Gozalpour Elnaz, Fenner Katherine S
Safety and ADME Translational Sciences Department, Drug Safety and Metabolism, IMED Biotech Unit, AstraZeneca R&D, Cambridge CB4 0FZ, United Kingdom.
Curr Drug Metab. 2018;19(4):310-326. doi: 10.2174/1389200219666180119115133.
Renal proximal tubule (PT) epithelial cells, expressing uptake and efflux transporters at basolateral and apical membranes, are the location of active renal drug secretion and reabsorption. In addition to singly transfected cells, an in vitro renal cell-based model is a requirement to study the active renal secretion of drugs, drug-drug interactions (DDIs), drug-induced kidney injury, nephrotoxicity holistically and potentially renal replacement therapies.
So far, two-dimensional (2D) cell culture of primary and immortalized PT cells has been the only tool to study drugs active secretion, interactions and nephrotoxicity, however a number of in vivo characteristics of cells such as drug transporter expression and function, along with morphological features are lost during in vitro cell culture. Cellular microenvironment, extracellular matrix, cell-cell interactions, microfluidic environment and tubular architecture are the factors lacking in 2D cell culture. Currently, there are a few 3D cell culture platforms mimicking the in vivo conditions of PT cells and thus potentially enabling the necessary factors for the full functional PT cells.
In this review, we address in vivo physiological and morphological characteristics of PT cells, comparing their available sources and remaining in vivo features. In addition, 2D and 3D cell culture platforms and the influence of cell culture architecture on the physiological characteristics of cells are reviewed. Finally, future perspective of 3D models, kidney and multi organs on a chip, generation of kidney organoids, other ex vivo renal models and their capabilities to study drug disposition and in vitro-in vivo extrapolation are described.
肾近端小管(PT)上皮细胞在基底外侧膜和顶端膜表达摄取和外排转运体,是肾脏药物主动分泌和重吸收的场所。除了单个转染细胞外,基于肾细胞的体外模型是全面研究药物的肾脏主动分泌、药物-药物相互作用(DDIs)、药物性肾损伤、肾毒性以及潜在的肾脏替代疗法所必需的。
到目前为止,原代和永生化PT细胞的二维(2D)细胞培养一直是研究药物主动分泌、相互作用和肾毒性的唯一工具,然而,细胞的许多体内特征,如药物转运体的表达和功能,以及形态特征在体外细胞培养过程中会丢失。细胞微环境、细胞外基质、细胞-细胞相互作用、微流体环境和肾小管结构是二维细胞培养中缺乏的因素。目前,有一些三维(3D)细胞培养平台可模拟PT细胞的体内条件,从而可能为功能完整的PT细胞提供必要因素。
在本综述中,我们阐述了PT细胞的体内生理和形态特征,比较了它们的可用来源和保留的体内特征。此外,还综述了二维和三维细胞培养平台以及细胞培养结构对细胞生理特征的影响。最后,描述了三维模型、肾脏和多器官芯片、肾脏类器官的生成、其他离体肾脏模型及其在研究药物处置和体外-体内外推方面的能力的未来前景。
