Multimodality Molecular Imaging with Combined Optical and SPECT/PET Modalities

Cross-Validation of Optical Method for In Vivo Molecular Imaging

The high detection sensitivity is shared by nuclear and optical imaging, prompting the use of both methods for molecular imaging studies and facilitating a direct comparison of the nascent optical imaging performance with the established nuclear imaging performance. Typically, the radionuclides in radiopharmaceuticals are replaced with fluorescent dyes to produce the analogous optical molecular probes. Although initial strategies for tumor-specific imaging used fluorescent dye-labeled antibodies to minimize the effects of the dye on biologic activity and the distribution of the biomolecules, more recent methods have used smaller bioactive peptides and compounds (4,5). In general, studies have shown that replacing a radionuclide with a fluorescent dye may alter the in vivo distribution or rate of uptake in the target tissue without a loss of molecular recognition of the carrier molecule by the receptor, in some cases.

Recently, elegant molecular designs have been developed to take full advantage of the unique high detection sensitivity of both optical and nuclear imaging methods. Instead of preparing 2 different imaging agents (1 for each modality) that are distributed differently in the body, thereby increasing the potential for cumulative toxicity and complicating data fusion, a new trend is to fuse the signaling moieties for the 2 imaging systems into one molecule (monomolecular multimodality imaging agents [MOMIAs]) (16–20). This unique structural feature ensures that both signals emanate from the same source, allowing for the fusion of contrast data with high spatial precision. In addition to single molecules, quantum dots and a cross-linked near-infrared fluorescent polymer core were recently labeled with ⁶⁴Cu and ¹¹¹In for dual optical/PET and optical/SPECT studies, respectively (21,22). The polyvalent nature of these nanomaterials is attractive for multimodality imaging because the normalization of differences in the detection sensitivities for different contrast mechanisms can be achieved by incorporating the appropriate number of signaling molecules per particle.

Conversely, optical methods have been used to cross-validate radionuclear images. For example, a trimodal fusion reporter system with the ability to furnish fluorescent, bioluminescent, and PET {with 9-[4-¹⁸F-fluoro-3-(hydroxymethyl)butyl]guanine} contrast data has been developed (23). In metastatic cells transfected with a mutant herpes simplex virus type 1 thymidine kinase enzyme, the phosphorylation of 9-[4-¹⁸F-fluoro-3-(hydroxymethyl)butyl]guanine traps the radiopharmaceutical in the cells, thereby allowing the visualization of primary and metastatic tumors by PET. The highly sensitive and specific bioluminescence imaging and the high resolution provided by fluorescence microscopy of ex vivo tissue are subsequently used to validate the PET data. Variations of transduced multimodality molecular probes for combined optical and SPECT/PET studies are now available and have revealed the unique strengths of each reporter system (23–26). These genetically engineered reporter systems show great promise in preclinical drug development and biomedical research but have limited potential for human applications outside gene therapy.

Quantitation and Whole-Body Biodistribution

Tissue absorption and scattering of the low-energy radiation used in optical imaging limit the penetration depth. The net result is that optical imaging methods can provide micron-level spatial resolution and exquisite detection sensitivity for superficial tissues but rapidly lose these advantages in deep tissues. Conversely, quantitative imaging by SPECT/PET is not limited by tissue depth in either small animals or humans. In a combined system using a simple planar optical imaging approach, the optical contrast data can provide high-throughput imaging of molecular and functional events, and nuclear imaging can provide quantitative data when needed. In combined systems that use DOT, quantitative optical data is possible at depths of up to several centimeters but not at depths sufficient for whole-body human imaging as is possible by SPECT/PET. The MOMIA construct or the dual–reporter gene approach is ideally suited for this complementary imaging strategy.

Longitudinal Studies

A fundamental difference between optical imaging and nuclear imaging is that the emission of radioisotopes is a single event that is governed by the half-life of the radionuclide. This half-life can range from a few seconds to several years. Radionuclides with short half-lives, such as ¹⁸F and ¹¹C, are useful for rapid signal acquisition and minimize patient exposure to prolonged radioactivity. Considering that signal regeneration is the hallmark of optical contrast mechanisms, dual imaging with ¹⁸F or ¹¹C could provide early pharmacokinetic data by PET followed by longitudinal imaging by DOT. Unlike the high photon fluency often used in fluorescence microscopy, the lower light power used for in vivo optical imaging minimizes photobleaching. In fact, optical signals can be detected in tissues for several weeks after a single administration of the imaging agent. For bioluminescence imaging, a controlled release of enzyme substrates can be used to prolong the light emission during longitudinal studies. Consequently, PET can provide early quantitative data in a target tissue, and subsequent changes can be monitored longitudinally by an optical method.

Intraoperative Procedures

A combination of optical and nuclear methods is routinely used in disease diagnosis and management. For example, PET/CT is used to localize diseased tissue, which is then biopsied for histologic validation by an optical method. Another example is the conventional use of methylene blue or isosulfan blue and ^99mTc-labeled sulfur colloid to detect sentinel lymph nodes for staging of the axilla in breast cancer patients (27). For the detection of melanoma, ^123/131I-radiolabeled methylene blue was delivered to cancerous tissues for subsequent scintigraphy or radiotherapy (28). Although the optical imaging component of the dye was not used in that study, the molecular construct was similar to the MOMIA construct and was clearly amenable to the dual-imaging concept. In general, optical and nuclear MOMIAs can be used in 2 ways. First, the nuclear component can provide a whole-body image and localize diseased tissue, and the fluorescence component can guide tissue biopsy. Second, after nuclear imaging, the optical component can serve as a visual guide during surgery. Along with in vivo microscopy, high-resolution optical images of tumor boundaries can also be obtained.

Fusion of PET and Optical Data for Improved Optical Image Quality and Unified Molecular Imaging

PET and optical data could be fused to provide a unified report of an imaging probe. Incorporation of PET data into DOT reconstructions could serve as a priori spatial information in the form of tissue segmentations, linear correlations of optical contrast and PET contrast data, or dynamic models of the biochemical relationships between optical contrast and PET contrast data (29,30). Fused images potentially provide the resolution of PET with a joint optical/PET molecular readout. For instance, PET data might indicate the localization of a probe, whereas optical data would report the probe activity. A comprehensive algorithmic would jointly reconstruct both PET and DOT datasets in a manner similar to that used for fused PET/CT reconstructions. If such an approach incorporated a model of optical/PET probe activity, then a single self-consistent readout of all of the molecular information could be obtained.