At the time this article was written, Dr. Kuo was an Assistant Professor, Department of Diagnostic Radiology, Yale University School of Medicine, New Haven, CT. He is currently an Associate Professor, Department of Medicine, Hematology/ Oncology Section, University of Arizona School of Medicine, Tucson, AZ, and a Staff Radiologist, Southern Arizona Veterans Administrations Health Care System Tucson, AZ. Dr. Chen is an Associate Professor and Dr. Weidhaas is an Assistant Professor, Department of Therapeutic Radiology, Yale University School of Medicine, New Haven, CT.
Both 2-deoxy-2-[F-18]fluoro-D-glucose (FDG) positron emission tomography (PET) and PET fused with computed tomography (PET/CT) are emerging as the standard of care for the staging, monitoring of response to therapy, and detection of disease recurrence for numerous malignancies. PET is increasingly being used to alter the management of patients by detecting a suboptimal response to therapy and thereby directing an intensification or switch of therapeutic regimens. Since the introduction of the first PET/CT camera for clinical use in 2000, PET/CT has proven to add sensitivity and specificity as compared with PET alone for a variety of malignancies.1-6 The PET/CT camera provides an inline hardware fusion of the functional imaging from PET with the anatomical detail from CT. Reaping the benefits of PET/CT technology for the optimization of planning of radiation therapy (RT) requires a melding of sophisticated fields that took time to develop but can now be readily accomplished.
For optimal collaboration, both the radiologist/nuclear medicine physician and the radiation therapist need an understanding of the basic principles of FDG-PET/CT and RT. In this article, a protocol for the integration of PET/CT into treatment planning of radiotherapy is provided as a model that can be fine-tuned to meet the equipment and requirements of each institution. Subsequently, cases are presented to illustrate the 4 crucial concepts of FDG-PET/CT in planning RT. First, FDG-PET/CT may alter treatment decisions. Second, FDG-PET/CT improves treatment planning. Third, FDG-PET/CT may be used to assess response to therapy. Fourth, not recognizing pitfalls in the interpretation of FDG-PET/CT can have disastrous implications.
Basic principles of PET
PET utilizes special radioactive isotopes, which are mostly produced in cyclotrons. PET isotopes emit positrons (positively charged electrons) that annihilate with electrons to produce two 511-keV gamma rays directed approximately 180˚ apart. The PET camera is a ring of detectors that accepts “true” counts that arrive within a narrow time window (coincidence detection) and at opposite detectors 180˚ apart (Figure 1).
Basic principles of FDG
As with all of nuclear medicine, the PET scan is defined by the injected radiotracer. FDG is by far the most widely used PET radiotracer. As the chemical name suggests, FDG behaves as an analog of glucose and is transported into the cell through glucose transporters. FDG is injected intravenously, and the patient is imaged approximately 45 to 60 minutes after sitting quietly. The PET camera localizes and quantifies the accumulation of FDG within the patient. Tumors have higher rates of glucose metabolism and, therefore, have increased FDG uptake in comparison with the normal surrounding tissue. The substitution of the fluorine into the glucose molecule results in biochemical trapping of FDG in the malignant cell (Figure 2).
Basic principles of PET/CT
The PET/CT camera is essentially a PET camera and CT scanner placed back-to-back into one machine (Figure 3). The physiologic data from PET and the anatomic data from CT are acquired nearly simultaneously. The data set of attenuation coefficients that constitute a CT image is utilized to correct for attenuation of the gamma rays, and, thus, a separate transmission scan for attenuation correction is not necessary as in PET-only cameras. PET and CT images are fused by the overlay of color PET images onto the CT images (Figure 4). In-line PET and CT scans are accurately and rapidly registered for more accurate attenuation correction and better anatomic correlation than was done previously by software packages or by the radiologist. 9
Basic principles of RT
How does radiation kill cells? “Packets” of energy are deposited into biological material, leading to cell death. There is overwhelming evidence that deoxyribonucleic acid (DNA) is the target, which is confimed by the observation of a 1-to-1 correlation of visible lethal chromosomal aberrations and cell death. 10 While there are many forms of immediate cell death following radiation, including apoptosis and autophagy, it is firmly believed that the most significant form of cell death in solid tumors is a delayed form of cell death referred to as reproductive cell death (Figure 5). 11,12 This is a unique genetic form of cell death caused by ineffective DNA repair and requires several cell cycles before cells undergo death.
