Splenic switch-off as a novel marker for adenosine response in nitrogen-13 ammonia PET myocardial perfusion imaging: Cross-validation against CMR using a hybrid PET/MR device

Positron emission tomography myocardial perfusion imaging (PET MPI) is a robust and excellent tool for quantitative and semi-quantitative assessment of myocardial blood flow.1 Besides physical exercise or dobutamine stress, pharmacological vasodilators such as adenosine, regadenoson or dipyridamole are commonly used to induce coronary hyperaemia. However, adequate patient response to the latter is crucial to detect ischemia or reduced myocardial flow reserve (MFR), and conversely, an inadequate response might result in a false-negative result, decreased extent of ischemia or seemingly reduced MFR. Rates of up to 5% to 10% of false-negative MPI examinations have been reported,2,3 and up to one-third of these may be attributed to inadequate stress.4 Haemodynamic parameters such as an increase in heart rate or a drop in systolic blood pressure are commonly used to assess the response to vasodilators, however, whether this reflects true coronary response remains doubtful.5,6 Recently, for patients undergoing stress cardiac magnetic resonance (CMR), the splenic switch-off (SSO) sign, which is the visually assessed decrease in splenic enhancement during adenosine stress, has been proposed to be a marker for haemodynamic response. Its validity as a marker for adenosine response is based on the assumption that while adenosine receptor stimulation results in splanchnic vasodilation, the splenic circulation is not affected by this mechanism, potentially even showing an opposite reaction in the form of vasoconstriction.7,8 The utility of SSO for identifying inadequate adenosine response in CMR was first described in the CE-MARC study cohort, where significantly more false-negative than true negative exams failed to show the sign.9 A subsequent study in a real-world population also showed an increased prevalence of SSO in true positive as compared to false-negative CMR exams, although not reaching statistical significance.10

In the present study, we test the hypothesis that similarly to CMR, SSO can be assessed in nitrogen-13 ammonia PET MPI. To this aim, we assessed patients undergoing simultaneous CMR and PET MPI with adenosine-induced stress on a hybrid PET/MR device with co-injection of a gadolinium-based contrast agent (GBCA) and nitrogen-13 ammonia using SSO in CMR as the standard of reference.

All 50 patients successfully underwent adenosine stress PET/CMR. Detailed patient baseline characteristics are given in Table 1.

Positive SSO in CMR was found in 37 patients (74%). SIR, as derived from CMR, was significantly lower in patients with positive versus negative SSO (0.57 [IQR 0.49 to 0.62] vs 0.89 [IQR 0.76 to 0.98]; P < .001; Figure 3a). Similarly, SAR, as derived from PET, was significantly lower in patients with positive versus negative SSO (0.4 IQR [0.32 to 0.45] vs 0.8 IQR [0.47 to 0.98]; P = .001; Figure 3b). ROC analysis revealed an area under the curve of 0.87 for SAR to detect positive SSO and a cut-off value of 0.46 (Figure 3c). Using this threshold, a sensitivity of 81%, specificity of 85%, PPV of 94% and NPV of 61% were calculated. SSO and SAR ≤ 0.46 showed moderate agreement (κ = 0.58, P < .001). SIR and SAR showed a weak, but statistically significant correlation (σ = 0.38, P = .007; Figure 4).

SLR_Stress was significantly lower than SLR_Rest (0.75 [IQR 0.55 to 1.15] vs. 2.05 [IQR 1.7 to 2.36]; P < .001). SLR_Rest did not differ significantly between patients with positive versus negative SSO (2.05 [± 0.49] vs. 2.12 [± 0.55]; P = .666; Figure 5a). SLR_Stress was significantly lower in patients with positive versus negative SSO (0.68 [IQR 0.51 to 0.91] vs. 1.5 [IQR 0.98 to 1.83]; P < .001; Figure 5b). ROC analysis for SLR_Stress to detect positive SSO showed an area under the curve of 0.83 and a cut-off value of 0.92 (Figure 5c). Using this threshold, a sensitivity of 78%, specificity of 85%, PPV of 94% and NPV of 58% were calculated. SSO and SLR_Stress < 0.92 showed moderate agreement (κ = 0.55, P < .001).

