Ex vivo models for intestinal translocation studies of cellulose nanocrystals.

In vitro models Pub Date : 2023-08-21 eCollection Date: 2023-11-01 DOI:10.1007/s44164-023-00056-x

Michelle Müller, Roland Drexel, Marie Burkhart, Stephan Dähnhardt-Pfeiffer, Lena Wien, Christine Herrmann, Thorsten Knoll, Christoph Metzger, Heiko Briesen, Sylvia Wagner, Florian Meier, Yvonne Kohl

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Abstract

Purpose: Cellulose nanocrystals (CNC) play a promising role in the development of new advanced materials. The growing demand of CNC-containing products in the food industry will lead to an increased human exposure through oral uptake. To date, there is a dearth of studies reporting on the risks which CNC pose to human health following ingestion. In vitro models, which lack physiological accuracy, are often used to justify animal experiments in the field of nanosafety assessment. Nevertheless, ex vivo models of the intestine pose promising alternatives to in vivo experiments.

Methods: Two ex vivo models, a microfluidic chip based on porcine intestinal mucus and the Ussing chamber apparatus with tissue from abattoirs, which aim to complement in vitro models, are characterized by investigating the transport and toxicity of CNC through them in comparison to an in vitro triple co-culture model. Silver nanoparticles were included in this study as well-known and characterized nanomaterials for comparative purposes.

Results: Study results show that CNC cross the intestinal mucus layer but do not pass the intestinal tissue barrier ex vivo and in vitro; furthermore, no toxic effects were observed under exposure conditions tested.

Conclusion: These ex vivo models present complementary methods to the existing standardized in vitro and in silico methods to support data generation under physiologically relevant conditions without the use of animals. This multi-model approach offers an enhanced understanding of the complex interaction between new materials and human tissue and aligns with the flexible approach of IATA (Integrated Approaches to Testing and Assessment) and NAMs (New Approach Methods) for chemical and drug safety assessment.

Supplementary information: The online version contains supplementary material available at 10.1007/s44164-023-00056-x.

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纤维素纳米晶体肠道易位研究的离体模型。

目的：纤维素纳米晶体（CNC）在新型先进材料的开发中具有广阔的应用前景。食品工业对含cnc产品的需求不断增长，将导致人类通过口服摄入的接触量增加。迄今为止，缺乏关于摄入CNC后对人体健康构成风险的研究报告。体外模型缺乏生理准确性，经常被用来证明纳米安全性评估领域的动物实验是合理的。然而，离体肠道模型为体内实验提供了有希望的替代方案。方法：采用猪肠黏液微流控芯片和屠宰场组织ususing chamber装置两种离体模型作为体外模型的补充，研究CNC通过它们的转运和毒性，并与体外三联培养模型进行比较。银纳米粒子被包括在这项研究中，作为众所周知的和表征的纳米材料进行比较。结果：研究结果表明，CNC在体内和体外均能穿过肠道黏液层，但不通过肠道组织屏障；此外，在测试的暴露条件下没有观察到毒性作用。结论：这些离体模型为现有的标准化体外和计算机方法提供了补充方法，支持在生理相关条件下无需使用动物的数据生成。这种多模型方法增强了对新材料与人体组织之间复杂相互作用的理解，并与IATA（测试和评估综合方法）和NAMs（化学和药物安全评估新方法）的灵活方法保持一致。补充信息：在线版本包含补充资料，提供地址为10.1007/s44164-023-00056-x。

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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In vitro models

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