian artery. Standardized uptake values (SUV) were measured from each ROI. To account for background [64Cu]Cu-DOTATATE uptake, SUV values were divided with a background SUV value measured as the mean of 4 adjacent slices in the right atrium, to allow for calculation of target-to-background (TBR) values. [64Cu]Cu-DOTATATE TBR and SUV uptake values are reported as whole-artery maximum (SUVmax and TBRmax) and mean of max (mSUVmax and mTBRmax), where max values from all slices were averaged. Also, a most-diseased segment (SUVmds and TBRmds) of the artery approach, where the slice with the maximum SUV or TBR together with the 4 adjacent slices (2 on each side) was averaged, was also calculated and reported (Figure 2A). A representative example of the ROI’s drawn are shown in Figure 2B and C.
Statistical analysis
Statistical analysis was performed using the programming language R version 4.1.2 (R Foundation, Vienna, Austria) with the integrated development environment RStudio version 2021.09.1 (RStudio, Boston, USA). Continuous normally distributed variables are reported as means with standard deviation (SD) or 95% confidence intervals (CI), and nonnormally distributed variables are reported as medians and interquartile range [IQR]. Differences in [64Cu]Cu-DOTATATE PET uptake values between the three groups were assessed using a linear multiple regression model with age, sex, smoking history, and BMI as co-variates and uptake value as dependent variable. Results of the linear multiple regression analyses are reported as parameter estimates of difference between the groups (Controls vs At-Risk group or known CVD group) with corresponding 95% CI and P-values, after adjustment of the aforementioned co-variates.
A random subset of ~ 25% (n = 20) of the total number PET/CT scans were assessed by a second trained reviewer to allow for assessment of agreement by calculation of the intraclass correlation coefficient (ICC) with 95% confidence intervals based on a single rating, consistency, two-way mixed effects model, and Bland–Altman plots. Reviewers were blinded to group allocation. ICC agreement was interpreted according to the standards previously proposed.[20]
Receiver operator characteristics (ROC) analysis were made using uptake values from the controls and the known CVD group, and area under the curve (AUC) was calculated along with optimal cut-point values using the point closest to (0,1) corner in the ROC plane approach with corresponding specificity and sensitivity percentages. Two-sided P-values < .05 were considered significant.
Results
Patient clinical characteristics
A total of 79 patients with a [64Cu]Cu-DOTATATE PET/CT scans available for analysis were divided into the 3 groups: 33 patients with at least 1 documented previous ischemic event, 24 patients with CVD risk factors but no ischemic event, and 22 controls without known CVD risk factors. Clinical characteristics of the 3 groups are listed in Table 1. All patients had a diagnosis of NEN. Patients in the known CVD group were in general more likely to have received a diagnosis of hyperlipidemia and type 2 diabetes compared to the At-Risk group.
[64Cu]Cu-DOTATATE uptake of the carotid arteries measured as SUV
All unadjusted mean differences between the groups along with parameter estimates for the group differences from the multiple regression analyses are listed in Table 2.
PET uptake, measured as SUV metrics, in the carotid arteries showed a significant difference in SUVmax between the controls and the known CVD group and the At-Risk vs known CVD group, but not between the controls and At-Risk group (controls: 3.09 ± 0.63; At-Risk: 3.38 ± 0.79; known CVD: 3.68 ± 1.23) (Figure 3A; Table 2). Similarly, when measuring SUVmds (controls: 2.20 ± 0.28; At-Risk: 2.30 ± 0.49; known CVD: 2.54 ± 0.78) differences were observed between the controls and known CVD group and the At-Risk and known CVD groups, but not the controls and At-Risk group (Figure 3C; Table 2). Measurements of mSUVmax (controls: 1.60 ± 0.22; At-Risk: 1.65 ± 0.25; known CVD: 1.70 ± 0.38) displayed no differences between the groups (Figure 3B; Table 2). Unadjusted group means for all uptake values are also listed in Supplemental Table I.
