Keywords
thyroid gland, carcinoma, adenoma, invasion, histological classification, TNM classification
How to Cite
Bogdanova, T., Zurnadzhi, L. Y., Kovalenko, A., Bolgov, M., Chernishev, S., & Tronko, M. (2017). Changes in the pathological diagnoses of thyroid tumors after the introduction into practice of the 4th edition of the Histological classification of tumors of the endocri ne organs of WHO, and the 8 th edition of the TNM classification, which can influen. Endokrynologia, 22(4), 375-380. Retrieved from https://endokrynologia.com.ua/index.php/journal/article/view/105
Abstract
New pathological diagnoses of encapsulated thyroid tumors are described in accordance with the 4th edition of WHO Histology classification (WDTUMP, FTUMP, WDCaNOS, NIFTP),
which should be taken into account not only by pathologists, but also by endocrine surgeons of Ukraine, as they can lead to changes in the tactics of surgical treatment. New requirements for the pT3 category of thyroid carcinoma are considered in accordance with the 8th edition of the TNM Classification. Using the examples of own data, the possible frequency of new pathological diagnoses and changes in the pT category of the new TNM Classification was demonstrated
References
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6. Tronko M, Brenner A, Bogdanova T, Shpak V, Oliynyk V, Cahoon E, et al. Thyroid neoplasia risk is increased nearly 30 years after the Chernobyl accident. Int. J. Cancer. 2017;141:1585-8.
7. Zablotska LB, Nadyrov EA, Rozhko AV, Gong Z, Polyanskaya ON, McConnell RJ, et al. Analysis of thyroid malignant pathologic findings identified during 3 rounds of screening (1997-2008) of a cohort of children and adolescents from Belarus exposed to radioiodines after the Chernobyl accident. Cancer. 2014;121:457-66. 8. Ahn HS, Kim HJ, Welch HG. Korea’s thyroid-cancer «epidemic»–screening and overdiagnosis. N Engl J Med. 2014; 371:1765-7.
9. Ahn HS, Kim HJ, Kim KH, Lee YS, Han SJ, Kim Y, et al. Thyroid cancer screening in South Korea increases detection of papillary cancers no impact on other subtypes or thyroid cancer mortality. Thyroid. 2016;26:1535-40.
10. Yamashita S. Comprehensive health risk managements after the Fukushima Nuclear Power Plant accident. Clinical Oncology. 2016;28:255-62.
2. Fridman M, King-yin Lam A, Krasko O, Schmid KW, Branovan DI, Demidchik Yu. Morphological and clinical presentation of papillary thyroid carcinoma in children and adolescents of Belarus: The influence of radiation exposure and the source of irradiation. Experimental and Molecular Pathology. 2015; 98:527-31.
3. Demidchik YuE, Fridman MV, Mankovskaya S, Krasko O, Schmid KW, Lam AK, et al. Post-Chernobyl Pediatric Papillary Thyroid Carcinoma in Belarus: Histopathological Features, Treatment Strategy, and Long-Term Outcome. In: Yamashita S, Thomas G, editors. Thyroid cancer and Nuclear accidents — long term after effects of Chernobyl and Fukushima. Amsterdam: Elsevier. 2017:49-58.
4. Brenner AV, Tronko MD, Hatch M, Bogdanova TI, Oliynik VA, Lubin JH, et al. I‑131 dose response for incident thyroid cancers in Ukraine related to the Chornobyl accident. Environ Health Perspect. 2011Jul;19(7):933-9.
5. Tronko M, Brenner A, Bogdanova T, Shpak V, Hatch M, Likhtarev I, et al. Thyroid cancer risk in Ukraine following the Chernobyl accident (the Ukrainian-American cohort thyroid study). In: Yamashita S, Thomas G, editors. Thyroid cancer and Nuclear accidents — long term after effects of Chernobyl and Fukushima. Amsterdam: Elsevier. 2017:77-86.
6. Tronko M, Brenner A, Bogdanova T, Shpak V, Oliynyk V, Cahoon E, et al. Thyroid neoplasia risk is increased nearly 30 years after the Chernobyl accident. Int. J. Cancer. 2017;141:1585-8.
7. Zablotska LB, Nadyrov EA, Rozhko AV, Gong Z, Polyanskaya ON, McConnell RJ, et al. Analysis of thyroid malignant pathologic findings identified during 3 rounds of screening (1997-2008) of a cohort of children and adolescents from Belarus exposed to radioiodines after the Chernobyl accident. Cancer. 2014;121:457-66. 8. Ahn HS, Kim HJ, Welch HG. Korea’s thyroid-cancer «epidemic»–screening and overdiagnosis. N Engl J Med. 2014; 371:1765-7.
9. Ahn HS, Kim HJ, Kim KH, Lee YS, Han SJ, Kim Y, et al. Thyroid cancer screening in South Korea increases detection of papillary cancers no impact on other subtypes or thyroid cancer mortality. Thyroid. 2016;26:1535-40.
10. Yamashita S. Comprehensive health risk managements after the Fukushima Nuclear Power Plant accident. Clinical Oncology. 2016;28:255-62.
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