Rationale for integration of PET/CT and RT
Despite the efficacy of RT, >50% of patients diagnosed with cancer will die of their disease, with local failure being common. There are several factors contributing to this poor outcome, including inadequate tumor identification, inadequate staging of nodal or metastatic disease, inadequate tumor targeting due to unidentified nodes or inaccurate borders of tumor, and inadequate dose or tumor resistance. PET/CT can help in all these areas. First, PET/CT is superior to CT and PET alone in the evaluation of nodal and metastatic disease. 1-6 Additionally, the coregistration between planning CT and PET/CT improves lesion localization and identification for optimal targeting of tumor. PET/CT alters radiation treatment planning in up to 45% of patients and also leads to changes in tumor volumes in 30% to 50% of patients. 13 To overcome the issue of inadequate dose, the radiation oncologist must attempt to increase the therapeutic ratio to avoid normal tissue complications while increasing the dose to the tumor and, ultimately, increasing local control (Figure 6). Increasing the therapeutic ratio can be achieved by intensity-modulated RT (IMRT), which allows the delivery of highest doses to the tumor while minimizing the dose to normal tissue.
Basics of IMRT
Intensity-modulated RT is an advanced form of 3-dimensional (3D) conformal radiotherapy (CRT). Earlier radiotherapy involved administering square or rectangular radiation beams to the tumor volume (Figure 7). In 3D CRT, irregular apertures that conform to the outline of the tumor volume as seen from the beam's eye view (BEV) have replaced the primitive rectangular beam apertures (Figure 7). Coupled with interactive graphical representation of the 3D patient anatomy, 3D CRT has significantly reduced the amount of normal tissue exposed to unnecessary radiation in RT. In IMRT, the radiation intensity within each irregular beam aperture is further manipulated to achieve a best-possible radiation dose distribution that conforms to the 3D shape of the tumor volume with sharp dose fall-off to protect the nearby normal structures (Figure 8). Conceptually, an intensity-modulated beam in IMRT can be considered to consist of hundreds of tiny beamlets that have different intensities (Figure 7). A computer-aided optimization algorithm (typically referred to as “inverse planning” in IMRT) is used to determine the optimal intensities for these beamlets in order to fulfill a prescribed radiation dose distribution. In most clinics, the intensity-modulated beams are delivered by a computer-controlled multileaf collimators system with a specially designed spatial-temporal leaf pattern for each beam. The goal of IMRT is to minimize toxicity by decreasing the dose to normal tissues while maximize tumor control by increasing the dose to the tumor; treatments typically last <6 weeks. Treatment plans for IMRT are generally characterized by complex dose maps with sharp dose fall-offs that allow a high degree of target volume conformity and/or avoidance of critical structures.14
PET/CT protocol for RT planning
A protocol for melding PET/CT with radiation treatment planning requires optimization for the nuances of each center. At our institution, the departments of nuclear medicine and RT are on different wings and floors of the hospital. Figure 9 presents our protocols, which can be used as a template to be modified for another specific institution.
FDG-PET/CT altering the treatment plan
The functional data from FDG-PET greatly improves sensitivity and specificity over CT alone for the staging of a variety of malignancies. The complementary combination of the 2 modalities performs best of all. Increased uptake of FDG can clearly show neoplastic involvement of subcentimeter nodules that would otherwise have been missed on CT alone. Detection of residual tumor in a mass after treatment can be assessed promptly by PET rather than relying on serial anatomical imaging to assess for any change in size. Obviously, accurate disease staging is crucial to treatment planning and to determine the goal of radiation therapy (no treatment, curative, or palliative).
Discovery of widespread or distant spread of disease could change the goal of RT from cure to palliation or no treatment. In a patient with cervical cancer (Figure 10), the detection of occult disease in the mediastinum by PET/CT changed the treatment plan from attempting a cure (with 6 weeks of combined chemotherapy/RT plus 2 hospital stays and brachytherapy) to palliation with standard radiation fields. The more accurate staging by PET/CT spared the patient the morbidity and potential mortality associated with the toxicity of therapy intended to eradicate all disease.
In a patient with non-Hodgkin’s lymphoma (Figure 11), CT found only the lesion in the right glenoid, but FDG-PET/CT showed multiple sites of bone involvement, including the left femur. The findings from the PET/CT altered the treatment plan from local radiation for 5 weeks with chemotherapy to the consideration of transplant as the only option for cure and radiation only for treatment failure.
