Small-animal SPECT and SPECT/CT: application in cardiovascular research

SPECT is based on the molecular tracer principle and detection of gamma rays by radiolabelled molecules. The suitable energy range of gamma rays for clinical SPECT is typically around 60–300 keV. Due to the small size of rats and mice, isotopes with much lower energies (e.g. ¹²⁵I, with 27–35 keV) can be employed in microSPECT, which would not be useful for imaging in patients. For obtaining tomographic images, tens up to hundreds of projection images of the animal are acquired with position-sensitive gamma-detectors. Today almost all small-animal SPECT is performed with pinhole collimators, since these collimators provide a much better noise resolution trade-off in small objects than parallel hole or fan-beam collimators that are commonly used in clinical cardiac SPECT. Most small-animal SPECT systems rotate either the detector and collimator or the object [4‐12]. Stationary small-animal pinhole SPECT systems [13‐17] do not need to be rotated since they use detector set-ups that cover 360° and many pinholes to provide a large number of projection angles under which the animal is observed. They also have the advantage that dynamic imaging is possible with arbitrarily short frame lengths [15, 18, 19].

The full 360° coverage in combination with many focusing micropinholes and a high magnification factor to maximize the information content per photon provide a very high reconstructed image resolution. Multiple projections from different angles that can be acquired at the same time in such systems facilitate excellent ECG-gated myocardial imaging in rats and mice, which have heart rates of around 300 and 600 beats per minute, respectively. For instance, the U-SPECT-II system (MILabs, The Netherlands) has 75 pinholes on its interchangeable cylindrical collimators (Fig. 1), and is based on three ultralarge NaI scintillation gamma-cameras. Reconstructed images can reach resolutions of ≤0.35 mm and 0.45 mm anywhere in the body using the mouse collimators with 0.35 mm and 0.6 mm gold pinhole apertures, respectively, and ≤0.8 mm with the standard total body rat collimator. It is expected that dedicated high-resolution detectors will contribute to further improvement in multipinhole SPECT resolution, thereby expanding the field of application of microSPECT. In addition, dedicated collimators to image specific organs are under development, and these can dramatically boost performance. Overviews and primers of pinhole SPECT technology have been provided by some investigators [20, 21].

In contrast to PET, dual-tracer or triple-tracer images can be readily obtained with SPECT. Multitracer imaging results in shorter acquisition times and perfect registration of images in space and time, and each tracer represents a different biological process. Another advantage of SPECT is that radiotracers can be produced more easily in the laboratory without the need for a cyclotron, so that the cost-effectiveness of SPECT is higher than that of PET. Clinical PET systems have a much higher resolution than SPECT, but this is reversed for microSPECT since the best resolution of commercial microPET systems is still above 1 mm [22, 23].

Perfusion SPECT provides valuable information for the diagnosis of patients with coronary artery disease (CAD). For example, in triple vessel disease, in which tracer delivery to the whole myocardium is diminished due to balanced hypoperfusion, SPECT images may be interpreted as normal in qualitative or semiquantitative image analysis because comparison of the defective area with the region of the most intense uptake will not show any difference from normal. Absolute quantification of tracer uptake, which measures megabecquerels of tracer uptake per gram of tissue, can solve this problem [24]. The most prominent obstacles to absolute quantification in clinical SPECT used to be photon absorption and scattering, but today these problems are much smaller: SPECT systems equipped with transmission sources or, more recently, integrated with CT scanners are on the market [25‐28]. These allow accurate correction for attenuation, and also use accurate methods to correct for scatter and collimator and detector blurring [29‐38]. Cardiac and respiratory movements also degrade quantification, but both could be dealt with through (dual) gating as used in microPET imaging [39]. Although significant technical improvements for absolute quantification of myocardial perfusion using microSPECT have been introduced in recent years, the “roll–off” phenomenon with typical commercial SPECT perfusion agents under hyperaemic conditions, even in humans with less myocardial blood flow than mice, still remains a limitation for accurate measurement in myocardial perfusion imaging.

