Positron emission tomography (PET) is a noninvasive imaging technique that provides a functional or metabolic assessment of normal tissue or disease conditions. 18 F-fluorodeoxyglucose PET imaging (FDG-PET) is widely used clinically for tumor imaging due to increased glucose metabolism in most types of tumors, and has been shown to improve the diagnosis and subsequent treatment of cancers. In this chapter, we review its use in cancer diagnosis, staging, restaging, and assessment of response to treatment. In addition, other metabolic PET imaging agents in research or clinical trial stages are discussed, including amino acid analogs based on increased protein synthesis, and choline, which is based on increased membrane lipid synthesis. Amino acid analogs and choline are more specific to tumor cells than FDG, so they play an important role in differentiating cancers from benign conditions and in the diagnosis of cancers with low FDG uptake or high background FDG uptake. For decades, researchers have shown that tumors have altered metabolic profiles and display elevated uptake of glucose, amino acids, and lipids, which can be used for cancer diagnosis and monitoring of the therapeutic response with excellent signalto-noise ratios.Positron Emission Tomography (PET), a noninvasive imaging technique that detects the gamma rays from positron-emitting isotopes has had a major impact on the diagnosis and treatment of disease. PET enables clinicians to view and assess the human body from a functional, biochemical perspective. As a highly sensitive and accurate nuclear medicine imaging technology based on molecular biology, PET has a unique ability to assess the functional and biochemical processes of the body's tissues, which are altered in the earliest stages of virtually all diseases. PET detects these changes -often before anatomical or structural changes have occurred and become evident on magnetic resonance imaging (MRI) or computed tomography (CT). In the 1970's and 1980's, PET was mainly used for research. During the early 1990's, the use of PET expanded into hospitals and diagnostic clinics as more and more medical communities began to realize the utility of PET in clinical applications, particularly in oncology for cancer staging, assessing treatment strategies, and monitoring the effects of therapy with appropriate radiotracers. Reimbursement of studies by Medicare and other third-party payers also contributed significantly to the growth in clinical PET imaging. However, the spatial resolution of PET is not comparable to CT or MRI,
