Quantifying Deformation and Migration Properties of U87 Glioma Cells Using Dielectrophoretic Forces.

in Biosensors by Meltem Elitas, Monsur Islam, Jan G Korvink, Esra Sengul, Pouya Sharbati, Beyzanur Ozogul, Sumeyra Vural Kaymaz

TLDR

  • The study investigates how the movement of U87 Glioma cells changes when exposed to dielectrophoretic forces. The authors found that the cells moved differently at different frequencies, and this movement could provide insights into the behavior of the cells. The study's approach could be used to monitor the effectiveness of treatments and personalize treatment plans.

Abstract

Glioblastoma multiforme is one of the most aggressive malignant primary brain tumors. To design effective treatment strategies, we need to better understand the behavior of glioma cells while maintaining their genetic and phenotypic stability. Here, we investigated the deformation and migration profile of U87 Glioma cells under the influence of dielectrophoretic forces. We fabricated a gold microelectrode array within a microfluidic channel and applied sinusoidal wave AC potential at 3 V, ranging from 30 kHz to 10 MHz frequencies, to generate DEP forces. We followed the dielectrophoretic movement and deformation changes of 100 glioma cells at each frequency. We observed that the mean dielectrophoretic displacements of glioma cells were significantly different at varying frequencies with the maximum and minimum traveling distances of 13.22 µm and 1.37 µm, respectively. The dielectrophoretic deformation indexes of U87 glioma cells altered between 0.027-0.040. It was 0.036 in the absence of dielectrophoretic forces. This approach presents a rapid, robust, and sensitive characterization method for quantifying membrane deformation of glioma cells to determine the state of the cells or efficacy of administrated drugs.

Overview

  • The study investigates the deformation and migration profile of U87 Glioma cells under the influence of dielectrophoretic forces. The authors fabricated a gold microelectrode array within a microfluidic channel and applied sinusoidal wave AC potential at 3 V, ranging from 30 kHz to 10 MHz frequencies, to generate DEP forces. They followed the dielectrophoretic movement and deformation changes of 100 glioma cells at each frequency. The primary objective of the study is to determine the state of the cells or efficacy of administrated drugs by quantifying membrane deformation of glioma cells. The hypothesis being tested is that the deformation and migration profile of glioma cells under the influence of dielectrophoretic forces can provide insights into the behavior of glioma cells and inform effective treatment strategies.

Comparative Analysis & Findings

  • The study found that the mean dielectrophoretic displacements of glioma cells were significantly different at varying frequencies with the maximum and minimum traveling distances of 13.22 µm and 1.37 µm, respectively. The dielectrophoretic deformation indexes of U87 glioma cells altered between 0.027-0.040. It was 0.036 in the absence of dielectrophoretic forces. These findings suggest that the deformation and migration profile of glioma cells under the influence of dielectrophoretic forces can provide insights into the behavior of glioma cells and inform effective treatment strategies.

Implications and Future Directions

  • The study's findings suggest that the deformation and migration profile of glioma cells under the influence of dielectrophoretic forces can provide insights into the behavior of glioma cells and inform effective treatment strategies. The study's approach presents a rapid, robust, and sensitive characterization method for quantifying membrane deformation of glioma cells. Future research could explore the use of dielectrophoretic forces to modulate the behavior of glioma cells and inform treatment strategies. Additionally, the study's approach could be used to monitor the efficacy of drugs in vivo and inform personalized treatment plans.
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