SLR_Stress/Rest was significantly lower in patients with positive versus negative SSO (0.32 [IQR 0.25 to 0.44] vs. 0.74 [IQR 0.36 to 1.05]; P = .002; Figure 6a). The ROC analysis for SLR_Stress/Rest to detect positive SSO showed an area under the curve of 0.79 and a cut-off value of 0.46 (Figure 6b). Using this threshold, a sensitivity of 78%, specificity of 69%, PPV of 88% and NPV of 53% were calculated. SSO and SLR_Stress/Rest < 0.46 showed moderate agreement (κ = 0.43, P < .01).

Mean MFR was significantly higher in patients with positive vs negative SSO in CMR (3.38 ± 0.86 vs 2.53 ± 0.84; t = 3.09, df = 48, P = .003). Similarly, in patients with SAR ≤ 0.46 (positive SAR), the mean MFR was significantly higher than in patients with SAR above this threshold (3.43 ± 0.82 vs 2.69 ± 0.95; t = 2.87, df = 48, P = .006). In patients with SLR_Stress < 0.92, the mean MFR was significantly higher than in patients with SLR_Stress above this threshold (3.52 ± 0.82 vs 2.58 ± 0.81; t = 3.94, df = 48, P < .001). In patients with SLR_Stress/Rest < 0.46, the mean MFR was significantly higher than in patients with SLR_Stress/Rest above this threshold (3.41 ± 0.90 vs 2.69 ± 0.80; t = 2.77, df = 48, P = .008).

To the best of our knowledge, this is the first study demonstrating the feasibility of detecting and quantifying SSO in adenosine stress nitrogen-13 ammonia PET MPI. We established a novel indicator for the presence of SSO in nitrogen-13 ammonia PET: the SAR, which was calculated by dividing the peak splenic activity during stress over the peak splenic activity at rest similar to the SIR in CMR. A SAR of 0.46 was found to be a highly accurate threshold to differentiate positive from negative SSO, as depicted in CMR. It should be noted that the results relate to the prediction of the visual interpretation of SSO and not directly to the vasodilator efficacy. Nevertheless, the study provides evidence that PET-derived quantitation of spleen activity in the form of SAR provides similar information on the adequacy of adenosine response as the MR-derived SSO.

We have applied a comparable and easy measurable method for quantification of SAR using peak activity measurements, as shown for SIR in CMR.9,10 These quantification methods resulted in some overlap in results as compared to visual SSO in CMR. This could be due to the fact that both timing and intensity can influence the interpretation of visual splenic switch-off, as opposed to SIR and SAR, which are derived from single data points. In further studies, using coronary anatomy as the standard of reference, alternative methods of quantification, i.e. the integral of the splenic activity over time, or kinetic parameters could be investigated. In contrast to CMR, where the same dose of a gadolinium-based contrast agent is injected for stress and rest, different activities of the tracer are usually administrated for stress and rest examinations in nitrogen-13 ammonia PET. Therefore, it is crucial to convert activity values of the datasets into SUV, in order to enable splenic activity comparison. This can be done using PET scanners undergoing routine quality control including dose calibration and commercially available software. The nitrogen-13 ammonia dose used for SUV calculations in our study was corrected with residual dose measurements in case if manual injections, or an automatic dose drawing system was used, with no residual dose measurements. The residual dose in the patient line and intravenous cannula was not measured, also an approximated time of 1 minute between the dose measurement and injection was used. Since this approach was used in both, the stress and rest acquisitions, there was no systemic bias influencing the ratio of splenic activities. Also the doses individually were within the linear sensitivity spectrum of the scanner, therefore we can assume that this approach works correctly. Alternatively, organs like the liver can be used as a reference allowing the calculation of dose-independent ratios. Therefore, we additionally showed that the median spleen-to-liver activity ratio under stress was significantly lower in patients with visual SSO in CMR compared to patients without visual SSO.

Only two patients in our study had impaired MFR, which did not allow for statistical analysis of the differences in SAR, or SLR between patients with normal and impaired MFR in this population. In the two patients with impaired MFR, the threshold for SAR correctly differentiated a true positive from false positive: Invasive coronary angiography of one patient with an MFR of 1.11 and a SAR of 0.41 (i.e. positive SAR) revealed obstructive multivessel CAD. By contrast, in the second patient (21-year old, with no cardiovascular risk factors except light smoking) with impaired MFR of 1.64 but a SAR of 0.93 (i.e. negative SAR), coronary computed tomography showed normal coronary arteries, suggesting inadequate adenosine response as the reason for the false-positive PET finding (Figure 7). As SAR is a novel parameter, it has not yet been used in MPI PET. However, the clinical advantage of SAR might warrant its implementation, especially in patients with reduced MFR in whom an adenosine non-responder or inadequate response cannot be excluded. Taking into account that a considerable number of patients might be understressed,2‐4 a novel marker in nitrogen-13 ammonia MPI PET would be more than welcome to differentiate truly from seemingly reduced MFR. This can help to further improve the already established substantial diagnostic and prognostic value of MFR in nitrogen-13 ammonia MPI PET.13

