References
Sung H., et al., Global Cancer Statistics 2020: GLOBOCAN Estimates of Incidence and Mortality Worldwide for 36 Cancers in 185 Countries. CA: A Cancer Journal for Clinicians, Vol. 71 No. 3 (2021): Volume 71 Issue 3, 209-249
Vaccarella S., et al, The Impact of Diagnostic Changes on the Rise in Thyroid Cancer Incidence, A Population-Based Study in Selected High-Resource Countries. Thyroid: Vol. 26 No. 8 (2021): Volume 26 Issue 8, 1127-1135
Cibas E. S., & Ali S. Z., The 2017 Bethesda System for Reporting Thyroid, Cytopathology Thyroid: Vol. 27 No. 11(2017): Volume 27 Issue 11, 1341-1346
Haugen B. R., et al., 2015 American Thyroid Association Management Guidelines for Adult Patients with Thyroid Nodules and Differentiated Thyroid Cancer, Thyroid: Vol. 26 No. 1, Volume 26 Issue 1 (2016): 1-133
Luca Giovanella, Thyroglobulin measurement in differentiated thyroid carcinoma management, Expert Review of Endocrinology & Metabolism; Vol 3 No 2 (2008): Volume 3 Issue 2, 117-125
Siravegna G., et al., Integrating liquid biopsies into the management of cancer, Nature Reviews Clinical Oncolog: Vol. 14 No. 9 (2017): 531-548
Ignatiadis M., et al., Liquid biopsy enters the clinic — implementation issues and future challenges, Nature Reviews Clinical Oncology: Vol. 18 No. 5 (2021): Volume 18 Issue 5, 297-312
Page M. J., et al., The PRISMA 2020 statement, an updated guideline for reporting systematic reviews: BMJ, Volume 372 Issue 71
Whiting P. F., et al., QUADAS-2: a revised tool for the quality assessment of diagnostic accuracy studies, Annals of Internal Medicine: Vol. 155 No. 8 (2011): Volume 155 Issue 8, 529-536
Wells G. A., et al., The Newcastle-Ottawa Scale (NOS) for assessing the quality of nonrandomised studies in meta-analyses, Ottawa Hospital Research Institute: (2000)
Zill O. A., et al., The Landscape of Actionable Genomic Alterations in Cell-Free Circulating Tumor DNA from 21,807 Advanced Cancer Patients, Clinical Cancer Research: Vol. 24 No. 15 (2018): Volume 24 Issue 15, 3528-3538
Kim K. W., et al., Clinical Utility of Circulating Tumor DNA Analysis in the Diagnosis and Management of Thyroid Cancer, Endocrinology and Metabolism: Vol. 35 No. 2 (2020): Volume 35 Issue 2, 295-305
Lan X., et al., Diagnostic accuracy of circulating tumor DNA for BRAF V600E mutation in papillary thyroid carcinoma: a systematic review and meta-analysis, Clinical Chemistry and Laboratory Medicine: Vol. 59 No. 5 (2021): Volume 59 Issue 5, 843-851
Priyanka C. Iyer, Gilbert J. Cote, Tao Hai, Maria Gule-Monroe, Jacquelin Bui-Griffith, Michelle D. Williams, Kenneth Hess., Circulating BRAF V600E Cell-Free DNA as a Biomarker in the Management of Anaplastic Thyroid Carcinoma, JCO Precis Oncol 2: Volume 2 (2018): 1
Tatiana Marina Vieira Giorgenon, et al, Preoperative detection of TERT promoter and BRAFV600E mutations in papillary thyroid carcinoma in high-risk thyroid nodules , Arch Endocrinol Metab: Vol. 63 No. 02 (2025): Vol. 63 Issue 02, 107–112.