[64Cu]Cu-DOTATATE uptake of the carotid arteries measured as TBR
Venous SUV background measures for calculation of TBR metrics were comparable between the groups (controls vs At-Risk: − 0.08, 95% CI [− 0.27 to 0.09], P = .34; controls vs known CVD: − 0.13, 95% CI [− 0.31 to 0.05], P = .15; At-Risk vs known CVD: − 0.04, 95% CI [− 0.21 to 0.12], P = .60).
Differences in TBR uptake metrics between the groups for the carotid arteries were observed between the controls and known CVD group with regards to both TBRmax (controls: 3.43 ± 0.90; At-Risk: 4.34 ± 1.80; known CVD: 4.66 ± 1.63), mTBRmax (controls: 1.77 ± 0.33; At-Risk: 2.07 ± 0.59; known CVD: 2.16 ± 0.60), and TBRmds (controls: 3.41 ± 0.78; At-Risk: 4.10 ± 1.51; known CVD: 4.32 ± 1.33) (Figure 3D-F; Table 2). No significant differences were observed when comparing the controls and At-Risk group, with regards to any of the uptake metrics. Trends toward significance were observed when comparing the At-Risk and known CVD groups with regards to TBRmax.
[64Cu]Cu-DOTATATE uptake of the aorta measured as SUV
Compared to uptake values from the carotids, values obtained from the aorta were largely observed to have higher values (Figures 3, 4).
[64Cu]Cu-DOTATATE uptake quantified by SUV in the aorta was generally observed to be higher in patients with known CVD compared especially to control patients and less compared to those At-Risk of CVD. Differences between groups were largest for SUVmax (controls: 4.27 ± 1.00; At-Risk: 4.67 ± 1.68; known CVD: 4.88 ± 1.61) and SUVmds (controls: 3.10 ± 0.62; At-Risk: 3.27 ± 0.98; known CVD: 3.42 ± 0.95) and negligible for the whole-artery mSUVmax (controls: 2.29 ± 0.51; At-Risk: 2.31 ± 0.40; known CVD: 2.33 ± 0.54) (Figure 4A-C; Table 2). We found no significant differences between any of the groups in the multivariate analyses, neither when assessing the whole-artery mSUVmax localized nor SUVmds measured in the aorta (Table 2).
[64Cu]Cu-DOTATATE uptake of the aorta measured as TBR
When calculating TBR uptake metrics differences between the groups were more evident than when using SUV metrics (Fig. 4 D-F). A significant difference was observed between the controls and Known CVD group with regards to TBRmds, while no difference was observed when comparing the controls with the At-Risk group and the At-Risk with the known CVD group (controls: 3.42 ± 0.78; At-Risk: 4.10 ± 1.51; known CVD: 4.32 ± 1.33). TBRmax (controls: 4.65 ± 0.98; At-Risk: 6.00 ± 2.93; known CVD: 6.12 ± 1.92) and mTBRmax (controls: 2.49 ± 0.46; At-Risk: 2.91 ± 0.87; known CVD: 2.93 ± 0.73) of the aorta did not show a significant difference between any of the groups (Table 2).
Reproducibility
The reproducibility (ICC) of the [64Cu]Cu-DOTATATE SUV measurements, of both the aorta and carotid arteries, between the 2 reviewers were excellent (Aorta: 0.97; 95%CI [0.96 to 0.98] and Carotids: 0.94; 95% CI [0.92 to 0.96]). Likewise, when measuring the TBR values, ICC of the aortic and carotid measurements were good and excellent, respectively (Aorta: 0.89; 95% CI [0.83 to 0.93] and carotids: 0.91; 95% CI [0.87 to 0.94]). Bland–Altman plots for both aorta and carotids regarding all uptake metrics are shown in Figure 5. Here, only small fixed and proportional biases were observed between the reviewers.
