State Key Laboratory of Transducer Technology, Institute of Electronics, Chinese Academy of Sciences, Beijing, PR China.
Biosens Bioelectron. 2013 May 15;43:304-7. doi: 10.1016/j.bios.2012.12.035. Epub 2012 Dec 26.
This paper presents a microfluidic system enabling continuous characterization of specific membrane capacitance (Cspecific membrane) and cytoplasm conductivity (σcytoplasm) of single cells in suspension. In this study, cells were aspirated continuously through a constriction channel while cell elongations and impedance profiles at two frequencies (1kHz and 100kHz) were measured simultaneously using microscopy imaging and a lock-in amplifier. 1kHz impedance data were used to evaluate cellular sealing properties with constriction channel walls and 100kHz impedance data were translated to quantify equivalent membrane capacitance and cytoplasm resistance of single cells, which were further translated to Cspecific membrane and σcytoplasm. Two model cell lines (kidney tumor cell line of 786-O (n=302) and vascular smooth muscle cell line of T2 (n=216)) were used to evaluate this technique, producing Cspecific membrane of 3.67±1.00 and 4.53±1.51μF/cm(2) and σcytoplasm of 0.47±0.09 and 0.55±0.14S/m, respectively. Compared to previously reported techniques which can only collect Cspecific membrane and σcytoplasm from tens of cells, this new technique has a higher throughput, capable of collecting Cspecific membrane and σcytoplasm from hundreds of cells in 30min immediately after cell passage.
本文提出了一种微流控系统,能够连续表征悬浮单个细胞的特定膜电容(Cspecific membrane)和细胞质电导率(σcytoplasm)。在这项研究中,细胞被连续吸入收缩通道,同时使用显微镜成像和锁相放大器测量细胞的伸长和两个频率(1kHz 和 100kHz)的阻抗谱。1kHz 阻抗数据用于评估细胞与收缩通道壁的密封性能,100kHz 阻抗数据用于量化单个细胞的等效膜电容和细胞质电阻,进一步转化为 Cspecific membrane 和 σcytoplasm。使用两种模型细胞系(肾肿瘤细胞系 786-O(n=302)和血管平滑肌细胞系 T2(n=216))来评估该技术,得到 Cspecific membrane 分别为 3.67±1.00 和 4.53±1.51μF/cm(2),σcytoplasm 分别为 0.47±0.09 和 0.55±0.14S/m。与之前只能从数十个细胞中收集 Cspecific membrane 和 σcytoplasm 的技术相比,这种新技术具有更高的通量,能够在细胞传代后 30 分钟内从数百个细胞中收集 Cspecific membrane 和 σcytoplasm。
