基于微孔的单细胞捕获和磁场梯度刺激微流控装置

Richard Lee Lai
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引用次数: 0

摘要

我们开发了一个微流控平台,用于在不同生理条件下长期培养和观察两种THP-1细胞。首先,我们确定最佳播种条件和微井几何形状。接下来,我们观察细胞大小和圆度的变化。结果表明,102 T/m量级的梯度磁力导致细胞生长发育迟缓,细胞形状不规则。最后,我们观察了在可控磁场、静态磁场和梯度磁场下ROS信号的时间变化。对于静态和梯度磁场,ROS信号的峰值分别出现在24小时和36小时。
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A Microwell-Based Microfluidic Device for Single-Cell Trapping and Magnetic Field Gradient Stimulation
We develop a microfluidic platform for the long-term cultivation and observation of both THP-1 cells under different physiological conditions. First, we determine optimal seeding conditions and microwell geometry. Next, we observe changes in cell size and circularity. Results show that gradient magnetic forces on the order of 102 T/m results in stunted growth and irregular cell shapes. Finally, we observe the temporal change in ROS signals under control, static and gradient magnetic fields. For exposure to static and gradient magnetic fields, the peak in ROS signals occurs after 24 hours and 36 hours, respectively.
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