Bioengineered in vitro three-dimensional tumor models in endocrine cancers.

Endocrine-related cancer Pub Date : 2024-02-16 Print Date: 2024-04-01 DOI:10.1530/ERC-23-0344
Aleksander Skardal, Hemamylammal Sivakumar, Marco A Rodriguez, Liudmila V Popova, Priya H Dedhia
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Abstract

Graphical abstract:

Abstract: Endocrine tumors are a heterogeneous cluster of malignancies that originate from cells that can secrete hormones. Examples include, but are not limited to, thyroid cancer, adrenocortical carcinoma, and neuroendocrine tumors. Many endocrine tumors are relatively slow to proliferate, and as such, they often do not respond well to common antiproliferative chemotherapies. Therefore, increasing attention has been given to targeted therapies and immunotherapies in these diseases. However, in contrast to other cancers, many endocrine tumors are relatively rare, and as a result, less is understood about their biology, including specific targets for intervention. Our limited understanding of such tumors is in part due to a limitation in model systems that accurately recapitulate and enable mechanistic exploration of these tumors. While mouse models and 2D cell cultures exist for some endocrine tumors, these models often may not accurately model nuances of human endocrine tumors. Mice differ from human endocrine physiology and 2D cell cultures fail to recapitulate the heterogeneity and 3D architectures of in vivo tumors. To complement these traditional cancer models, bioengineered 3D tumor models, such as organoids and tumor-on-a-chip systems, have advanced rapidly in the past decade. However, these technologies have only recently been applied to most endocrine tumors. In this review we provide descriptions of these platforms, focusing on thyroid, adrenal, and neuroendocrine tumors and how they have been and are being applied in the context of endocrine tumors.

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内分泌癌症的生物工程体外三维肿瘤模型。
内分泌肿瘤是一种起源于能分泌激素的细胞的异质性恶性肿瘤。内分泌肿瘤包括但不限于甲状腺癌、肾上腺皮质癌和神经内分泌肿瘤。许多内分泌肿瘤的增殖速度相对较慢,因此,它们通常对常见的抗增殖化疗反应不佳。因此,针对这些疾病的靶向疗法和免疫疗法受到越来越多的关注。然而,与其他癌症相比,许多内分泌肿瘤相对罕见,因此人们对它们的生物学特性,包括具体的干预靶点了解较少。我们对此类肿瘤的了解有限,部分原因在于能准确再现这些肿瘤并对其进行机理探索的模型系统有限。虽然一些内分泌肿瘤有小鼠模型和二维(2D)细胞培养,但这些模型往往不能准确模拟人类内分泌肿瘤的细微差别。小鼠与人类内分泌生理学不同,二维细胞培养无法再现体内肿瘤的异质性和三维结构。为了补充这些传统的癌症模型,生物工程三维肿瘤模型(如器官组织和肿瘤芯片系统)在过去十年中发展迅速。然而,这些技术直到最近才被应用于大多数内分泌肿瘤。在这篇综述中,我们将介绍这些平台,重点关注甲状腺、肾上腺和神经内分泌肿瘤,以及它们在内分泌肿瘤中的应用情况。
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