Background

Coronary artery disease is a common disease in the world. Different methods such as exercise testing, electrocardiogram, single-photon diffusion tomography (SPECT), and cardiac angiography are used to diagnose CAD [1, 2]. Myocardial perfusion imaging (MPI) is widely used as a non-invasive clinical imaging technique for the diagnosis of coronary artery disease [3, 4, 5]. MPI in nuclear medicine consists of two steps: first is rest and the other is stress. Stress stage is done in two ways (drug stress or exercise).

In this phase, blood flow should increase. If the tide is reduced or limited, the vessels will be involved. The results are usually compared to the rest phase [6]. Two most commonly used radiopharmaceuticals in heart scans are Tc-99m sestamibi and Tc-99m tetrofosmin. For sestamibi, tetrofosmin, and thallium, uptake in the myocardium is proportional to blood flow. Both tetrofosmin and sestamibi are excited from the body through the hepatobiliary system into the intestine [7,8,9,10]. The heart is enclosed among the diaphragm and the intestine and the liver, and it is located on the diaphragm above the left edge of the liver and near the intestine. For this reason, the liver, bile duct, and intestine cause excessive radiation. Therefore, radioactivity in the sub-diaphragm region can change the results in heart scan studies and make it harder for nuclear medicine studies to achieve the desired goal. Due to the proximity of the liver and the intestine to the bottom of the heart, proper judgment can be severe in CAD cases [11, 12].

The emergence of unusual cardiac activity is predictable in the imaging of myocardial perfusion, so to provide high-quality images for comment, it is essential to remove the liver-bile duct and digestive tract [3, 7, 13].

Some foods and fluids have been used to reduce or eliminate this problem, which they increase radiopharmaceutical hepatobiliary and intestine transition, including drinking milk, eating high-fat foods, drinking milk and water, injections of cholecystokinin, and administration of metoclopramide in myocardial perfusion SPECT. Fatty foods release cholecystokinin (CCK) and increase secretion bile and evacuate the gallbladder whereby increased clearance hepatobiliary and reduced infracardiac activity [1, 11, 14, 15]. The main route of excretion of technetium, the liver, and the secondary route is the gastrointestinal tract. Increasing age leads to a decrease in the performance of these two systems. Increasing age leads to a decrease in the ability of the liver system to purify the material. Digestive motions of the gastrointestinal tract become ineffective as they age. As a result, increased intake of fatty acids leads to gastrointestinal complications in the elderly. On the other hand, a decrease in the function of these systems results in a decrease in the clearance of radioactive substances from the body of the elderly. In a study by Hofman et al., the group received the milk compared to the group that received the water, radiation was significantly reduced, but it did not improve the interpretation of the images [16,17,18]. The study by Boz et al. indicates that eating solid and liquid foods before the resting stage reduced intestinal activity in Tc-99m tetrofosmin myocardial perfusion [19, 20]. Also, Purbhoo et al. showed that diluted lemon juice and milk reduced significantly infracardiac radiation in myocardial perfusion scan with radiopharmaceuticals Tc-99m sestamibi, which this reduction in the milk group had been more prominent [21]. The purpose of our studies was to determine what steps should be taken before resting the SPECT myocardium so that we can reduce the side effects of the liver, intestine, and stomach interactions.

Methods

This study was performed on 30 patients (female /male) who were under MPI. We used the 2-day protocol and with the same injectable dose. At each phase of the patient’s scan (rest or stress), one of the two methods of extracardiac uptake discharge was used. According to previous studies, we used two methods for extracardiac uptake discharge. The first method is the use of profiterole with specific compounds (from butter). According to the recommendation of nuclear medicine technology: procedure and quick reference [6, 22], the second method is to use cold water before scanning [6]. For the same physiological conditions of the patient and a better comparison of the two methods of extracardiac uptake discharge, we used two methods for extracardiac uptake discharge in each of the two scan phases (rest, stress). The imaging process was carried out with the gamma camera at 60 min after the Tc-99m sestamibi injection. Finally, a nuclear medicine specialist reported a “reportable” factor for each scan. It should be noted that the nuclear medicine specialist did not know the protocol performed for each scan stage. The results were analyzed using the statistical software (SPSS 22).

