The future of hybrid imaging—part 1: hybrid imaging technologies and SPECT/CT

Historically, medical devices to image either anatomical structure or functional processes have developed along somewhat independent paths. The recognition that combining images from different techniques can nevertheless offer significant diagnostic advantages gave rise to sophisticated software techniques to co-register structure and function retrospectively [8, 9]. The usefulness of combining anatomical and functional planar images was evident to physicians as early as the 1960s [2]. In addition to simple visual alignment, or the use of stereotactic frames that are undesirable or inconvenient for diagnostic imaging, sophisticated image fusion software was developed from the late 1980s onwards. For relatively rigid objects such as the brain, software can successfully align images from MR, CT and PET, whereas in more flexible environments, such as the rest of the body, accurate alignment is difficult owing to the large number of possible degrees of freedom.

Alternatives to software-based fusion have now become available through instrumentation that combines two complementary imaging techniques within a single gantry, an approach that has since been termed “hardware fusion” (Fig. 2). A combined, or hybrid, tomograph such as SPECT/CT or PET/CT can acquire co-registered structural and functional information within a single study. The data are complementary allowing CT to accurately localise functional abnormalities and SPECT or PET to highlight areas of abnormal metabolism.

As a result, following their introduction into the clinic, combined PET/CT and SPECT/CT devices are now playing an increasingly important role in the diagnosis and staging of human disease. Recently, the first clinical PET/MR prototype systems have started to undergo clinical evaluation and, furthermore, other imaging combinations are being discussed.

The Hawkeye has experienced increasing popularity for SPECT where even low-resolution anatomy can have a significant impact on image interpretation. Numerous studies performed on Hawkeye systems have confirmed the utility of co-registered anatomical information for the interpretation of SPECT images [13, 16].

The introduction of SPECT/CT in 2004 offers physicians the additional choice of a fully clinical CT study aligned with the SPECT study. SPECT imaging has access to a much wider range of clinically established biomarkers and radiopharmaceuticals than clinical PET, which, today, is limited mainly to [¹⁸F]FDG (FDG) for glucose utilisation and ⁸²Rb for cardiac perfusion studies. The fusion of CT and SPECT images from stand-alone systems has already demonstrated clinical utility [17]. Thus, hardware fusion of SPECT with a 16-slice CT offers interesting further possibilities for cardiac SPECT. The combination of calcium scoring from CT and a cardiac SPECT study with ²⁰¹Tl for tissue viability and ^99mTc-sestamibi for perfusion is an attractive possibility.

Some of the SPECT tracers are highly specific to the disease process and the corresponding images offer little or no anatomical information compared with an FDG whole-body study. Examples of such specific biomarkers include ¹²³I and ¹³¹I for metastatic thyroid disease and ¹³¹I-labelled cholesterol for adrenal studies. SPECT/CT can also play an important role in imaging benign and malignant bone disease most commonly with ^99mTc-methylene diphosphonate (^99mTc-MDP) to distinguish foci of increased metabolism [18], and neuro-endocrine tumour imaging with ¹¹¹In-octreotide, ¹¹¹In-pentetreotide or ¹²³I-MIBG where uptake can be highly tumour-specific and impossible to localise anatomically without the co-registered CT [16, 19]. In bone imaging, for example, combined SPECT/CT may improve diagnostic accuracy compared with SPECT only [20, 21] and help distinguish between osteomyelitis, aseptic necrosis and metastatic disease. As with PET/CT, SPECT/CT has been shown to be beneficial in recurrent head and neck cancer imaged with ¹²³I-IMT {L-3[¹²³I]-iodo-alpha-methyl tyrosine (IMT)-SPECT}. The accuracy of sentinel node mapping is improved by accurately localising the affected nodes (Fig. 5). The co-registered CT should also improve the diagnostic accuracy of ¹¹¹In-capromab pendetide (ProstaScint) imaging for prostate cancer, a disease for which FDG-PET is of questionable value although other PET biomarkers not yet clinically available show some promise. Finally, myocardial perfusion scintigraphy by SPECT is one of the most widely used and well established non-invasive tools for the diagnosis of ischaemic heart disease with a documented high diagnostic accuracy [22]. The first promising results with ⁸²Rb-PET perfusion imaging [23] notwithstanding, combined SPECT/CT imaging can provide such unique complementary information on coronary anatomy as well as on pathophysiological lesion severity, which improves diagnostic assessment and risk stratification and helps make decisions with respect to revascularisation in patients with coronary artery disease. Furthermore, SPECT/CT helps to overcome heterogeneous photon attenuation in the thorax—one of the most notable limitations of myocardial perfusion scintigraphy. The integration of CT data for attenuation correction (Fig. 4) supports clinically relevant improvements in diagnostic testing [24, 25].

