Validity of the γ-Ray Evaluation with iodoamphetamine for Cerebral Blood Flow Assessment (REICA) method for quantification of cerebral blood flow including acetazolamide challenge test

A total of 59 patients (22 males and 37 females; mean age 59.7 ± 17.5) who underwent simultaneous GP and ARG procedures between August 2018 and November 2019 were included in the study (Table 1). Rest/stress examinations of the same patient were performed at intervals of 7 days or less. Diseases among the included participants were Moyamoya disease (18 patients), middle cerebral artery stenosis or occlusion (20 patients), carotid artery stenosis or occlusion (16 patients), and other vascular disorders (5 patients).

For the clinical images in this study, care was taken to protect personal information to prevent the identification of participants. This study was conducted in accordance with the Declaration of Helsinki 1975, as revised in 2000. The Ethics Review Committee of National Hospital Organization Kyushu Medical Center approved the utilization of data (Approval no. 19C203) and waived the need for patient consent for the utilization of existing data (the retrospective study).

The dynamic planar protocol (Fig. 1) was used as previously reported [14]. Dynamic frontal planar scans (2 s/frame, 60 frames, 3.9 mm/pixel) were acquired using a γ-camera (Siemens E.CAM, Siemens Medical Solutions, Erlangen, Germany) equipped with a low-energy high-resolution collimator from intravenous administration of a 167 MBq ¹²³I-IMP. The rest and stress data were acquired using the same γ-camera. Arterial blood samples were measured for γ-ray radiation counts using a well-type scintillation measurement device (NDW-351F; Hitachi Aloka Medical, Ltd.). The arterial blood samples were taken 10 min after the ¹²³I-IMP administration, and the input function values were obtained from the average of four measurements of radioactivity concentration per 1.0 g. To obtain stress data, 15 mg/kg of ACZ was injected intravenously 10 min before the administration of ¹²³I-IMP, and blood samples were collected under the same conditions as rest data. The image reconstruction method is filtered back projection, the reconstruction filter is ramp, and the preprocessing filter is Butterworth (cutoff 0.35 cycle/cm; order 8). Chang’s method was adopted for attenuation correction, and the attenuation coefficient was set to 0.07/cm. Scattering correction was not performed.

The REICA method was used for data analysis in this study. Regions of interest (ROIs) were selected for the pulmonary artery trunk, brain, and lungs. The time-activity curves (TACs) calculated by the ROI was smoothed with a low-pass filter to reduce statistical noise. After that, a time zero adjustment was performed when sharp increases in activity were observed [13, 16]. In this study, \(\left( {\frac{{\mathop \smallint \nolimits_{0}^{t} C_{{\text{r}}} \left( \tau \right){\text{d}}\tau }}{l\left( t \right)},\;\frac{{C_{{\text{b}}} \left( t \right)}}{\lambda l\left( t \right)}} \right)\) was plotted, and the slope of the linear section was determined. C_r(t) denotes tracer activity in the pulmonary artery, l(t) denotes activity in the lungs, C_b(t) denotes activity in the brain, and λ denotes lipophilic fraction of ¹²³I-IMP [14, 15].

The ARG method was performed using the built-in software (Syngo MI Applications®, Siemens Medical Solutions, Erlangen, Germany). The volume of distribution (Vd) value was set to 40. For the quantitative SPECT images obtained by the ARG method, ROIs were set on the normal side of the brain parenchyma nuclei in the basal ganglia slice, and mean CBF (mCBF) by the ARG method was obtained.

The GP method was analyzed using dedicated software Hayabusa (AZE VirtualPlace Hayabusa®, AZE, Tokyo, Japan). For the analysis, ROIs were set in the pulmonary artery and basal ganglia, respectively. For each ROI, the standardized F (SFR, F = Cerebral blood flow index) was obtained using the TACs of the pulmonary artery as the input function and the TACs of the brain as the output function. The mCBF was calculated from SFR using a conversion formula. The conversion equation for the GP method is as follows [17]:

The CVR for stress data obtained after injection of ACZ is calculated using the following equation [6]:

The mCBF value acquired using the ARG method was used as the reference standard.

The data, including significance levels, were analyzed using Excel® 2016 (Microsoft Corporation, Redmond, WA, USA).

Figure 2 shows the relationship between mCBF measured using the REICA and ARG method and mCBF measured using the GP and ARG method for 92 acquisition (rest: 57, stress: 35). The linear regression and correlation coefficients (r) were as follows: REICA and ARG method, y = 1.17 x−1.59, r = 0.792, p = 5.96 × 10^–21; GP and ARG method, y = 0.634 x + 25.6, r = 0.636, p = 1.01 × 10^–11. Furthermore, the difference between the two correlation coefficients was significant at p = 7.30 × 10^–3, indicating that the REICA method had a stronger correlation with the ARG method than the GP method. The slope of the linear regression for the REICA method was closer to 1.0 and the intercept to 0.0 than those of the linear regression for the GP method.

Figure 3 shows the results of the CVRs of REICA and ARG, of GP and ARG for the data of 33 patients. The respective linear regression and correlation coefficients were as follows: REICA and ARG method, y = 1.11 x + 6.93, r = 0.660, p = 2.96 × 10^–5; GP and ARG method, y = 0.642 x + 4.25, r = 0.578, p = 4.28 × 10^–4. Compared with the GP method, the REICA method yielded positive CVR values, and the slope of the linear regression equation was close to 1.0.