Zhang L., et al., Epithelial-Mesenchymal Plasticity in Circulating Tumor Cells Predicts Distant Metastasis in Radioiodine-Refractory Thyroid Cancer, Cancer Research: Vol. 82 No. 14 (2022): Volume 82 Issue 14, 2581-2592
Monia Bordoni., et. al., Open AccessReview, Towards an Integrated Multi-Omic Approach to Improve the Diagnostic Accuracy of Fine-Needle Aspiration in Thyroid Nodules with Indeterminate Cytology, Diagnostics: Vol. 15 N. 12 (2025): Volume 15 Issue 12
Cristiano S., et al., Genome-wide cell-free DNA fragmentation in patients with cancer, Nature: Vol. 570 No. 7761 (2019): Volume 570 Issue 7761, 385-389
Matthew Z Guo., et.al. Postsurgical circulating tumor DNA as a prognostic biomarker for relapse of resected pancreatic ductal adenocarcinoma, Gastrointest Surg: Vol. 30 No. 04 (2026): Volüme 30 Issue 04
Picchi G., et al., Predictive Value of Circulating BRAF V600E ctDNA in Biochemically Persistent Differentiated Thyroid Cancer, Thyroid: Vol. 33 No. 9 (2023): Volume 33 Issue 9, 1104-1112.
Schlumberger M., et al., Lenvatinib in Radioiodine-Refractory Thyroid Cancer: ctDNA Dynamics as an Early Pharmacodynamic Biomarker of Response, Journal of Clinical Oncology: Vol. 39 No. 15_suppl (2021): Volume 39 Issue 15 suppl, 6015
Wirth L J., et al., Efficacy of Selpercatinib in RET-Altered Thyroid Cancers, New England Journal of Medicine: Vol. 383 No. 9 (2020): Volume 383 Isssue 9 825-835
Solomon B J., et al., Acquired Resistance to RET Inhibitors in RET-Driven Cancers: Genomic Mechanisms from Serial ctDNA Analysis, Cancer Discovery: Vol. 13 No. 4 (2023): Volume 13 Issue 4, 874-889
Seok Jin Kim., Circulating Tumor DNA-Based Genotyping and Monitoring for Predicting Disease Relapses of Patients with Peripheral T-Cell Lymphomas, Cancer Res Treat: Vol 55 No 1 (2023): Volume 55 Issue 1, 291-303
Dinah V Parums, A Review of Circulating Tumor DNA (ctDNA) and the Liquid Biopsy in Cancer Diagnosis, Screening, and Monitoring Treatment Response, Med Sci Monit: 2025: doi: 10.12659/MSM.949300.
Zou Z., Zhong L., Anaplastic thyroid cancer: Genetic roles, targeted therapy, and immunotherapy, Genes & Diseases: Vol 12 No 4 (2025): Volume 12 Issue 4
Charu Aggarwal, Assessment of Tumor Mutational Burden and Outcomes in Patients With Diverse Advanced Cancers Treated With Immunotherapy, JAMA Netw Open: Vol 6 No 5 (2023): Volume 6 Issue 5
Gila Lithwick-Yanai, Multicentre validation of a microRNA-based assay for diagnosing indeterminate thyroid nodules utilising fine needle aspirate smears, J Clin Pathol: Vol 70 No 6 (2017): Volume 70 Issue 6, 500–507
Pritchard C. C., et al., Blood cell origin of circulating microRNAs: a cautionary note for cancer biomarker studies. Cancer Prevention Research: Vol. 5 No. 3 (2012): Volume 5 Issue 3, 492-497
Walsh P. S., et al., Analytical and Clinical Validation of ThyraMIR-B, a Next-Generation Sequencing-Based Circulating miRNA Assay for Thyroid Nodule Diagnosis, Clinical Chemistry,:Vol. 70 No. 4 (2024): Volume 70 Issue 4, 567-579
Sin Woo Kang, Diagnostic Models for Predicting Follicular Thyroid Carcinomas Using Circulating Plasma MicroRNAs, Cancers (Basel): Vol 17 No 21 (2025): Volume 17 Issue 21
YANQING ZHANG1, Dynamic monitoring of circulating microRNAs as a predictive biomarker for the diagnosis and recurrence of papillary thyroid carcinoma, ONCOLOGY LETTERS 13: (2017): 4252-4266
