Imaging Pathway of a Pediatric Patient with Succinate Dehydrogenase B-Deficient Paraganglioma

DISCUSSION

The best outcomes for treatment are based on early detection of as many lesions as possible (8). In addition, precise localization of lesions is vital for treatment decisions so that the effects of radiation therapy are minimized (9). The literature is consistent that CT and MRI are highly sensitive for localized tumors, at 95%–100% sensitivity, but drop to 45% sensitivity for metastases (10). Therefore, functional imaging is preferred when metastases are suspected, as when 2 tumors were found.

¹⁸F-FDG and ¹⁸F-FDOPA are often used for skeletal tumors (10) and, before 2015, were regarded as the tracers of choice for metastatic paragangliomas. However, comparative studies (11) have shown the superiority of ⁶⁸Ga-DOTATATE in the localization of succinate dehydrogenase subunit–related paragangliomas in pediatric patients and early detection of metastatic disease. Therefore, the literature (12) supports its use in pediatric imaging, for which it is superior in detecting sporadic and metastatic paragangliomas. However, the normal physiologic adrenal uptake reduces sensitivity to pheochromocytomas. Therefore, contrast medium is suggested for abdominal scans (11).

Because ¹²³I-MIBG targets catecholamine, entering the cell via the norepinephrine transporter, Mettler and Guibertau (10,13) make a case that ¹²³I-MIBG is more sensitive for pheochromocytomas and neuroblastoma, with sensitivities of 85%–100%. It is the most widely used functional imaging technique for assessing adrenal pheochromocytomas and sympathetic paragangliomas but has a minimal role for the head and neck. Sensitivity for thoracic paraganglioma is too low (56%–78%), resolution is limited, and quantitative uptake estimates have not yet been provided (13). Although PET/CT is associated with a higher diagnostic accuracy, better patient compliance and comfort, and lower radiation exposure, SPECT/CT has a proven incremental value in assessing neuroendocrine neoplasms (14). Therefore, it is concluded that ¹²³I-MIBG was chosen to complement ⁶⁸Ga-DOTATATE to provide a breadth of coverage for both pheochromocytomas and paragangliomas

Babic et al. (15) recommend that all pediatric patients with paragangliomas undergo genetic testing and imaging to detect metastatic disease and guide treatment, as 80% of patients have a germline mutation in a known susceptibility gene. Funded gene tests for hereditary paragangliomas are available throughout New Zealand to identify the most common succinate dehydrogenase gene mutations (16). Because sympathetic paragangliomas are characterized by a catecholamine excess, there is a 24-h urine test and blood plasma test for measuring free metanephrines (a metabolite of catecholamine) released from the tumor (17). Bolah and Bunchman (18) advocate localization of tumors with imaging only once paraganglioma is suspected and only once this biochemical evidence is established. These susceptibility tests have very few false-negative results. Elevations of 4-fold or more above the reference level are associated with a nearly 100% probability of a catecholamine-secreting tumor and might have been considered in this case.

The time to diagnosis is influenced by tumor growth rate and clinician awareness. There is a 4.5-y gap in imaging in this case study. Paraganglioma is an excellent mimic, with the differential diagnosis a challenge, typically taking 4 or more years (17,19). Michałowska et al. (19) describe succinate dehydrogenase subunit–based paragangliomas as slowly growing tumors with a thoracic volume doubling time of 11.8 y, contrasting with this case. The Royal New Zealand College of General Practitioners recognizes the challenge of low awareness of rare disorders (https://www.raredisorders.org.nz/assets/VOICE-OF-RARE-DISORDERS-White-Paper-February-2021-FINAL.pdf). However, the New Zealand Guidelines Group (20) lays out clear screening guidelines for general practice, supported internationally (21), when it comes to young people and cancer. CT/MRI, because of accessibility, will often be the first detailed diagnostic imaging technique used, but initial diagnosis using standard radiographs should not be underestimated, as the radiograph at 15 y shows. For pediatrics, radiographs offer a balance in radiation protection. When done regularly, they are safer than the radiation burden of CT and cheaper and more practical for pediatrics than MRI. CT and MRI are more sensitive for localized tumors with suspicion of something abnormal, but functional imaging is essential where metastases are suspected (22).

In addition to imaging modalities, nuclear medicine can be used to treat pediatric paraganglioma. ¹³¹I, for example, can be utilized to administer targeted radiation therapy to cancer cells while causing minimal damage to healthy cells. Radioisotope therapy, or targeted radionuclide therapy, is a method that has been shown to help treat juvenile paraganglioma, especially when combined with other treatments such as surgery and chemotherapy (23,24). Molecular imaging is another method by which nuclear medicine can enhance health outcomes for children with paraganglioma. With PET and SPECT, it is possible to find out what chemicals or receptors are on the surface of cancer cells. By using radiotracers to target these molecules or receptors, health-care providers can develop images that reveal precise information about the biology of the tumor and how it responds to treatment. With this information, treatment plans can be tailored to fit the needs of each patient, making the treatments more effective and reducing the chance of side effects. Molecular imaging can also be used to find possible targets for new therapies (25), making it easier to treat pediatric paraganglioma and other types of cancer. Finally, nuclear medicine is essential in diagnosing, treating, and monitoring pediatric paraganglioma. Using imaging tools and custom radionuclide therapy, doctors can find and treat this rare cancer early. Also, molecular imaging can tell us a lot about the biology of the tumor, which can help us come up with new treatments and make the ones we already have work better (26,27).

Integration of clinicopathologic information with imaging is essential for early diagnosis. Access to the clinical records is necessary for what was performed and is a limitation to this analysis. However, on the basis of available data and the literature, there may have been a missed opportunity to diagnose these rapidly growing tumors earlier. Therefore, a traditional, holistic approach should be adopted, combining guidelines with best-practice testing to avoid missing rare disorders. Consultation with tertiary or quaternary centers is also recommended in atypical cases. Annual functional imaging is recommended for the patient. In addition, a thorough family history check, particularly of siblings, is recommended.

Several significant factors likely contributed to the delay in diagnosis. First, there was reduced accessibility due to the patient’s remote geographical location. There were also patient comorbidities making it difficult for the patient to communicate symptoms and their escalation. Lastly, functional imaging is available in only a few centers in the country, with ⁶⁸Ga-DOTATATE PET/CT in only one, and at the outset, ¹²³I-MIBG was available only overseas, which, when combined with complex pathways to access specialist imaging, resulted in significant delays (27). In contrast to these delays, once the tumors were identified, however, this paucity of information was replaced with a rapid and intensive access to a range of high-quality specialist services and treatments.