Université de Technologie de Compiègne, CNRS, Biomechanics and Bioengineering, Centre de Recherche Royallieu, CS 60319, 60203 Compiègne Cedex, France.
CNRS/IIS/Centre Oscar Lambret/Lille University SMMiL-E Project, CNRS Délégation Hauts-de-France, 43 Avenue le Corbusier, 59800 Lille, France; CNRS, IRL2820, Laboratory for Integrated Micro Mechatronic Systems, Institute of Industrial Science, University of Tokyo, 4-6-1 Komaba, Meguro-ku, Tokyo 153-8505, Japan.
J Biosci Bioeng. 2024 Jan;137(1):64-75. doi: 10.1016/j.jbiosc.2023.10.006. Epub 2023 Nov 14.
The liver is one of the main organs involved in the metabolism of xenobiotics and a key organ in toxicity studies. Prior to accessing the hepatocytes, xenobiotics pass through the hepatic sinusoid formed by liver sinusoidal endothelial cells (LSECs). The LSECs barrier regulates the kinetics and concentrations of the xenobiotics before their metabolic processing by the hepatocytes. To mimic this physiological situation, we developed an in vitro model reproducing an LSECs barrier in coculture with a hepatocyte biochip, using a fluidic platform. This technology made dynamic coculture and tissue crosstalk possible. SK-HEP-1 and HepG2/C3a cells were used as LSECs and as hepatocyte models, respectively. We confirmed the LSECs phenotype by measuring PECAM-1 and stabilin-2 expression levels and the barrier's permeability/transport properties with various molecules. The tightness of the SK-HEP-1 barrier was enhanced in the dynamic coculture. The morphology, albumin secretion, and gene expression levels of markers of HepG2/C3a were not modified by coculture with the LSECs barrier. Using acetaminophen, a well-known hepatotoxic drug, to study tissue crosstalk, there was a reduction in the expression levels of the LSECs markers stabilin-2 and PECAM-1, and a modification of those of CLEC4M and KDR. No HepG2/C3a toxicity was observed. The metabolisation of acetaminophen by HepG2/C3a monocultures and cocultures was confirmed. Although primary cells are required to propose a fully relevant model, the present approach highlights the potential of our system for investigating xenobiotic metabolism and toxicity.
肝脏是参与外源化学物代谢的主要器官之一,也是毒性研究的关键器官。在进入肝细胞之前,外源化学物要通过由肝窦内皮细胞(LSEC)形成的肝窦循环。LSEC 屏障调节着外源化学物在被肝细胞代谢之前的动力学和浓度。为了模拟这种生理情况,我们开发了一种在体外模型中,使用流体平台在与肝细胞生物芯片的共培养中再现 LSEC 屏障的方法。该技术使动态共培养和组织串扰成为可能。SK-HEP-1 和 HepG2/C3a 细胞分别被用作 LSEC 和肝细胞模型。我们通过测量 PECAM-1 和 stabilin-2 的表达水平以及各种分子的屏障通透性/转运特性来确认 LSEC 的表型。在动态共培养中,SK-HEP-1 屏障的紧密性增强。与 LSEC 屏障共培养并未改变 HepG2/C3a 的形态、白蛋白分泌和基因表达水平。使用对乙酰氨基酚(一种众所周知的肝毒性药物)来研究组织串扰,结果显示 LSEC 标志物 stabilin-2 和 PECAM-1 的表达水平降低,CLEC4M 和 KDR 的表达水平发生了改变。未观察到 HepG2/C3a 的毒性。在 HepG2/C3a 单培养和共培养中均证实了对乙酰氨基酚的代谢。尽管需要原代细胞来提出一个完全相关的模型,但本方法突出了我们的系统在研究外源化学物代谢和毒性方面的潜力。
