Juvenile differentiated thyroid carcinoma and the role of radioiodine in its treatment: a qualitative review

doi:10.1677/erc.1.00880

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Juvenile differentiated thyroid carcinoma and the role of radioiodine in its treatment: a qualitative review

B Jarz $a$ b, D Handkiewicz-Junak and J W $l$ och¹

Department of Nuclear Medicine and Endocrine Oncology and
¹ Clinic of Oncological Surgery, Maria Sk $l$ odowska-Curie Memorial Cancer Center and Institute of Oncology, Gliwice Branch, Wybrzezÿe Armii Krajowej 14, 44-100 Gliwice, Poland

(Requests for offprints should be addressed to B Jarz $a$ b; Email: bjarzab{at}io.gliwice.pl)

Well under 15% of differentiated thyroid carcinoma (DTC) isdiagnosed at $≤$ 18 years of age. The population is heterogenousand the differences between prepubertal children and pubertalsand adolescents are to be considered. Although very little hasbeen reported on children with sporadic DTC under the age of10 years, juvenile DTC has at least some undeniable differenceswith adult DTC: (1) larger primary tumor at diagnosis; (2) metastaticpattern and features, namely: (a) greater prevalence of necklymph node and distant metastases at diagnosis, (b) lungs almostthe sole distant metastatic site, (c) pulmonary metastases nearlyalways functional; (3) closer-to-normal and more frequent sodium-iodidesymporter (NIS) expression; and (4) higher recurrence rate butlonger overall survival. These differences are especially distinctin prepubertal children. The goals of primary treatment of juvenileDTC are to eradicate disease and extend not only overall, butrecurrence-free survival (RFS). Extending RFS is itself a desirablegoal in children because it improves quality-of-life, alleviatesanxiety during psychologically formative years, reduces medicalresource consumption, and may increase overall survival. Primarytreatment of DTC generally comprises a combination of surgery,radioiodine (¹³¹I) ablation, and thyroid hormone therapy appliedat varying levels of intensity. Therapeutic decision-makingmust rely on retrospective adult and/or pediatric outcome studiesand on treatment guidelines formulated mostly for adults. Differencesbetween juvenile and adult DTC and physiology dictate distincttreatment strategies for children. We, and many others, advocatea routine intensive approach because of the more advanced diseaseat diagnosis, propensity for recurrence, and greater radioiodineresponsiveness in children, as well as published evidence ofsignificant survival benefits, especially regarding RFS. Thisintensive approach consists of total thyroidectomy and centrallymphadenectomy in all cases, completed by modified laterallymphadenectomy when necessary and followed by radioiodine administration.However, absence of prospective studies and of universal proofof overall cause-specific survival benefits of this approachhave led some to propose more conservative strategies. MostEuropean centers give radioiodine ablation to the vast majorityof juvenile DTC patients. Ablation seeks to destroy any residualcancer, including microfoci, as well as healthy thyroid remnant.Large studies have documented the procedure to decrease cause-specificdeath rates and, in children, to significantly lessen locoregionalrecurrence rates (by factors of 2–11) independent of theextent of surgery. There is universal agreement on treatinginoperable functional metastases with large radioiodine activities.Treatment is especially effective in small tumor foci up to1 cm in diameter, and should be administered every 6–12months until complete response, loss of functionality, or attainmentof cumulative activities between 18.5–37GBq (500–1000mCi). Radioiodine therapy is generally safe. Short-term sideeffects include nausea and vomiting (more frequent in childrenthan in adults), transient neck pain and edema, sialadenitis(<5% incidence), mild myelosuppression (~25%), transientimpairment of gonadal function both in females and males (spermquality in boys), or nasolacrimal obstruction (~3%), with mostcases generally being asymptomatic–moderate, self-limiting,or easily prevented or treated. If pregnancy is ruled out beforeeach ¹³¹I administration, and conception avoided in the yearafterward, radioiodine therapy appears not to impair fertility.However, therapeutic ¹³¹I carries a small but definite increasein cancer risk, particularly in the salivary glands, colon,rectum, soft tissue and bone. To better guide primary treatment,different therapeutic combinations should be prospectively comparedusing RFS as the primary endpoint. Efforts also should be madeto identify molecular signatures predicting recurrence, metastasisand mortality.

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