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Radionuclide therapy is a rapidly expanding oncological treatment method. Overwhelmingly, the application of radionuclide therapy in clinical practice relies on fixed or empirical dosing strategies. In principle, the application of dosimetry promises to improve patient outcomes by tailoring administered radionuclide therapy activities to each patient's unique tumour burden and tumour uptake. However, robust prospective data are scarce due to few prospective randomised clinical trials investigating the use of dosimetry in radionuclide therapy. In this Review, we describe the role of dosimetry as it has been applied historically and in modern clinical practice and its potential future applications. We further emphasise areas of future growth and a potential pathway to optimised personalised activity modulation of radionuclide therapy

This trial compared two thyrotropin-stimulation methods and two 131I doses for postoperative ablation in patients with low-risk thyroid cancer. Rates of ablation were similar in all treatment groups. Doses lower than those currently recommended may be adequate for this condition. Radioiodine ( 131 i) is administered to patients with thyroid cancer after total thyroidectomy for three reasons 1 – 3 : first, to eradicate normal-thyroid remnants (ablation) in order to achieve an undetectable serum thyroglobulin level; second, to irradiate any neoplastic focus in order to decrease the risk of recurrence; and third, to perform 131 I total-body scanning for persistent carcinoma. Successful ablation is defined by the combination of undetectable serum thyroglobulin levels after thyrotropin stimulation and normal results on neck ultrasonography 6 to 12 months after 131 I administration. 2 , 3 When these criteria are met, approximately 1% of patients have a recurrence. 4 – 6 In . . .

In this randomized phase 3 trial involving patients with low-risk differentiated thyroid cancer undergoing thyroidectomy, a follow-up strategy that did not involve the use of radioiodine was noninferior to the use of radioiodine in the response to treatment at 3 years.

BACKGROUNDMolecular characterization in pediatric papillary thyroid cancer (PTC), distinct from adult PTC, is important for developing molecularly targeted therapies for progressive radioiodine-refractory (131I-refractory) PTC.METHODSPTC samples from 106 pediatric patients (age range: 4.3-19.8 years; n = 84 girls, n = 22 boys) who were admitted to SNUH (January 1983-March 2020) were available for genomic profiling. Previous transcriptomic data from 125 adult PTC samples were used for comparison.RESULTSWe identified genetic drivers in 80 tumors: 31 with fusion oncogenes (RET in 21 patients, ALK in 6 patients, and NTRK1/3 in 4 patients); 47 with point mutations (BRAFV600E in 41 patients, TERTC228T in 2 patients [1 of whom had a coexisting BRAFV600E], and DICER1 variants in 5 patients); and 2 with amplifications. Fusion oncogene PTCs, which are predominantly detected in younger patients, were at a more advanced stage and showed more recurrent or persistent disease compared with BRAFV600E PTCs, which are detected mostly in adolescents. Pediatric fusion PTCs (in patients <10 years of age) had lower expression of thyroid differentiation genes, including SLC5A5, than did adult fusion PTCs. Two girls with progressive 131I-refractory lung metastases harboring a TPR-NTRK1 or CCDC6-RET fusion oncogene received fusion-targeted therapy; larotrectinib and selpercatinib decreased the size of the tumor and restored 125I radioiodine uptake. The girl with the CCDC6-RET fusion oncogene received 131I therapy combined with selpercatinib, resulting in a tumor response. In vitro 125I uptake and 131I clonogenic assays showed that larotrectinib inhibited tumor growth and restored radioiodine avidity.CONCLUSIONSIn pediatric patients with fusion oncogene PTC who have 131I-refractory advanced disease, selective fusion-directed therapy may restore radioiodine avidity and lead to a dramatic tumor response, underscoring the importance of molecular testing in pediatric patients with PTC.FUNDINGThe Ministry of Science, ICT and Future Planning (NRF-2016R1A2B4012417 and 2019R1A2C2084332); the Korean Ministry of Health and Welfare (H14C1277); the Ministry of Education (2020R1A6A1A03047972); and the SNUH Research Fund (04-2015-0830).TRIAL REGISTRATIONTwo patients received fusion-targeted therapy with larotrectinib (NCT02576431; NAVIGATE) or selpercatinib (LOXO-RET-18018).