Quantification errors due to scatter and attenuation do degrade small-animal studies to a much lesser extent than in clinical SPECT because of less photon attenuation in small bodies (about 25% in the centre of a rat body when imaging with ^99mTc [40]). MicroCT imaging is able to provide photon attenuation information which can be used for nonuniform attenuation correction in microSPECT. However, several studies [40, 41] have shown that uniform attenuation correction (which may be based on the animal’s body contour) may reduce quantification errors from more than 10% to less than 5%. Therefore, a CT scan that adds dose and needs additional scanning equipment and scan time may be unnecessary. A webcam-based correction has been proposed [41].

Multimodal imaging can rely on separate devices (Fig. 2a) in which images are fused through markers [42, 43], or marker-free methods in which the spatial relationship between beds is known through calibration [42, 44]. The accuracy of registration can be very satisfactory (0.2 mm), and an advantage is that SPECT and CT can be used in parallel, and are individually upgradable. Also registration with other systems such as MRI can be based on the same principles. The advantage and disadvantages of both approaches have been discussed [34, 45].

An attractive aspect of high-resolution integrated microSPECT/CT devices [46‐49] (e.g. Fig. 2b) is that the bed with the fixed animal does not have to be moved from one scanner to another. Integrated SPECT/CT, in which the bed moves through both the SPECT and the CT scanner is very convenient, although this approach is hard to extend to MRI, and image registration is still needed to obtain accurately matched combined images.

The translatability of the cardiovascular systems of small animals including mice and rats to the human cardiovascular system and the exceptional characteristics of modern microSPECT and multimodality imaging approaches provide promising opportunities in preclinical cardiovascular research. Novel microSPECT systems can provide quantitative images, and can perform longitudinal studies in the same animal, a high pinhole magnification factor resulting in high resolution, possibly dynamic imaging, and multitracer imaging. MicroSPECT and microSPECT/CT systems have a wide range of applications in preclinical cardiovascular research, including investigation of myocardial left ventricular (LV) parameters such as ejection fractions and volumes, cardiac innervation parameters, vascular and atherosclerosis parameters, and the timing of administration and dose of novel radiotracers and biomarkers.

The autonomic nervous system plays an important role in cardiovascular diseases. Disturbances in function and integrity, as well as enhanced sympathetic activity may lead to numerous heart pathologies. Therefore, evaluation of the sympathetic innervation of the heart could provide important data on the aetiology and progress of heart diseases. It might also provide a tool for noninvasive assessment of novel therapeutic approaches targeting sympathetic nervous system activity, and also assessment of the side effects of drugs on cardiac adrenergic function. ¹²³I-labelled metaiodobenzylguanidine (¹²³I-MIBG), an analogue of the false neurotransmitter guanethidine, has been used clinically for sympathetic neuronal activity and integrity since the 1980s. Presynaptic sympathetic nerve terminals can take up and store MIBG in the same way as norepinephrine. Thus, MIBG uptake and washout rate can be influenced by sympathetic tone and the integrity of nerve terminals. Studies using ¹²³I-MIBG in animal models of coronary artery occlusion have revealed more extended nerve damage than myocardial injury in MI [95]. Also, some investigations have focused on the role of denervation in diabetic heart disease and cardiomyopathy [96]. ¹²³I-MIBG uptake defects have also been shown to be related to arrhythmogenesis in the heart after CAD, cardiomyopathy and other cardiac pathologies [97]. Due to more favourable properties of ^99mTc-bound radiopharmaceuticals compared with ¹²³I-based tracers, Samnick et al. labelled 1-(4-fluorobenzyl)-4-(2-mercapto-2-methyl-4-azapentyl)-4-(2-mercapto-2-methylpropylamino)-piperidine (FBPBAT) with ^99mTc and compared its characteristics in the assessment of cardiac adrenergic function in the rat with those of ¹²³I-MIBG [98]. They used rat models pretreated with α1 and β1 inhibitors and acquired SPECT images after radiopharmaceutical incubation. ^99mTc-FBPBAT showed higher uptake than ¹²³I-MIBG. ^99mTc-FBPBAT also had more cardiac adrenergic specificity. Moreover, ^99mTc-FBPBAT targeted postsynaptic adrenoreceptors, whereas ¹²³I-MIBG was absorbed via a presynaptic uptake I route. In another study, the average effective dose of ^99mTc-FBPBAT was shown to be less than half that of ¹²³I-MIBG [99]. These studies encourage further investigations of ^99mTc-based radiopharmaceuticals for SPECT studies of cardiac adrenergic innervation [97].