Nano-Bio Energy Department, Chung-Ang University, Heukseok-dong, Dongjak-gu, Seoul 156-756, Republic of Korea.
Biosens Bioelectron. 2013 Dec 15;50:453-9. doi: 10.1016/j.bios.2013.07.019. Epub 2013 Jul 17.
In this study, we have provided a novel analytical integration between hydrogel-based cell chip and Electric Cell-substrate Impedance Sensing (ECIS) technique to apply to a high-throughput, real-time cell viability assay and drug screening. For simulating the drug diffusion model, we have developed a hydrogel-based tissue-mimicking structure with microfluidic channel, without unwanted flow, to generate a gradient concentration with long-term stability. Along the gradient line, four individual micro-electrodes were installed to record the impedance signal changes, which result from the cell viability under drug effects. By watching for cellular impedance changes, we successfully estimated the cytotoxicity of the treatment corresponding to the various concentration values of stimuli, generated by the diffusion process along the channel. Reliable IC50 values and time-dose relationships were also achieved. With the feature of real-time monitoring capability, the advantages of non-invasion, label-free detection, time saving and simple manipulation, our integrative device has become a promising high throughput cell-based on-chip platform for cell viability assay and drug screening.
在这项研究中,我们提供了一种新颖的基于水凝胶的细胞芯片与电动细胞-基质阻抗传感(ECIS)技术的分析集成,以应用于高通量、实时细胞活力分析和药物筛选。为了模拟药物扩散模型,我们开发了一种基于水凝胶的组织模拟结构,带有微流道,没有不必要的流动,以产生具有长期稳定性的浓度梯度。沿着梯度线,安装了四个独立的微电极来记录阻抗信号的变化,这些变化是由药物作用下细胞活力引起的。通过观察细胞阻抗的变化,我们成功地估计了与通道中扩散过程产生的各种刺激浓度相对应的处理的细胞毒性。还获得了可靠的 IC50 值和时-量关系。我们的集成设备具有实时监测功能、非侵入性、无标记检测、省时和操作简单的优点,已成为一种有前途的高通量基于细胞的片上平台,用于细胞活力分析和药物筛选。