About half of patients with papillary thyroid cancer have tumours with activating BRAF(V600E) mutations. Vemurafenib, an oncogenic BRAF kinase inhibitor approved for BRAF-positive melanoma, showed clinical benefit in three patients with BRAF(V600E)-positive papillary thyroid cancer in a phase 1 trial. We aimed to establish the activity of vemurafenib in patients with BRAF(V600E)-positive papillary thyroid cancer. We did an open-label, non-randomised, phase 2 trial at ten academic centres and hospitals worldwide in patients aged 18 years or older with histologically confirmed recurrent or metastatic papillary thyroid cancer refractory to radioactive iodine and positive for the BRAF(V600E) mutation. Participants either had never received a multikinase inhibitor targeting VEGFR (cohort 1) or had been treated previously with a VEGFR multikinase inhibitor (cohort 2). Patients received vemurafenib 960 mg orally twice daily. The primary endpoint was investigator-assessed best overall response in cohort 1 (confirmed on two assessments 4 weeks or longer apart). Analyses were planned to have a minimum median follow-up of 15 months (data cutoff April 18, 2014) and were done in safety, intention-to-treat, and per-protocol populations. This trial is closed and is registered at ClinicalTrials.gov, number NCT01286753. Between June 23, 2011, and Jan 15, 2013, 51 patients were enrolled to the study, 26 in cohort 1 and 25 in cohort 2. Median duration of follow-up was 18·8 months (IQR 14·2-26·0) in cohort 1 and 12·0 months (6·7-20·3) in cohort 2. Partial responses were recorded in ten of 26 patients in cohort 1 (best overall response 38·5%, 95% CI 20·2-59·4). Grade 3 or 4 adverse events were recorded in 17 (65%) of 26 patients in cohort 1 and 17 (68%) of 25 patients in cohort 2; the most common grade 3 and 4 adverse events were squamous cell carcinoma of the skin (seven [27%] in cohort 1, five [20%] in cohort 2), lymphopenia (two [8%] in each cohort), and increased γ-glutamyltransferase (one [4%] in cohort 1, three [12%] in cohort 2). Two individuals in cohort 2 died due to adverse events, one from dyspnoea and one from multiorgan failure, but neither was treatment related. Serious adverse events were reported for 16 (62%) of 26 patients in cohort 1 and 17 (68%) of 25 patients in cohort 2. Vemurafenib showed antitumour activity in patients with progressive, BRAF(V600E)-positive papillary thyroid cancer refractory to radioactive iodine who had never been treated with a multikinase inhibitor. As such, this agent represents a potential new treatment option for these patients. F Hoffmann-La Roche.

In a phase 3, placebo-controlled study, lenvatinib was associated with a significant increase in progression-free survival (18.3 months vs. 3.6 months). Toxic effects with lenvatinib were substantial and included hypertension, diarrhea, and unexplained death. The 10-year survival rate among patients with differentiated thyroid cancer that is refractory to radioiodine (iodine-131) therapy is 10% from the time of detection of metastasis. 1 – 3 Although treatment options have historically been limited, efforts have first targeted vascular endothelial growth factor (VEGF) and its receptor (VEGFR), since this signaling network has been associated with the aggressiveness and metastasis of thyroid cancer. 4 – 6 However, other molecular pathways of tumor growth and maintenance beyond VEGF-driven angiogenesis contribute to the pathogenesis of thyroid cancer, including BRAF, NRAS, HRAS, RET/PTC, fibroblast growth factor receptor (FGFR), and platelet-derived growth factor receptor (PDGFR). 7 – 16 Because . . .

Inhibition of mitogen-activated protein kinase resulted in an increase in expression of the sodium–iodide symporter in 12 of 20 patients, 8 of whom had sufficient uptake to warrant treatment with radioiodine. Five patients had a response, and 3 had stable disease. Metastatic disease is the most frequent cause of death related to thyroid cancer. 1 Radioiodine (iodine-131) remains a mainstay of therapy for patients with metastatic thyroid cancer of follicular origin (i.e., papillary thyroid cancer or follicular thyroid cancer). Unfortunately, many patients have tumors that do not concentrate iodine, resulting in radioiodine resistance and a poor prognosis (the 10-year survival rate among patients with metastatic thyroid cancer that retains radioiodine avidity is approximately 60%, whereas it is only 10% if the metastases are refractory to radioiodine therapy). 2 Several trials have evaluated strategies to “redifferentiate” metastatic thyroid cancers and render them responsive to . . .