Optimal cut-point values
As an exploratory analysis, ROC curves were made for the PET uptake values that were observed to be significantly different between the controls and known CVD group in the multiple regression analysis. The area under the curve (AUC) for the TBR values were all similar (~ 0.73) as seen in Figure 6. AUCs for the significant SUV metrics were lower. Optimal cut-point values and corresponding specificity and sensitivity estimates are listed in Table 3. In line with the AUC measurements, greater specificity and sensitivity were achieved with the TBR metrics compared to SUV.
Discussion
Visualization and quantification of arterial atherosclerosis using multimodality PET have been investigated for the past 20 years, starting with the first reports using [18F]FDG as the tracer of choice.[21,22] Since then, both improvements in imaging methods and technological advancement have made PET more readily available, and novel radiotracers offer promise of more specific imaging of the physiological processes of atherosclerosis.[23]
In the present retrospective study, we observed a gradual increase in arterial uptake of [64Cu]Cu-DOTATATE from control patients without known CVD to patients at-risk and to patients with known CVD. The difference in carotid uptake between healthy controls and patients with known CVD was significant. The aortic uptake was higher than the carotid uptake, but with larger variance leading to mostly non-significant differences in the aorta between the groups.
Methods of tracer uptake quantification
Several methods have been used to quantify [18F]FDG uptake in previous studies. In the present study, we sought to investigate these methods when imaging atherosclerosis using the radiolabeled tracer [64Cu]Cu-DOTATATE in NEN patients with different degrees of CVD compared to controls with no known cardiovascular risk factors. PET [64Cu]Cu-DOTATATE imaging has previously been used to study atherosclerosis, but this is the first time that it has been used to investigate potential differences between retrospectively pre-defined groups with varying degrees of CVD.
When comparing uptake between the groups using the carotid arteries as the vessel of interest, significant differences between the controls and the known CVD group were observed for all uptake metrics except mSUVmax (Table 2). Comparisons between the at-risk and the known CVD group showed significant differences with regards to SUVmax and SUVmds.
The only uptake metric that showed a group-wise difference when using the aorta as the vessel of interest was TBRmds. None of the other uptake metrics measured in the aorta showed any difference as seen in Figure 4 and Table 2. It is worth noticing that in this study, a large portion of the aorta was quantified (both ascending and descending), compared to other studies using [18F]FDG that measured a smaller segment.[8,24] Analyzing the ascending aorta alone did not change these conclusions (Supplemental Figure I).
A variety of uptake metrics and vessels of interest have been used in other studies, and guidelines as to which metrics and vessels to image for quantification of atherosclerosis have been published for [18F]FDG-related imaging.[8,25] Similar recommendations do not exist for [64Cu]Cu-DOTATATE imaging. Based on our results, TBRmax or TBRmds measures in the carotid artery seem to be the most robust method for quantifying in vivo uptake of [64Cu]Cu-DOTATATE and detect differences in subjects with varying degrees of CVD compared to the mean-of-max approach. This point of view was further corroborated by ROC curve analyses, where TBRmax and TBRmds yielded the best results with respect to cut-point values and corresponding sensitivity and specificity. This is equivalent to the results previously found with [18F]FDG.[8]
It can be speculated that the differentiation between patients with or without CVD might have been improved in a prospective set-up, which would have made group allocation less prone to selection bias. In addition, allocation to the at-risk group in the present study was determined by the presence of one or more pre-defined risk factors for CVD, whereas a previous similar study investigating [18F]FDG allocated on the basis of two or more risk factors.[8]
Comparison to in vivo imaging using other PET tracers