In our cohort, mean MFR in PET was significantly higher in patients with a splenic SAR ≤ 0.46 (i.e. positive SAR) as compared to patients with a SAR > 0.46 (i.e. negative SAR). This was also true for the other activity ratios in PET MPI: SLR_Stress and SLR_Stress/Rest. The conclusion that this observation might be due to a more pronounced coronary adenosine response has to be drawn with caution as MFR can be reduced in patients with an adequate adenosine response due to severe CAD or microvascular dysfunction. Also, although SAR showed the best agreement with visual SSO in CMR, patients with SLR_Stress < 0.92 and SLR_Stress ≥ 0.92 showed the most significant differences in MFR, suggesting the best correlation with the haemodynamic response to vasodilator stress. All three activity ratios should be compared, when validating SSO in PET MPI against coronary anatomy.

There is growing evidence about the incremental value of SSO in stress CMR to predict adequate adenosine response,9,10,14,15 although there is also literature demonstrating that SSO in CMR failed to predict false-negative adenosine results after caffeine intake.16 Only one study examined this phenomenon in Rb-82 PET MPI, 17 despite the fact that initial observations about reduced splenic tracer activity during stress have been described in 1984.18 In line with the former CMR studies, Bami et al found an incremental prognostic value of a splenic response ratio in PET.17 However, this PET study did not aim at cross-validation versus a standard of reference, while the simultaneity of assessment of both markers through co-injection and use of a hybrid PET/MR device virtually excluded intrapatient variability of adenosine response in our study. Prognostic outcomes were not the subject of our study, as the population was not representative of a typical population of patients undergoing PET MPI.

Compared to CMR studies by Manisty et al (90%) 9 and Hoskins et al (89%), 10 positive SSO in our study was less frequent. Reasons for the slightly lower prevalence (74%) in our cohort might be the different doses of adenosine used in the studies. While we used a fixed adenosine infusion dose of 140 μg·kg⁻¹·min⁻¹, both other studies titrated adenosine up to 175 μg·kg⁻¹·min⁻¹. Indeed, current guidelines for nuclear cardiology procedures recommend a fixed infusion of 140 μg·kg⁻¹·min⁻¹ adenosine,19 supported by the fact that uptitrating adenosine beyond this point does not result in further hyperaemia,20 even though an increase in the rate of SSO can be observed.21 In accordance with this, only two patients in our study showed a reduced MFR, while one of those should be considered a true non-responder.

SSO in PET MPI, as derived from SAR, corresponds with SSO in CMR and can be used as a marker for adequate adenosine response.

The low patient number may be perceived as a limitation of our study. However, as a pilot study used for the initial validation of SAR in selected patients undergoing hybrid PET/MR MPI, we believe that it allows drawing the above conclusions. Furthermore, we did not assess the predictive value of SAR to identify non-responders as only two patients had an impaired MFR. The patient population, consisting of both patients with coronary artery disease, as well as myocarditis may not be representative of patients undergoing routine PET MPI, so the applicability of the results should be verified in further studies, also including patients not abstaining from caffeine. It should be also noted that while the results of our study may be applicable to patients undergoing dipyridamole stress, the splenic switch-off sign is not observed after administration of regadenoson due to its selective receptor affinity or during dobutamine stress.7,9 Furthermore, since this study demonstrated the feasibility of detecting SSO in PET MPI as defined by visual SSO in CMR, further assessment of this sign using invasive coronary angiography and coronary computed angiography as an anatomical correlate is needed. Finally, our binary system of categorizing patients as responders and non-responders might be an over-simplification as a more graded adenosine response is suggested by some studies, depending on receptor density and responsiveness of adenosine receptors, as well as the distribution of SIR and activity ratios in our study suggest a graded response of splenic perfusion to adenosine stress.

Similarly to CMR, SSO can be detected in nitrogen-13 ammonia PET MPI. This might help distinguish adenosine non-responders from patients with truly impaired MFR due to microvascular dysfunction or multivessel CAD.