一种在肝脏芯片模型中产生可灌注的生理样血管通道的方法。

IF 2.6 4区 工程技术 Q2 BIOCHEMICAL RESEARCH METHODS
Biomicrofluidics Pub Date : 2023-12-04 eCollection Date: 2023-12-01 DOI:10.1063/5.0170606
E Ferrari, E Monti, C Cerutti, R Visone, P Occhetta, L G Griffith, M Rasponi
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引用次数: 0

摘要

人体脉管系统在器官和组织中运输营养物质、代谢废物和维持体内平衡是必不可少的。因此,在体外器官芯片中整合血管可以提高与原生器官微环境的相似性,保证其正常的生理功能,减少实验研究与临床结果之间的差距。这种差距在药物测试中尤其明显,使用血管化模型可以在药物开发管道的临床前阶段为人类对药物的反应提供更现实的见解。在这种情况下,已经开发了不同的血管化肝脏模型来概括肝窦的结构,利用多孔膜或生物打印技术。在这项工作中,我们开发了一种在器官芯片内产生具有圆形横截面的可灌注血管通道的方法,而在薄壁组织和周围环境之间没有任何中间材料。通过该技术,设计和开发了带有或不包含Disse空间的血管化肝窦芯片系统。因此,与肝细胞与内皮细胞密切接触时相比,肝细胞与内皮细胞之间的间隙,即天然肝脏环境中存在的肝细胞与内皮细胞之间的间隙,似乎可以增强肝脏功能(例如,白蛋白的产生)。这些发现为微流控技术与血管化组织模型(如免疫系统灌注)以及多器官芯片集成的大量进一步应用铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A method to generate perfusable physiologic-like vascular channels within a liver-on-chip model.

The human vasculature is essential in organs and tissues for the transport of nutrients, metabolic waste products, and the maintenance of homeostasis. The integration of vessels in in vitro organs-on-chip may, therefore, improve the similarity to the native organ microenvironment, ensuring proper physiological functions and reducing the gap between experimental research and clinical outcomes. This gap is particularly evident in drug testing and the use of vascularized models may provide more realistic insights into human responses to drugs in the pre-clinical phases of the drug development pipeline. In this context, different vascularized liver models have been developed to recapitulate the architecture of the hepatic sinusoid, exploiting either porous membranes or bioprinting techniques. In this work, we developed a method to generate perfusable vascular channels with a circular cross section within organs-on-chip without any interposing material between the parenchyma and the surrounding environment. Through this technique, vascularized liver sinusoid-on-chip systems with and without the inclusion of the space of Disse were designed and developed. The recapitulation of the Disse layer, therefore, a gap between hepatocytes and endothelial cells physiologically present in the native liver milieu, seems to enhance hepatic functionality (e.g., albumin production) compared to when hepatocytes are in close contact with endothelial cells. These findings pave the way to numerous further uses of microfluidic technologies coupled with vascularized tissue models (e.g., immune system perfusion) as well as the integration within multiorgan-on-chip settings.

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来源期刊
Biomicrofluidics
Biomicrofluidics 生物-纳米科技
CiteScore
5.80
自引率
3.10%
发文量
68
审稿时长
1.3 months
期刊介绍: Biomicrofluidics (BMF) is an online-only journal published by AIP Publishing to rapidly disseminate research in fundamental physicochemical mechanisms associated with microfluidic and nanofluidic phenomena. BMF also publishes research in unique microfluidic and nanofluidic techniques for diagnostic, medical, biological, pharmaceutical, environmental, and chemical applications. BMF offers quick publication, multimedia capability, and worldwide circulation among academic, national, and industrial laboratories. With a primary focus on high-quality original research articles, BMF also organizes special sections that help explain and define specific challenges unique to the interdisciplinary field of biomicrofluidics. Microfluidic and nanofluidic actuation (electrokinetics, acoustofluidics, optofluidics, capillary) Liquid Biopsy (microRNA profiling, circulating tumor cell isolation, exosome isolation, circulating tumor DNA quantification) Cell sorting, manipulation, and transfection (di/electrophoresis, magnetic beads, optical traps, electroporation) Molecular Separation and Concentration (isotachophoresis, concentration polarization, di/electrophoresis, magnetic beads, nanoparticles) Cell culture and analysis(single cell assays, stimuli response, stem cell transfection) Genomic and proteomic analysis (rapid gene sequencing, DNA/protein/carbohydrate arrays) Biosensors (immuno-assay, nucleic acid fluorescent assay, colorimetric assay, enzyme amplification, plasmonic and Raman nano-reporter, molecular beacon, FRET, aptamer, nanopore, optical fibers) Biophysical transport and characterization (DNA, single protein, ion channel and membrane dynamics, cell motility and communication mechanisms, electrophysiology, patch clamping). Etc...
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