[18F]FDG is the most thoroughly investigated radiolabeled tracer used for PET imaging in atherosclerosis, has shown the ability to detect differences in uptake between groups with varying degrees of CVD, and proven a valuable tool in detecting the effects of various drugs in relation to atherosclerosis.[8,9,24] Other tracers, in particular [18F]-sodium fluoride primarily related to micro calcification, have also been heavily investigated in the context of atherosclerosis and have shown promising results.[26] [64Cu]Cu-DOTATATE on the other hand offers the possibility of directly imaging-activated macrophages in atherosclerosis enabling a more specific approach as opposed to [18F]FDG.[15,27,28] The majority of research in the field of atherosclerotic PET imaging using SST2 ligand tracers has been done with 68Ga-labeled DOTATATE, and some studies have found correlations between [68Ga]Ga-DOTATATE PET uptake measures and CVD risk factors.[14,29]
Studies using 64Cu-labeled DOTATATE for PET imaging of atherosclerosis are sparse but as with 68Ga evidence suggests that uptake correlates with established risk factors of CVD.[11,16,30]
DOTATATE has also been shown to be a marker of specific macrophage activity in studies using both histological and cell-specific assays, where it also outperformed [18F]FDG as a marker of coronary inflammation.[12] Although, some early ex vivo studies did find low expression of the SST2 receptor on endothelial cells.[31,32] SST signaling in vascular tissue cells has been shown to serve an anti-inflammatory function, but the importance of this in relation to atherosclerosis and SST imaging has not yet been established.[33]
[64Cu]Cu-DOTATATE also has the distinct advantage of a shorter positron range (~ 1 mm) as opposed to its 68Ga-labeled counterpart (~ 4 mm). This offers better spatial resolution, which is of paramount importance when imaging smaller structures as arterial vessel walls, including coronary arteries, which has also been shown to be feasible using [64Cu]Cu-DOTATATE in patients with type 2 diabetes.]13,34]
As previously mentioned, another study investigated the performance and optimal metrics using [18F]FDG uptake as a marker of atherosclerotic inflammation. Compared to this, [64Cu]Cu-DOTATATE uptake might seem to have underperformed somewhat in the ability to discriminate between subjects with and without established CVD compared to [18F]FDG.[8] However, important differences in study design should be considered, as the present study is retrospective in its nature.
Another aspect that should be considered is the effective radiation dose observed when using the different radiotracers. The clinical [64Cu]Cu-DOTATATE PET used in the present study exposes the patients to approximately 6-7 mSv.[35] Because of methodological differences, the effective dose in atherosclerosis studies using [18F]FDG varies quite considerably between 4 and 7 mSv.[6,8,9,36] [68Ga]Ga-DOTATATE exposes patients to less radiation, with an effective dose of 3-5 mSv.[35,37] Hopefully, technological advances in scanner and image reconstruction technology will allow for PET imaging with lower radiation doses. This is also a prerequisite if atherosclerosis imaging using PET is to become a routine clinical examination.
Reproducibility
The results from the present study are in line with previous investigations that have shown the reproducibility of PET measurements in atherosclerosis to be excellent.[8,38] We did observe that the ICC was somewhat lower for the TBR measurements, probably due to the dependency of two measurements, as opposed to only one for the SUV’s, which should be considered when designing trials using [64Cu]Cu-DOTATATE TBR metrics as endpoints. No fixed or proportional bias was observed in the Bland–Altman analysis between the two reviewers, which testifies to the robustness of the methods. The contrast-enhanced PET/CT scans used in this study allow for good anatomical discrimination of the aorta and carotid arteries, but is not the standard when comparing to similar studies that most often use low-dose non-contrast-enhanced CT scans.[8,13,39] This might limit the generalizability of the results.
Limitations
Some limitations apply to the present study. Firstly, this is a retrospective study and all data were collected from electronic medical records, which makes it prone to selection bias. Furthermore, we did not assess any data beyond what was documented in the electronic medical records. Therefore, no predictive inferences can be drawn from it. Secondly, the patients included in this study were all diagnosed with NEN and received various treatments for this, which might have affected tracer uptake and limits the generalizability of the results to a broader population. It would have been a meaningful addition to evaluate the uptake of the coronary arteries between the groups, but the routine clinical PET/CT scan protocol used in this cohort of patients did not allow for coronary measurement due to lack of gating of respiratory and cardiac movement.