Xuan Zou, A three-microRNA panel in serum as novel biomarker for papillary thyroid carcinoma diagnosis, Chin Med J (Engl): Vol 133 No 21 (2020): Volume 133 Isuse 21, 2543–2551
Hashem Khanbabaei, Non-coding RNAs in cancer and epithelial-mesenchymal transition: molecular mechanisms and clinical implications, J Experimental Clinical Cancer Research: Vol 16 No. 41(2022): Volume 16 Issue 41, 278, doi: 10.1186/s13046-022-02488-x
Xu J. Y., et al., Detection and Characterization of Circulating Tumor Cells in Patients with Thyroid Cancer, Endocrine: Vol. 53 No. 3 (2016): Volume 53 Issue 3, 737-745
Miller M. C., et al., The Parsortix Cell Separation System – A versatile liquid biopsy platform, Cytometry Part A: Vol. 93 No. 12 (2018): Volume 93 Issue 12, 1234-1239
Qatar Medical Journa igbal Amer, Role of epithelial-mesenchymal markers in predicting metastasis of papillary thyroid carcinoma, A retrospective case-control study: Volume/Issue: Volume 2025: Issue 2
Lina Lu., Anaplastic transformation in thyroid cancer revealed by single-cell transcriptomics, The Journal of clinical investigation: June 2023, Vol 133 No 11 (2023): Volume 133 Issue 11
Hodgkinson C. L., et al., Tumorigenicity and genetic profiling of circulating tumor cells in small-cell lung cancer, Nature Medicine: Vol. 20 No. 8 (2014): Volume 20 Issue 8, 897-903. [Note: This is a reference for the CDX method, adapted by a 2023 study for MTC].
Yuxin Min., et.al., Single extracellular vesicle surface protein-based blood assay identifies potential biomarkers for detection and screening of five cancers, Mol Oncol: Vol 18 No 3 (2024): Volume 18 Issue 3, 743-761
Melo S. A., et al., Glypican-1 identifies cancer exosomes and detects early pancreatic cancer, Nature: Vol. 523 No. 7559 (2015): Volume 523 Issue 7559, 177-182. [Note: Foundational EV reference, with the 2024 study being a direct methodological descendant].
Kyung-A Kim, Sunmin Kim, Inbal Wortzel, Suho Lee, Yoon Dae Han, Tae-Min Kim, Han Sang Kim, Genome-wide methylation profiling reveals extracellular vesicle DNA as an ex vivo surrogate of cancer cell-derived DNA, Sci Rep: Vol 14 No 1 (2024): Volume 14 Issue 1
Proteomics study of serum exosomes from papillary thyroid cancer patient, Endocrine-Related Cancer, June 2018: 25 (10): ERC-17-0547., DOI:10.1530/ERC-17-0547
Ymke van der Pol., Real-time analysis of the cancer genome and fragmentome from plasma and urine cell-free DNA using nanopore sequencing, EMBO Mol Med: Vol 15 No 12 (2023): Volume 15 Issue 12
Shubin Hong, Cell-free DNA methylation biomarker for the diagnosis of papillary thyroid carcinoma, BioMedicine: Vol. 90 (2023): 104497
Meng Jia, MicroRNA-146b-5p as an oncomiR promotes papillary thyroid carcinoma development by targeting CCDC6, Cancer Lett: 2019 Feb 28: 443: 145-156
Cancer Biomark, Circulating microRNA as potential diagnostic and prognostic biomarkers of well-differentiated thyroid cancer, A review article Cezary Bielak: 2023;Vol 36 No 3 (2023): Volume 36 Issue 3, 193-205
Davies L., & Welch, H. G., Current thyroid cancer trends in the United States, JAMA Otolaryngology–Head & Neck Surgery: Vol. 140 No. 4 (2014): Volume 140 Issue 4, 317-322.
Fagin J. A., & Wells S. A., Biologic and Clinical Perspectives on Thyroid Cancer, New England Journal of Medicine: Vol. 375 No. 11 (2016): Volume 375 Issue 1, 1054-1067
Alix-Panabières C., & Pantel K., Liquid Biopsy: From Discovery to Clinical Application, Cancer Discovery: Vol. 11 No. 4 (2021): Volume 11 Issue 4, 858-873