Esch Mandy B, Mahler Gretchen J, Stokol Tracy, Shuler Michael L
Department of Biomedical Engineering, 305 Weill Hall, Cornell University, Ithaca, NY 14853, USA.
Lab Chip. 2014 Aug 21;14(16):3081-92. doi: 10.1039/c4lc00371c.
The use of nanoparticles in medical applications is highly anticipated, and at the same time little is known about how these nanoparticles affect human tissues. Here we have simulated the oral uptake of 50 nm carboxylated polystyrene nanoparticles with a microscale body-on-a-chip system (also referred to as multi-tissue microphysiological system or micro Cell Culture Analog). Using the 'GI tract-liver-other tissues' system allowed us to observe compounding effects and detect liver tissue injury at lower nanoparticle concentrations than was expected from experiments with single tissues. To construct this system, we combined in vitro models of the human intestinal epithelium, represented by a co-culture of enterocytes (Caco-2) and mucin-producing cells (TH29-MTX), and the liver, represented by HepG2/C3A cells, within one microfluidic device. The device also contained chambers that together represented the liquid portions of all other organs of the human body. Measuring the transport of 50 nm carboxylated polystyrene nanoparticles across the Caco-2/HT29-MTX co-culture, we found that this multi-cell layer presents an effective barrier to 90.5 ± 2.9% of the nanoparticles. Further, our simulation suggests that a larger fraction of the 9.5 ± 2.9% nanoparticles that travelled across the Caco-2/HT29-MTX cell layer were not large nanoparticle aggregates, but primarily single nanoparticles and small aggregates. After crossing the GI tract epithelium, nanoparticles that were administered in high doses estimated in terms of possible daily human consumption (240 and 480 × 10(11) nanoparticles mL(-1)) induced the release of aspartate aminotransferase (AST), an intracellular enzyme of the liver that indicates liver cell injury. Our results indicate that body-on-a-chip devices are highly relevant in vitro models for evaluating nanoparticle interactions with human tissues.
纳米颗粒在医学应用中的使用备受期待,与此同时,人们对这些纳米颗粒如何影响人体组织却知之甚少。在此,我们使用微尺度芯片上人体系统(也称为多组织微生理系统或微细胞培养模拟物)模拟了50纳米羧化聚苯乙烯纳米颗粒的口服摄取过程。使用“胃肠道-肝脏-其他组织”系统使我们能够观察复合效应,并在比单组织实验预期更低的纳米颗粒浓度下检测到肝脏组织损伤。为构建该系统,我们在一个微流控装置中组合了以肠上皮细胞(Caco-2)和产粘蛋白细胞(TH29-MTX)的共培养物为代表的人肠上皮体外模型以及以HepG2/C3A细胞为代表的肝脏模型。该装置还包含一些腔室,这些腔室共同代表了人体所有其他器官的液体部分。通过测量50纳米羧化聚苯乙烯纳米颗粒穿过Caco-2/HT29-MTX共培养物的转运情况,我们发现这个多细胞层对90.5±2.9%的纳米颗粒构成了有效屏障。此外,我们的模拟表明,穿过Caco-2/HT29-MTX细胞层的9.5±2.9%的纳米颗粒中,较大一部分不是大的纳米颗粒聚集体,而是主要为单个纳米颗粒和小聚集体。在穿过胃肠道上皮后,按照可能的每日人体摄入量估算(240和480×10¹¹纳米颗粒·mL⁻¹)给予高剂量的纳米颗粒会诱导天冬氨酸转氨酶(AST)的释放,AST是一种肝脏细胞内酶,表明肝细胞受到损伤。我们的结果表明,芯片上人体装置是评估纳米颗粒与人体组织相互作用的高度相关的体外模型。