In this trial, low-dose radioiodine was as effective as high-dose radioiodine in patients with differentiated thyroid tumors, and recombinant human thyrotropin (thyrotropin alfa) was as effective as thyroid hormone withdrawal. Thyroid cancer is the most frequently occurring endocrine cancer, with more than 2100 new cases each year in the United Kingdom and more than 48,000 in the United States. 1 , 2 Most cases are differentiated thyroid cancer, which is associated with a high 10-year survival rate (90 to 95%). 3 Many patients with differentiated thyroid cancer undergo radioiodine ablation to remove residual normal thyroid tissue after surgery. Some nonrandomized studies have suggested that radioiodine ablation reduces rates of death and recurrence. 4 – 7 However, there is uncertainty over the dose (administered activity) of radioiodine required for effective ablation. A systematic review of randomized . . .

Abstract Context Risk factors for radioactive iodine (RAI)-refractory disease in follicular (FTC) and oncocytic thyroid carcinoma (OTC) are unknown. Objective The aim of this study is to identify clinical and histopathological risk factors for RAI-refractory disease in FTC and OTC patients, facilitated by an extensive histopathological revision. Methods All adult FTC and OTC patients treated at Erasmus MC (the Netherlands) between 2000 and 2016 were retrospectively included. The 2015 American Thyroid Association guidelines were used to define RAI-refractory disease. An extensive histopathological revision was performed applying the 2022 World Health Organization Classification using PALGA, the Dutch Pathology Databank. Logistic regression was used to identify risk factors for RAI-refractory disease, stratified by histological subtype. Results Ninety FTC and 52 OTC patients were included, of whom 14 FTC (15.6%) and 22 OTC (42.3%) patients developed RAI-refractory disease over a follow-up time of 8.5 years. RAI-refractory disease occurred in OTC after fewer cycles than in FTC (2.0 [interquartile range (IQR): 1.0-2.0] vs 2.5 [IQR: 2.0-3.75]), and it substantially decreased 10-year disease-specific survival, especially in OTC (46.4%; FTC 85.7%). In FTC, risk factors were higher age at diagnosis, pT3/pT4 stage, N1 stage, widely invasive tumors, and extrathyroidal extension. N1 stage and M1 stage were the strongest risk factors in OTC, rather than histopathological characteristics of the primary tumor. Conclusion To our knowledge, this is the first study that correlates clinical and histopathological risk factors with RAI-refractory disease in FTC and OTC, facilitated by a histopathological revision. In FTC, risk factors for RAI-refractory disease were foremost histopathological characteristics of the primary tumor, whereas in OTC presentation with lymph node and distant metastasis was associated with RAI-refractory disease. Our data can help clinical decision-making, particularly in patients at risk for RAI-refractory disease.

Abstract Context The specific characteristics of pediatric and adolescent differentiated thyroid cancer (DTC) is the more frequent occurrence of distant metastasis (DM) compared with adult DTC. Objective To investigate the clinical outcomes of DM in this population and analyze risk factors related to DM. Design, Setting, and Participants Medical records of 171 patients with DTC < 19 years old, who underwent initial surgery between 1979 and 2014 were retrospectively reviewed. Main Outcome Measure Clinical responses to radioiodine (RAI) therapy evaluated by the American Thyroid Association (ATA) guidelines for adult DTC and Response Evaluation Criteria in Solid Tumors (RECIST) criteria. Risk factors related to distant-metastasis-free survival (DMFS). Results DM was observed in 29 patients, and all were lung metastases. The pattern of lung metastasis was classified into 3 categories: macronodular, micronodular, and no apparent nodule (detected only by RAI scintigraphy). Patients with excellent responses according to the ATA guideline criteria or complete remission of the RECIST criteria were most frequently observed in those with no apparent nodule. Significant factors related to DMFS were sex, clinical lymph node metastasis (LNM), extrathyroidal extension, and number of LNM. Subjects were divided into 3 groups according to the number of risk factors: low risk (no risk factors); intermediate risk (1 risk factor); and high risk (≥2 risk factors). Twenty-year DMFS rates in the low-, intermediate-, and high-risk groups were 99.0%, 71.7%, and 28.6%, respectively. Conclusion To achieve the full efficacy of RAI therapy, early diagnosis of DM before apparent metastases appear is desirable. The selective approach would be preferable for pediatric and adolescent DTC.