Dynamic culture of cerebral organoids using a pillar/perfusion plate for the assessment of developmental neurotoxicity.

IF 8.2 2区 医学 Q1 ENGINEERING, BIOMEDICAL Biofabrication Pub Date : 2024-10-24 DOI:10.1088/1758-5090/ad867e
Prabha Acharya, Sunil Shrestha, Pranav Joshi, Na Young Choi, Vinod Kumar Reddy Lekkala, Soo-Yeon Kang, Gabriel Ni, Moo-Yeal Lee
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Abstract

Despite the potential toxicity of commercial chemicals to the development of the nervous system (known as developmental neurotoxicity or DNT), conventionalin vitrocell models have primarily been employed for the assessment of acute neuronal toxicity. On the other hand, animal models used for the assessment of DNT are not physiologically relevant due to the heterogenic difference between humans and animals. In addition, animal models are low-throughput, time-consuming, expensive, and ethically questionable. Recently, human brain organoids have emerged as a promising alternative to assess the detrimental effects of chemicals on the developing brain. However, conventional organoid culture systems have several technical limitations including low throughput, lack of reproducibility, insufficient maturity of organoids, and the formation of the necrotic core due to limited diffusion of nutrients and oxygen. To address these issues and establish predictive DNT models, cerebral organoids were differentiated in a dynamic condition in a unique pillar/perfusion plate, which were exposed to test compounds to evaluate DNT potential. The pillar/perfusion plate facilitated uniform, dynamic culture of cerebral organoids with improved proliferation and maturity by rapid, bidirectional flow generated on a digital rocker. Day 9 cerebral organoids in the pillar/perfusion plate were exposed to ascorbic acid (DNT negative) and methylmercury (DNT positive) in a dynamic condition for 1 and 3 weeks, and changes in organoid morphology and neural gene expression were measured to determine DNT potential. As expected, ascorbic acid did not induce any changes in organoid morphology and neural gene expression. However, exposure of day 9 cerebral organoids to methylmercury resulted in significant changes in organoid morphology and neural gene expression. Interestingly, methylmercury did not induce adverse changes in cerebral organoids in a static condition, thus highlighting the importance of dynamic organoid culture in DNT assessment.

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利用支柱/灌注板动态培养脑有机体,以评估发育期神经毒性。
尽管商业化学品对神经系统的发育具有潜在毒性(称为发育神经毒性或 DNT),但传统的体细胞模型主要用于评估急性神经元毒性。另一方面,用于评估 DNT 的动物模型由于人与动物之间的异源性差异而与生理不相关。此外,动物模型通量低、耗时长、成本高,在伦理方面也存在问题。最近,人脑类器官成为评估化学物质对发育中大脑有害影响的一种有前途的替代方法。然而,传统的类器官培养系统存在一些技术限制,包括通量低、缺乏可重复性、类器官成熟度不够,以及由于营养物质和氧气扩散受限而形成坏死核心。为了解决这些问题并建立预测性 DNT 模型,我们在一个独特的支柱/灌注板中动态分化了脑有机体,并将其暴露于测试化合物以评估 DNT 潜力。支柱/灌注板通过数字摇杆上产生的快速双向流动,促进了脑有机体的均匀、动态培养,提高了增殖和成熟度。将支柱/灌注板中第 9 天的脑有机体在动态条件下暴露于抗坏血酸(DNT 阴性)和甲基汞(DNT 阳性)1 周和 3 周,测量有机体形态和神经基因表达的变化,以确定 DNT 电位。不出所料,抗坏血酸没有引起类器官形态和神经基因表达的任何变化。然而,将第 9 天的大脑有机体暴露于甲基汞会导致有机体形态和神经基因表达发生显著变化。有趣的是,在静态条件下,甲基汞并没有诱导大脑类器官发生不良变化,这突出了动态类器官培养在 DNT 评估中的重要性。
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来源期刊
Biofabrication
Biofabrication ENGINEERING, BIOMEDICAL-MATERIALS SCIENCE, BIOMATERIALS
CiteScore
17.40
自引率
3.30%
发文量
118
审稿时长
2 months
期刊介绍: Biofabrication is dedicated to advancing cutting-edge research on the utilization of cells, proteins, biological materials, and biomaterials as fundamental components for the construction of biological systems and/or therapeutic products. Additionally, it proudly serves as the official journal of the International Society for Biofabrication (ISBF).
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