FDG-PET/CT optimizing the treatment plan
FDG-PET/CT can be used to optimize the treatment plan by improving delineation of the entire extent of disease so that the treatment field can be appropriately increased or decreased. Even a single positive node just outside of the field of treatment will result in failure of therapy. At the same time, FDG-PET/CT also allows for minimizing toxicity by decreasing elective nodal irradiation and treatment of normal tissue that could not be distinguished from diseased tissue by conventional anatomic imaging.
In a patient with cervical cancer (Figure 12), PET/CT detected nodal disease occult on the diagnostic CT and, therefore, the treatment fields were modified to include this disease, which otherwise would have been at the border of the field. Without the PET/CT, the nodal disease would have been missed, leading to treatment failure and certain death.
Figure 13 shows a patient who had both esophageal adenocarcinoma and chronic lymphocytic leukemia (CLL). Unlike esophageal cancer, CLL has a low metabolic rate and therefore no increased uptake of FDG. The treatment field could therefore be adjusted to spare the adenopathy in the abdomen and the subsequent toxicity, particularly to the radiation-sensitive bowel.
FDG-PET/CT for monitoring of response and recurrence after RT
FDG-PET/CT assesses early response to RT and can also be used for the detection of disease recurrence. A patient received RT for recurrence of cervical cancer at the pelvic sidewall (Figure 14, A through D). At 3 months after RT, there was diffuse faint activity at the site of disease, which was compatible with inflammation, and there were no new sites of disease (Figure 14, E through H). At 6 months, there was no significant activity at the site indicating that the faint uptake at 3 months was inflammatory in origin (Figure 14, I through L). Unfortunately, the patient had a recurrence of disease at this pelvic sidewall site that was detected on PET/CT 24 months after completing radiation (Figure 14, M through O). This case highlights the concern that activity from the inflammation from radiation could potentially mask low-level activity from residual disease; however, in this case, the false-negative FDG-PET was likely due to microscopic disease below the level of resolution.
Interpretive pitfalls for FDG-PET/CT
Accurate interpretation of the FDG-PET/CT is obviously crucial, and thus one should be familiar with FDG-PET/ CT interpretation pitfalls. As an analog of glucose, FDG exhibits physiologic uptake in metabolically active tissues (brain, lymphoid tissue, muscles, heart, testicles, etc.) and also in inflammation and infection. The clinical history is often critical for optimal interpretation. Recent surgery, infection, or trauma can result in false-positive findings. In particular, inflammation after radiation is variable with respect to the degree and duration of uptake of FDG. The clinical situation, such as degree of suspicion for treatment failure or the time frame for next possible therapy, should be taken into account so that the PET/CT can be performed in a reasonable time window. The authors typically image approximately 8 to 12 weeks after completion of radiation, which is a common time frame. 15
Communication between the radiologist/nuclear medicine physician and radiation therapist is paramount for this complex group of patients. One example of tissue with increased physiologic uptake of FDG is brown fat, as shown in a case of restaging for lymphoma (Figure 15).
In a patient with lung cancer, asymmetric increased activity in the neck represented uptake in the musculature of the left vocal cord due to unilateral right vocal cord paralysis rather than neoplasm (Figure 16). Adenopathy in the right tracheoesophageal groove damaged the right laryngeal nerve.
Advantages of combining PET/CT and IMRT
FDG-PET/CT optimizes treatment planning by providing more accurate and appropriate treatment. In combination with IMRT, FDG-PET/CT allows 1) dose escalation to tumor, 2) decreased dose to normal tissue, 3) decreased acute toxicity, 4) the possibility of better tumorcure, and 5) (it is hoped) less long-term toxicity.
PET/CT has the advantages of both modalities by fusing the physiologic data from PET onto the anatomic data from CT. Integrating PET/CT into the planning of radiation therapy is readily achievable. Upfront, PET/CT impacts the treatment goal of RT through improved staging. Next, PET/CT optimizes the treatment plan to increase the radiation dose to the tumor and decrease the dose to sensitive organs (improving the therapeutic ratio). After treatment, PET/CT can be used to monitor response to treatment and assess for recurrence. All of the advantages of PET/CT for RT are predicated on the proper interpretation of this multimodality technology, which has its own unique pitfalls.
The authors thank Geri Mancini for her invaluable assistance with illustrations.
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