Salivary Gland Pathology. Группа авторов

Figure 2.25. Contrast‐enhanced axial CT exam through the parotid gland prior to biopsy demonstrates a relatively large heterogeneous mass with ill‐defined borders (a). (b) Ultrasound‐guided core needle biopsy. Note the biopsy needle passing into the hyperechoic mass within the parotid gland. (c) Fine needle aspiration biopsy: Note the darkly staining cells that appear atypical. A definitive diagnosis cannot be reached utilizing this cryptologic material. (d) Core needle biopsy. Note the darkly staining epithelial cells arranged in ductal groups. This biopsy was consistent with an atypical mixed tumor. (e) Surgical material from a parotidectomy. This lesion represents a carcinoma ex. mixed tumor. Note the similar cells seen in the core needle biopsy.

      PET radionuclides are produced in a cyclotron and are relatively short lived. Typical radionuclides include ¹⁸F, ¹¹C, ¹⁵O, ⁸²Rb, and ¹³N. A variety of ligands have been labeled and studied for the evaluation of perfusion, metabolism, and cell surface receptors. The most commonly available is ¹⁸F‐deoxyglucose (FDG), which is used to study glucose metabolism of cells. Most common uses of FDG include oncology, cardiac viability, and brain metabolism. PET has a higher spatial resolution than SPECT. Both systems are prone to multiple artifacts, especially motion. Acquisition times for both are quite long, limiting the exam to patients who can lie still for prolonged periods of time. Both systems, but PET in particular, are very costly to install and maintain. Radiopharmaceuticals are now widely available to most institutions through a network of nuclear pharmacies.

      The oncologic principle behind FDG PET is that neoplastic tissues can have a much higher metabolism than normal tissues and utilize glucose at a higher rate (Warburg 1925). Glucose metabolism in the brain was extensively studied using autoradiography by Sokoloff and colleagues at The National Institutes of Health (NIH) (Sokoloff 1961). The deoxyglucose metabolism is unique in that it mimics glucose and is taken up by cells using the same transporter proteins. Both glucose and deoxyglucose undergo phosphorylation by hexokinase to form glucose‐6‐phosphate. This is where the similarities end. Glucose‐6‐phosphate continues to be metabolized, eventually to form CO₂ and H₂O. Deoxyglucose‐6‐phosphate cannot be further metabolized and becomes trapped in the cell as it cannot diffuse out through the cell membrane. Therefore, the accumulation of FDG reflects the relative metabolism of tissues (Sokoloff 1986). The characteristic increased rate of glucose metabolism by malignant tumors was initially described by Warburg and is the basis of FDG PET imaging of neoplasms (Warburg 1925).

FDG PET takes advantage of the higher utilization of glucose by neoplastic tissues to produce a map of glucose metabolism. Although the FDG PET system is sensitive, it is not specific. Several processes can elevate glucose metabolism, including neoplastic tissue, inflammatory or infected tissue, and normal tissue in a high metabolic state. An example of the latter includes uptake of FDG in skeletal muscle that was actively contracting during the uptake phase of the study (Figure 2.26). Another peculiar hypermetabolic phenomenon is brown adipose tissue (BAT) FDG uptake (Figure 2.27). BAT is distributed in multiple sites in the body including interscapular, paravertebral, around large blood vessels, deep cervical, axillary, mediastinal, and intercostal fat, but is concentrated in the supraclavicular regions (Cohade et al. 2003b; Tatsumi et al. 2004). BAT functions as a thermogenic organ producing heat in mammals and most commonly demonstrates uptake in the winter (Tatsumi et al. 2004). BAT is innervated by the sympathetic nervous system, has higher concentration of mitochondria, and is stimulated by cold temperatures (Cohade et al. 2003a; Tatsumi et al. 2004). Administration of ketamine anesthesia in rats markedly increased FDG uptake presumably from sympathetic stimulation (Tatsumi et al. 2004). Although typically described on FDG PET/CT exams, it can be demonstrated with ¹⁸F‐Fluorodopamine PET/CT, ⁹⁹mTc‐Tetrofosmin, and ¹²³I‐MIBG SPECT as well as ²⁰¹TlCl, and ³H‐l‐methionine (Baba et al. 2007; Hadi et al. 2007). Propranalol and reserpine administration appears to decrease the degree of FDG uptake whereas diazepam does not appear to have as significant an effect (Tatsumi et al. 2004). Exposure to nicotine and ephedrine also resulted in increased BAT uptake; therefore, avoiding these substances prior to PET scanning can prevent or reduce BAT uptake (Baba et al. 2007). Preventing BAT uptake of FDG can be accomplished by having the patient stay in a warm ambient temperature for 48 hours before the study and by keeping the patient warm during the uptake phase of FDG PET (Cohade et al. 2003a; Delbeke et al. 2006). Although somewhat controversial, diazepam or lorazepam and propranalol can reduce BAT uptake by blocking sympathetic activity, as well as reducing skeletal muscle uptake from reduced anxiety and improved relaxation (Delbeke et al. 2006). Understanding the distribution of BAT and the physiology that activates BAT, as well as recognizing the uptake of FDG in BAT in clinical studies, is critical in preventing false positive diagnosis of supraclavicular, paravertebral, and cervical masses or lymphadenopathy.