Department of Electrical, Computer and Energy, University of Colorado Boulder, Boulder, Colorado.
Department of Physics, University of Wisconsin-Parkside, Kenosha, Wisconsin.
Bioelectromagnetics. 2021 Apr;42(3):212-223. doi: 10.1002/bem.22332. Epub 2021 Mar 18.
In this study, we investigated the effects of weak static magnetic fields (SMFs) on HT-1080 human fibrosarcoma cells. Exposures to SMFs for four consecutive days were varied from 0.5 to 600 µT for treated units, while exposures to control units were held at 45 µT. Growth rates were measured by comparing cell counts, whereas membrane potentials, mitochondrial calcium, mitochondrial superoxide (O ), nitric oxide (NO), hydrogen peroxide (H O ), intercellular pH, and oxidative stress were measured by using fluorescent dyes. The relative cell growth rates vary with the angle of the SMFs. Increases in the magnitude of the SMFs increased concentrations of mitochondrial calcium and membrane potential and decreased intracellular pH. H O , an important reactive oxygen species (ROS), increases at 100 and 200 µT, decreases at 300 and 400 µT and increases again at 500 and 600 µT. Overall, oxidative stress increases slightly with increasing SMFs, while superoxide and NO concentrations decrease. These results indicate that weak SMFs can accelerate and inhibit cell growth rates and induce alterations in ROS. Changes in ROS and oxidative stress are important for various cell functions. Calcium influx into mitochondria was one of the initial steps into the corresponding changes. Bioelectromagnetics. 2021. © 2021 Bioelectromagnetics Society.
在这项研究中,我们研究了弱静磁场(SMFs)对 HT-1080 人纤维肉瘤细胞的影响。连续四天暴露于 SMFs 的处理组磁场强度从 0.5 到 600 μT 不等,而对照组的暴露磁场强度保持在 45 μT。通过比较细胞计数来测量生长速率,而通过荧光染料测量膜电位、线粒体钙、线粒体超氧化物(O )、一氧化氮(NO)、过氧化氢(H O )、细胞间 pH 和氧化应激。相对细胞生长速率随 SMFs 的角度而变化。随着 SMFs 强度的增加,线粒体钙和膜电位的浓度增加,细胞内 pH 值降低。H O ,一种重要的活性氧(ROS),在 100 和 200 μT 时增加,在 300 和 400 μT 时减少,在 500 和 600 μT 时再次增加。总的来说,随着 SMFs 的增加,氧化应激略有增加,而超氧化物和 NO 浓度降低。这些结果表明,弱 SMFs 可以加速和抑制细胞生长速率,并诱导 ROS 的变化。ROS 和氧化应激的变化对各种细胞功能很重要。线粒体钙内流是相应变化的初始步骤之一。生物电磁学。2021. © 2021 生物电磁学学会。