We used a single head MIE for doing this research, and the software we used was Sintron 7. Reconstruction of images is done with the ECT program, and the factors used are as follows [23]:

Filter type

Butter worth

Method

FBP

Butter worth

#5

Cutoff frequency

0.4

Result

Twelve men and 18 women (30 patients) were examined for this test. Thirty scans were performed in a rest phase and 30 scans in the stress phase. To discharge the liver in a heart test, for each patient, each scan phase used one of two approaches. The two methods are drinking cold water and eating profiterole that was used in 28 scans of water (rest or stress) and 32 scans of the profiterole. We study “reportable factor.” From 24 male scans, fourteen men were reportable, and also, 26 women of 36 were reportable (Table 1). Also, we performed 30 scans at rest and 30 scans at stress that 22 of the rest scans and 18 of the stress scans were reportable (Table 2), as well as liver discharge in 28 scans by drinking water and 32 scans by eating the profiterole. Of the 28 scans, 20 scans can be reported, and of the 32 scans, only 20 scans were reported. The description stated in the text indicates that the data were not statistically significant, but those who used water had about 50% more chance of reporting and using water has better results (Table 3). We show four images of unreported (including fatty meals and water) examples in Figs. 1, 2, 3 and 4. It should be noted that all images of patients were examined by three physicians visually.

Table 1 Sex
Full size table
Table 2 Scan phase
Full size table
Table 3 Liver clearance agent
Full size table
Fig. 1
figure 1

Fatty meal (Non reportable)

Full size image
Fig. 2
figure 2

Fatty meal (Reportable)

Full size image
Fig. 3
figure 3

Water (Non reportable)

Full size image
Fig. 4
figure 4

Water (Reportable)

Full size image

Discussion

In many previous studies, various factors have been investigated by researchers. Things like using the UDCA in the survey of Sood [20] or using different filters in the survey of Shah [17]; however, research on food for better imaging has always been considered. A survey by Gholami et al. found that gender, age, and BMI did not significantly alter spectral imaging quality. On the other hand, there was a significant difference only in the group consuming milk compared to the control group. This is a confirmation of high-fat milk discharge performance in itself in nuclear medicine scans. Therefore, different substances can be compared to milk [1]. Hara et al. found that soda water increased intestinal activity and increased image quality at the time of imaging [7]. Also, Alice J. Vandongen et al. found that water and milk intake at specific times before scanning facilitated better image acquisition [14]. Boz et al. has been established that the consumption of solid foods and liquids causes gastric filling and changes in bowel movements resulting in better imaging [19]. In a 2017 study, Mohsen Qutbi also showed that consuming 2–4 glasses of water immediately before imaging can eliminate extracardiac activity in cardiac imaging [18]. All of these studies confirm the reason for our use of water as an alternative method of reducing extracardiac activity. In their research, Peace et al. investigated several factors affecting cardiac imaging and ultimately found no significant difference between water and milk intake [8]. We did not differ in the present study. However, in 2005, a survey by Dee Nandurkar and colleagues showed that the effect of drinking milk from consuming water for imaging the heart was more significant in nuclear medicine [16]. A comparison between two common interventions to reduce extracardiac disturbing activity was performed. According to the previous studies, fat meals could prompt radiotracer clearance from the liver. However, fat meals may led to some problems for patients, especially in elderly and in patients with gastrointestinal disorders. So looking for a safe approach with fewer side effects is interested in researchers. We compare cold water versus high-fat meal in this study. Finally, no remarkable difference for diagnostic report of myocardial perfusion imaging was noted among two interventions, but cold water has favorable outcomes with convenience for the patients in comparison to fat congaing meals. Further studies are needed to confirm these results and attempt to consider this approach as a standard intervention in the nuclear cardiology setting.

Conclusions

The results of this study showed that scans performed with the water groups had equal results with the fatty meal group. Water is better than fatty meals because of its ease of use and lower cost. Therefore, the use of water can be a good alternative for routine use in NM centers. Fatty meals can cause gastrointestinal side effects in patients, especially the elderly, and water is useable for everyone. Therefore, staffs are advised to use water because it has fewer side effects for patients.