Conclusion
In the present study, we were able to demonstrate differences in some of the most frequently reported PET uptake metrics using [64Cu]Cu-DOTATATE as a marker of atherosclerotic inflammation in patients with different degrees of known CVD. Measurements of the carotid artery as either maximum uptake values or most-diseased segment analysis showed the best ability to discriminate between the groups. The present study paves the way for further prospective investigations to validate and establish the value of [64Cu]Cu-DOTATATE PET as a method for imaging and quantifying macrophage burden and therefore inflammation in atherosclerosis.
New knowledge gained
PET uptake measurements of the activated macrophage tracer [64Cu]Cu-DOTATATE are reproducible and able to demonstrate differences in vascular inflammation between groups with different degrees of CVD when using the most frequently reported uptake metrics.
References
Virani SS, Alonso A, Aparicio HJ, Benjamin EJ, Bittencourt MS, Callaway CW. Heart disease and stroke statistics-2021 update: A report from the American Heart Association. Circulation 2021;143:e254‐743.
Timmis A, Vardas P, Townsend N, Torbica A, Katus H, De Smedt D, et al. European Society of Cardiology: Cardiovascular disease statistics 2021. Eur Heart J 2022;43:716‐99.
Greenland P, Blaha MJ, Budoff MJ, Erbel R, Watson KE. Coronary calcium score and cardiovascular risk. J Am Coll Cardiol 2018;72:434‐47.
Sriranjan RS, Tarkin JM, Evans NR, Le EPV, Chowdhury MM, Rudd JHF. Atherosclerosis imaging using PET: Insights and applications. Br J Pharmacol 2019;178:2186‐203.
Koelwyn GJ, Corr EM, Erbay E, Moore KJ. Regulation of macrophage immunometabolism in atherosclerosis. Nat Immunol 2018;19:526‐37.
Moon SH, Cho YS, Noh TS, Choi JY, Kim BT, Lee KH. Carotid FDG uptake improves prediction of future cardiovascular events in asymptomatic individuals. JACC Cardiovasc Imaging 2015;8:949‐56.
Abdelbaky A, Corsini E, Figueroa AL, Fontanez S, Subramanian S, Ferencik M, et al. Focal arterial inflammation precedes subsequent calcification in the same location: A longitudinal FDG-PET/CT study. Circ Cardiovasc Imaging 2013;6:747‐54.
van der Valk FM, Verweij SL, Zwinderman KA, Strang AC, Kaiser Y, Marquering HA, et al. Thresholds for arterial wall inflammation quantified by (18)F-FDG PET imaging: Implications for vascular interventional studies. JACC Cardiovasc Imaging 2016;9:1198‐207.
Tawakol A, Fayad ZA, Mogg R, Alon A, Klimas MT, Dansky H, et al. Intensification of statin therapy results in a rapid reduction in atherosclerotic inflammation: Results of a multicenter fluorodeoxyglucose-positron emission tomography/computed tomography feasibility study. J Am Coll Cardiol 2013;62:909‐17.
Ripa RS, Zobel EH, von Scholten BJ, Jensen JK, Binderup T, Diaz LJ, et al. Effect of liraglutide on arterial inflammation assessed as [(18)F]FDG uptake in patients with type 2 diabetes: A randomized, double-blind, placebo-controlled trial. Circ Cardiovasc Imaging 2021;14:e012174.
Pedersen SF, Sandholt BV, Keller SH, Hansen AE, Clemmensen AE, Sillesen H, et al. 64Cu-DOTATATE PET/MRI for detection of activated macrophages in carotid atherosclerotic plaques: Studies in patients undergoing endarterectomy. Arterioscler Thromb Vasc Biol 2015;35:1696‐703.
Tarkin JM, Joshi FR, Evans NR, Chowdhury MM, Figg NL, Shah AV, et al. Detection of atherosclerotic inflammation by (68)Ga-DOTATATE PET compared to [(18)F]FDG PET imaging. J Am Coll Cardiol 2017;69:1774‐91.
Zobel EH, Ripa RS, von Scholten BJ, Curovic VR, Diaz LJ, Hansen TW, et al. Effect of liraglutide on vascular inflammation evaluated by [(64)Cu]DOTATATE. Diagnostics (Basel) 2021;11:1431.
