Electric Field Modulation of Cells: From Signaling Pathway to Physiological Behaviors
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Description
The response of living cells to electric field (EF) has been observed for more than a hundred years, but the mechanism of how cells interact with EF is not entirely ascertained. Although many efforts have been devoted to the application of EF stimulation in tissue engineering and regeneration, the fundamental scientific principle of such practice remains unveiled and keeps drawing attention during the pursuit of consistent outcomes. In this regard, my research focuses on the underlying mechanism by which EF stimulation evokes cellular responses and the EF modulation of cell signaling pathways to physiological behaviors. The first part of my research focuses on developing the platform for controlled EF stimulation and real-time imaging/analysis. High-k dielectric passivated microelectrodes are fabricated to send capacitively coupled alternating current electric field (AC EF) stimulation to cells. I have developed two generations of EF stimulation devices with environmental control chambers: the first one is used to study cell signaling pathway dynamics; the second one is upgraded with long-term culture capability to study cell physiological behaviors. The second part of my research focuses on the quantification and mechanistic study of AC EF perturbation of the extracellular signal-related kinase (ERK) signaling pathway. I demonstrate that AC EF stimulation can induce both inhibition and activation of the ERK pathway, with different AC EF amplitude thresholds and time and magnitude scales. The mechanistic study shows that the ERK activation is initiated by AC EF-induced epidermal growth factor receptor (EGFR) phosphorylation, and the ERK inhibition is related to AC EF-induced change of Ras activities. In addition, these ERK responses show high sensitivity to AC EF waveform and timing, indicating electrostatic coupling mechanism and providing new parameter spaces for further investigation on the modulation of the ERK signaling pathway via AC EF stimulation. The last part of my research steers to cell physiological behaviors under prolonged AC EF stimulation. I report that AC EF stimulation can clearly inhibit cell proliferation and migration, and the inhibition in cell proliferation is sensitive to AC EF amplitude, stimulation pattern, and pulse rising time. These findings can benefit the AC EF application in medical treatment.