Summary: The potential of molecular imaging (MI) to identify features of the cancer phenotype make it an effective tool in patients receiving cancer therapy. It is expected that MI will provide a better understanding of cancer biology and how that information can be used to plan radiation treatments for cancer. The author reviews the use of MI to characterize disease and to evaluate therapeutic efficacy.
Dr. Divgi is a Professor of Radiology, Professor of Radiation Oncology, Professor in the Wistar Institute, a Member of the Abramson Cancer Center, University of Pennsylvania; and the Chief of Nuclear Medicine and Clinical Molecular Imaging, Hospital of the University of Pennsylvania, Philadelphia, PA.
Molecular imaging (MI) creates images of cellular processes either by using molecular probes that target molecules critical in the pathophysiology of the disease process, or by using probes that reflect perturbation that is characteristic of a disease.
The potential of MI to identify features of the cancer phenotype make it a particularly effective tool in the development of agents for cancer therapy. Currently, cancer drug discovery goes through an inexorable process through which toxicity is defined in early trials with conventional methods of efficacy evaluation including assessments of structural change (particularly CT) that utilize inadequate measures of response. 1 Incorporation of MI will permit the earlier detection of treatment failures by identifying key pharmacodynamic endpoints. 2 The growing potential for development of biologic agents with little or no systemic toxicity has also increased the need for identification of optimum biologic doses more is no longer necessarily better and MI will likely enable pharmacokinetic studies that will better characterize the biologic behavior of molecular therapies.
There is a growing consensus that MI will become an established means to characterize disease and to validate therapeutic efficacy, particularly of molecular therapy. Of particular clinical relevance are magnetic resonance imaging (MRI)/spectroscopy and nuclear medicine positronemission tomography (PET) and single-photon emission computed tomography (SPECT) imaging, whose utility and promise are evident in clinical trials that have explored agents and technologies. However, as yet, there are no completed, carefully controlled clinical trials that evaluate the utility of MI in determining outcome.
Optical imaging, using fluorescence or luminescence, is increasingly being used in preclinical studies to evaluate changes following therapy. 3 Signal attenuation as a function of depth and the suboptimal biologic characteristics of many optical probes preclude its widespread clinical use. The sensitivity (ability to discriminate low signal) and resolution (smallest discernible focus) of optical imaging are excellent, and therefore it is increasingly becoming the first imaging modality used to evaluate therapeutic potential in animal and invitro models. Clinical trials using optical imaging probes are still in their infancy, but its promise is evident in endoscopic applications. 4
The quantification of nuclei with odd atomic weights (proton hydrogen-1, sodium-23, phosphorus-31) is possible with MR spectroscopy,which, along with MRI, is increasingly being used to characterize tumors. 5 Dynamic contrast-enhanced MRI (DCE-MRI) evaluates tissue (tumor) vascularity and is being used to evaluate antiangiogenic agents for cancer therapy, using surface coils in patients with disease close to the body surface. The high (submillimeter) resolution of MRI is offset by low sensitivity, thus only high concentrations can be detected reliably with high field-strength magnets. There is a paucity of standardized protocols that can be used in multicenter studies. Considerable progress has been made in all factors other than the inherent lack of sensitivity of proton imaging/spectroscopy; however, most clinical MRI is nonmolecular, albeit functional, since vascular perturbation is measured. 6
MR spectroscopy does involve assessment of molecular profiles within tissue. Choline content in tissue is measured as a choline-containing peak (Figure 1), and several studies have found a link between an elevated peak and tumor aggressiveness. 7 Again, the lack of sensitivity has provided for limited utility. The assessment of changes in sodium and phosphorus concentrations is currently exploratory and hampered by the necessity for high field-strength magnets. 6,8
The tracer principle allows the measurement of nanomolar quantities of radioactive agents that target molecules of relevance in cancer pathophysiology or that utilize radiotracers to track other functional features of the cancer phenotype, including vascularity and oxygenation. 9 Perhaps the earliest molecular image indeed is an image of the distribution of iodide in a thyroid gland. 10 Clinical PET really came of age when it was combined with anatomic imaging using computed tomography (CT), leading to phenomenal growth in the use of radiotracers usually labeled with short-lived positron emitters such ascarbon-11(20 minutes) or fluorine-18 (110 minutes) in the metabolic and molecular imaging of tumor characteristics. 11
The archetypal molecular PET imaging is using [18F]-fluorodeoxyglucose (FDG) to assess carbohydrate metabolism (Figures 2 and 3). FDG enters the cell via glucose transporters in a manner identical to glucose and is phosphorylated at a rate comparable to glucose phosphorylation. It is, however, not subsequently metabolized, and its accumulation therefore serves as a surrogate for glucose metabolism. 9 FDG PET/CT is now approved for extent of disease evaluation in a large number of cancers (hematologic as well as solid tumors) and is increasingly being used for evaluation of response to therapy 12 (Figures 4 through 6). An increasing number of radiotracers, labeled with F-18 as well as other radionuclides, are being studied to evaluate functional characteristics of the cancer phenotype. 12-15
FDG uptake has been associated with tumor viability and aggressiveness, and FDG PET/CT is used in radiation therapy planning for delineation of tumor volumes to determine biologic tumor volume. 16 While this has been of considerable value in the delineation of viabletumor, its utility in treatment follow-up has been less than clear. 17,18 Moreover, there is no consensus on methodology for the definition ofviable tumor volumes to be selected for therapy. Finally, the utility of FDG PET/CT to define tumor volumes during therapy is also not understood, with several groups reporting that volumes can be variable and may not always represent viable tumor. 18 Increased glucose uptake is a component of the Warburg effect (which states that glucose avidity is greater in tumors than in normal tissue) and is also a feature of increased glucose metabolism by other cells (eg, peritumoral inflammatory cells).
More specific methods for evaluation of cancer phenotype are being actively investigated. 19 The parameters of amino-acid or nucleoside turnover in cancer cells may be more specific, and radiolabeled tyrosine and thymidine radiotracers are among the agents being studied actively. In addition, other features of the cancer phenotype, particularly hypoxia, are being evaluated. 19,20
While this overview has focused on clinical imaging, it is self-evident that preclinical imaging plays a critical role in the assessment of agents that are brought to the clinic for evaluation. 21 Indeed, preclinical imaging has included cellular agents 22 as well, and MI is increasingly playing a decisive role in the translation of molecular therapies from the bench to the bedside.
It is becoming clear that molecular imaging will bring a new perspective to our understanding of cancer biology and its relevance in the planning of radiation treatments for cancer. FDG PET/CT is becoming an integral part of the initial work-up in patients scheduled to undergo radiation therapy, and other radiotracers particularly those that evaluate hypoxia and other important features of the tumor micro-environment are increasingly being studied. Most imaging modalities are now being evaluated at the beginning and end of therapy. MI for image-guided radiation therapy is entering the paradigm for optimal dose distribution and delivery. Methods for adaptive radiation therapy are being utilized as well. All these mandate a prospective approach with clearly defined endpoints that will eventually assure the proper utilization of these exciting means to establish cancer phenotype.
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