Li X, Samnick S, Lapa C, Israel I, Buck AK, Kreissl MC, et al. 68Ga-DOTATATE PET/CT for the detection of inflammation of large arteries: Correlation with18F-FDG, calcium burden and risk factors. EJNMMI Res 2012;2:52.
Li X, Bauer W, Kreissl MC, Weirather J, Bauer E, Israel I, et al. Specific somatostatin receptor II expression in arterial plaque: (68)Ga-DOTATATE autoradiographic, immunohistochemical and flow cytometric studies in apoE-deficient mice. Atherosclerosis 2013;230:33‐9.
Malmberg C, Ripa RS, Johnbeck CB, Knigge U, Langer SW, Mortensen J, et al. 64Cu-DOTATATE for noninvasive assessment of atherosclerosis in large arteries and its correlation with risk factors: Head-to-head comparison with 68Ga-DOTATOC in 60 patients. J Nucl Med 2015;56:1895‐900.
Johnbeck CB, Knigge U, Loft A, Berthelsen AK, Mortensen J, Oturai P, et al. Head-to-head comparison of (64)Cu-DOTATATE and (68)Ga-DOTATOC PET/CT: A prospective study of 59 patients with neuroendocrine tumors. J Nucl Med 2017;58:451‐7.
Conti M, Eriksson L. Physics of pure and non-pure positron emitters for PET: A review and a discussion. EJNMMI Phys 2016;3:8.
D’Agostino RB Sr, Vasan RS, Pencina MJ, Wolf PA, Cobain M, Massaro JM, et al. General cardiovascular risk profile for use in primary care: The Framingham Heart Study. Circulation 2008;117:743‐53.
Koo TK, Li MY. A guideline of selecting and reporting intraclass correlation coefficients for reliability research. J Chiropr Med 2016;15:155‐63.
Yun M, Yeh D, Araujo LI, Jang S, Newberg A, Alavi A. F-18 FDG uptake in the large arteries: A new observation. Clin Nucl Med 2001;26:314‐9.
Rudd JH, Warburton EA, Fryer TD, Jones HA, Clark JC, Antoun N, et al. Imaging atherosclerotic plaque inflammation with [18F]-fluorodeoxyglucose positron emission tomography. Circulation 2002;105:2708‐11.
Tarkin JM, Dweck MR, Evans NR, Takx RA, Brown AJ, Tawakol A, et al. Imaging atherosclerosis. Circ Res 2016;118:750‐69.
Fayad ZA, Mani V, Woodward M, Kallend D, Abt M, Burgess T, et al. Safety and efficacy of dalcetrapib on atherosclerotic disease using novel non-invasive multimodality imaging (dal-PLAQUE): A randomised clinical trial. Lancet 2011;378:1547‐59.
Gholami S, Salavati A, Houshmand S, Werner TJ, Alavi A. Assessment of atherosclerosis in large vessel walls: A comprehensive review of FDG-PET/CT image acquisition protocols and methods for uptake quantification. J Nucl Cardiol 2015;22:468‐79.
Kwiecinski J, Slomka PJ, Dweck MR, Newby DE, Berman DS. Vulnerable plaque imaging using (18)F-sodium fluoride positron emission tomography. Br J Radiol 2020;93:20190797.
Armani C, Catalani E, Balbarini A, Bagnoli P, Cervia D. Expression, pharmacology, and functional role of somatostatin receptor subtypes 1 and 2 in human macrophages. J Leukoc Biol 2007;81:845‐55.
Dalm VA, van Hagen PM, van Koetsveld PM, Achilefu S, Houtsmuller AB, Pols DH, et al. Expression of somatostatin, cortistatin, and somatostatin receptors in human monocytes, macrophages, and dendritic cells. Am J Physiol Endocrinol Metab 2003;285:E344‐53.
Rominger A, Saam T, Vogl E, Ubleis C, la Fougere C, Forster S, et al. In vivo imaging of macrophage activity in the coronary arteries using 68Ga-DOTATATE PET/CT: Correlation with coronary calcium burden and risk factors. J Nucl Med 2010;51:193‐7.
