Nuclear Imaging Modalities in the Diagnosis and Management of Thyroid Cancer.

IF 2.2 4区医学 Q3 MEDICINE, RESEARCH & EXPERIMENTAL

Current molecular medicine Pub Date : 2024-01-01 DOI:10.2174/1566524023666230915103723

Namit Kant Singh, Neemu Hage, Balaji Ramamourthy, Sushmitha Nagaraju, Krishna Medha Kappagantu

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引用次数: 0

Abstract

In this review we have brought forward various nuclear imaging modalities used in the diagnosis, staging, and management of thyroid cancer. Thyroid cancer is the most common endocrine malignancy, accounting for approximately 3% of all new cancer diagnoses. Nuclear imaging plays an important role in the evaluation of thyroid cancer, and the use of radioiodine imaging, FDG imaging, and somatostatin receptor imaging are all valuable tools in the management of this disease. Radioiodine imaging involves the use of Iodine-123 [I-123] or Iodine-131 [I-131] to evaluate thyroid function and detect thyroid cancer. I-123 is a gamma-emitting isotope that is used in thyroid imaging to evaluate thyroid function and detect thyroid nodules. I-131 is a beta-emitting isotope that is used for the treatment of thyroid cancer. Radioiodine imaging is used to detect the presence of thyroid nodules and evaluate thyroid function. FDG imaging is a PET imaging modality that is used to evaluate the metabolic activity of thyroid cancer cells. FDG is a glucose analogue that is taken up by cells that are metabolically active, such as cancer cells. FDG PET/CT can detect primary thyroid cancer and metastatic disease, including lymph nodes and distant metastases. FDG PET/CT is also used to monitor treatment response and detect the recurrence of thyroid cancer. Somatostatin receptor imaging involves the use of radiolabeled somatostatin analogues to detect neuroendocrine tumors, including thyroid cancer. Radiolabeled somatostatin analogues, such as Indium-111 octreotide or Gallium-68 DOTATATE, are administered to the patient, and a gamma camera is used to detect areas of uptake. Somatostatin receptor imaging is highly sensitive and specific for the detection of metastatic thyroid cancer. A comprehensive search of relevant literature was done using online databases of PubMed, Embase, and Cochrane Library using the keywords "thyroid cancer," "nuclear imaging," "radioiodine imaging," "FDG PET/CT," and "somatostatin receptor imaging" to identify relevant studies to be included in this review. Nuclear imaging plays an important role in the diagnosis, staging, and management of thyroid cancer. The use of radioiodine imaging, thyroglobulin imaging, FDG imaging, and somatostatin receptor imaging are all valuable tools in the evaluation of thyroid cancer. With further research and development, nuclear imaging techniques have the potential to improve the diagnosis and management of thyroid cancer and other endocrine malignancies.

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核成像在甲状腺癌症诊断和治疗中的应用。

在这篇综述中，我们提出了用于癌症诊断、分期和管理的各种核成像模式。甲状腺癌症是最常见的内分泌恶性肿瘤，约占癌症新诊断的3%。核成像在甲状腺癌症的评估中起着重要作用，使用放射性碘成像、FDG成像和生长抑素受体成像都是治疗该疾病的宝贵工具。放射性碘成像包括使用碘-123[I-123]或碘-131[I-131]来评估甲状腺功能和检测甲状腺癌症。I-123是一种γ发射同位素，用于甲状腺成像评估甲状腺功能和检测甲状腺结节。I-131是一种β-发射同位素，用于治疗甲状腺癌症。放射性碘成像用于检测甲状腺结节的存在并评估甲状腺功能。FDG成像是一种PET成像方式，用于评估甲状腺癌症细胞的代谢活性。FDG是一种葡萄糖类似物，被代谢活跃的细胞（如癌症细胞）吸收。FDGPET/CT可以检测原发性甲状腺癌症和转移性疾病，包括淋巴结和远处转移。FDGPET/CT也用于监测治疗反应和检测癌症的复发。生长抑素受体成像涉及使用放射性标记的生长抑素类似物来检测神经内分泌肿瘤，包括甲状腺癌症。给患者服用放射性标记的生长抑素类似物，如铟-111奥曲肽或镓-68 DOTATATE，并使用伽马相机检测摄取区域。生长抑素受体成像对检测转移性甲状腺癌症具有高度敏感性和特异性。方法：使用PubMed、Embase和Cochrane图书馆的在线数据库，使用关键字“甲状腺癌症”、“核成像”、“放射性碘成像”、FDG PET/CT和“生长抑素受体成像”，全面检索相关文献，以确定将纳入本综述的相关研究。结论：核成像在癌症的诊断、分期和治疗中具有重要作用。放射性碘成像、甲状腺球蛋白成像、FDG成像和生长抑素受体成像的使用都是评估甲状腺癌症的有价值的工具。随着研究和发展，核成像技术有可能改善甲状腺癌症和其他内分泌恶性肿瘤的诊断和管理。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Current molecular medicine 医学-医学：研究与实验

CiteScore

5.00

自引率

4.00%

发文量

141

审稿时长

4-8 weeks

期刊介绍： Current Molecular Medicine is an interdisciplinary journal focused on providing the readership with current and comprehensive reviews/ mini-reviews, original research articles, short communications/letters and drug clinical trial studies on fundamental molecular mechanisms of disease pathogenesis, the development of molecular-diagnosis and/or novel approaches to rational treatment. The reviews should be of significant interest to basic researchers and clinical investigators in molecular medicine. Periodically the journal invites guest editors to devote an issue on a basic research area that shows promise to advance our understanding of the molecular mechanism(s) of a disease or has potential for clinical applications.