Most of these earlier publications are from studies performed with Hawkeye systems and, therefore, the addition of clinical CT to SPECT can only enhance the results obtained to date. As the installed base of SPECT/CT systems grows, publications documenting the benefits will no doubt appear in the literature [21, 26].

With routine availability of CT-based attenuation correction SPECT/CT has been widely adopted in favour of SPECT-only imaging. However, unlike PET/CT which has replaced most standalone PET-only systems, SPECT/CT is unlikely to replace all, or even most SPECT. When compared to PET/CT most technical and methodological advances of SPECT, however, are not only available to SPECT/CT users but also to SPECT-only users.

Recently, a number of innovative hardware combinations of SPECT and CT were proposed, giving rise to the idea of disease-specific SPECT/CT imaging. Gambhir et al. [27] and Buechel et al. [28] demonstrated the clinical feasibility and technological benefit of a CdZnTe (CZT)-based SPECT imaging for cardiac applications. While this system is not combined with CT, it illustrates a major leap in SPECT instrumentation that could potentially enter into a new combination of SPECT/CT. The main benefit of CZT over standard scintillator-based SPECT detectors is the much higher energy resolution, which can be explored for dual-isotope imaging. CZT detectors are compact and future CZT SPECT/CT could be more physically integrated. However, today, production costs still limit the wider distribution of these novel SPECT imaging systems.

Already with standard SPECT in combination with CT several groups have demonstrated an increased diagnostic benefit from the availability of co-registered functional and anatomical information in combination with dedicated CT examinations, like angiography [17, 29]. So far these studies have been based on the retrospective alignment of SPECT and CT angiography data acquired on a 64-slice CT. Today, no SPECT/CT system would allow similar type of imaging sequences because of the limited number of CT detector rows (maximum 16, Fig. 3). It is fair to assume that if more SPECT-CT software fusion studies demonstrate the validity of hardware-based acquisitions of SPECT and CTA, then such combinations may well be designed and offered commercially.

In addition to cardiac applications, SPECT/CT can be optimised for orthopaedic imaging. Here, requirements entail fast and sensitive SPECT imaging in combination with high-resolution anatomical background information. As the age distribution of orthopaedic patients is very large, overexposure is a major concern when imaging these patients. Therefore, one vendor has proposed a novel design of SPECT/CT that combines a standard dual-head SPECT system with a cone-beam, flat-panel CT (Fig. 6) [30]. A single, 47-cm axial field-of-view of the SPECT is matched by three contiguous CT acquisitions of 14-cm axial field-of-view flat panel CT, thus allowing the co-axial SPECT/CT imaging range per bed position to be 42 cm.

Other innovations in SPECT/CT are expected from advanced data processing and acquisition (Fig. 7). As with nuclear medicine imaging techniques in general, SPECT describes a count limited imaging situation. Therefore, innovative image reconstruction techniques have been proposed to reduce noise propagation during the reconstruction (Fig. 7a). SPECT/CT images, even when based on low-dose CT acquisitions, provide the ability to anatomically define the fissures separating the lobes of the lungs so that lobar function can be assessed semi-automatically from co-registered V/Q images in patients who are candidates for lung volume reduction surgery (Fig. 7b). Similar approaches are followed when employing SPECT/CT information for image-based dosimetry calculations (Fig. 7c). Finally, Fig. 7d illustrates the potential of multi-bed, whole-body SPECT/CT imaging in oncology. Similar to PET/CT imaging, patients are injected with a single dose of radioactivity for SPECT/CT imaging. Imaging only a single bed position makes suboptimal use of the injected activity. Moreover, in oncology patients, disease can be widely distributed and not covered appropriately with a single bed position of SPECT/CT imaging. Here, a case of a patient with severe back pain with multiple foci of increased tracer uptake on the planar scintogram is shown. A two-bed SPECT/CT acquisition reveals several bone metastases in the spine and pelvis. Multi-bed, or whole-body SPECT/CT helps with the complete restaging of the patient, and is in synchrony with similar referring indications for whole-body PET/CT.

Since the commercial introduction of SPECT/CT in 2004, adoption of the technology has been rapid, particularly for oncology and cardiology. SPECT/CT has benefited from the advances in CT technology. SPECT/CT currently has a smaller installed base than PET/CT, but it is growing. In 2006, there were about 21-million SPECT studies performed in the USA compared with 1.5-million PET and PET/CT studies. The likelihood is that SPECT/CT will continue to grow with expanding applications in cardiology, oncology, infectious disease imaging and others, thereby benefiting from a much wider range of biomarkers and radiopharmaceuticals than clinical PET.