Mojtahedi AAA, Sanjay T, Amerinia R, Ranganathan D, Tworowska I, Delpassand E. Assessment of vulnerable atherosclerotic and fibrotic plaques in coronary arteries using 68Ga-DOTATATE PET/CT. Am J Nucl Med Mol Imaging 2015;5:65.
Curtis SB, Hewitt J, Yakubovitz S, Anzarut A, Hsiang YN, Buchan AM. Somatostatin receptor subtype expression and function in human vascular tissue. Am J Physiol Heart Circ Physiol 2000;278:H1815‐22.
Adams RL, Adams IP, Lindow SW, Zhong W, Atkin SL. Somatostatin receptors 2 and 5 are preferentially expressed in proliferating endothelium. Br J Cancer 2005;92:1493‐8.
Badway AC, West FM, Tente SM, Blake AD. Somatostatin regulates intracellular signaling in human carotid endothelial cells. Biochem Biophys Res Commun 2004;319:1222‐7.
Jensen JK, Zobel EH, von Scholten BJ, Rotbain Curovic V, Hansen TW, Rossing P, et al. Effect of 26 weeks of Liraglutide treatment on coronary artery inflammation in type 2 diabetes quantified by [(64)Cu]Cu-DOTATATE PET/CT: Results from the LIRAFLAME trial. Front Endocrinol (Lausanne) 2021;12:790405.
Johnbeck CB, Knigge U, Kjaer A. PET tracers for somatostatin receptor imaging of neuroendocrine tumors: Current status and review of the literature. Future Oncol 2014;10:2259‐77.
Quinn B, Dauer Z, Pandit-Taskar N, Schoder H, Dauer LT. Radiation dosimetry of 18F-FDG PET/CT: Incorporating exam-specific parameters in dose estimates. BMC Med Imaging 2016;16:41.
Walker RC, Smith GT, Liu E, Moore B, Clanton J, Stabin M. Measured human dosimetry of 68Ga-DOTATATE. J Nucl Med 2013;54:855‐60.
Rudd JH, Myers KS, Bansilal S, Machac J, Pinto CA, Tong C, et al. Atherosclerosis inflammation imaging with 18F-FDG PET: Carotid, iliac, and femoral uptake reproducibility, quantification methods, and recommendations. J Nucl Med 2008;49:871‐8.
Kelly PJ, Camps-Renom P, Giannotti N, Marti-Fabregas J, Murphy S, McNulty J, et al. Carotid plaque inflammation imaged by (18)F-fluorodeoxyglucose positron emission tomography and risk of early recurrent stroke. Stroke 2019;50:1766‐73.
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JKJ, JSM, RR, and MJ have no conflicts of interest to disclose. AK, one of the initiators of the study, is an inventor/holds IPR on human use of [64Cu]Cu-DOTATATE in neuroendocrine tumor patients.
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The authors are supported by funding from the European Union’s Horizon 2020 research and innovation program under grant agreements no. 670261 (ERC Advanced Grant) and 668532 (Click-It), the Lundbeck Foundation, the Novo Nordisk Foundation, the Innovation Fund Denmark, the Danish Cancer Society, Arvid Nilsson Foundation, the Neye Foundation, the Research Foundation of Rigshospitalet, the Danish National Research Foundation (grant 126), the Research Council of the Capital Region of Denmark, the Danish Health Authority, and the John and Birthe Meyer Foundation and Research Council for Independent Research. Andreas Kjaer is a Lundbeck Foundation Professor.
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Jensen, J.K., Madsen, J.S., Jensen, M.E.K. et al. [64Cu]Cu-DOTATATE PET metrics in the investigation of atherosclerotic inflammation in humans. J. Nucl. Cardiol. 30, 986–1000 (2023). https://doi.org/10.1007/s12350-022-03084-4
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DOI: https://doi.org/10.1007/s12350-022-03084-4