Near-Infrared Photobiomodulation of Living Cells, Tubulin, and Microtubules In Vitro

IF 2.7 Q3 ENGINEERING, BIOMEDICAL Frontiers in medical technology Pub Date : 2022-05-04 DOI:10.3389/fmedt.2022.871196
M. Staelens, E. Di Gregorio, A. Kalra, H. T. Le, N. Hosseinkhah, M. Karimpoor, L. Lim, J. Tuszynski
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引用次数: 8

Abstract

We report the results of experimental investigations involving photobiomodulation (PBM) of living cells, tubulin, and microtubules in buffer solutions exposed to near-infrared (NIR) light emitted from an 810 nm LED with a power density of 25 mW/cm2 pulsed at a frequency of 10 Hz. In the first group of experiments, we measured changes in the alternating current (AC) ionic conductivity in the 50–100 kHz range of HeLa and U251 cancer cell lines as living cells exposed to PBM for 60 min, and an increased resistance compared to the control cells was observed. In the second group of experiments, we investigated the stability and polymerization of microtubules under exposure to PBM. The protein buffer solution used was a mixture of Britton-Robinson buffer (BRB aka PEM) and microtubule cushion buffer. Exposure of Taxol-stabilized microtubules (~2 μM tubulin) to the LED for 120 min resulted in gradual disassembly of microtubules observed in fluorescence microscopy images. These results were compared to controls where microtubules remained stable. In the third group of experiments, we performed turbidity measurements throughout the tubulin polymerization process to quantify the rate and amount of polymerization for PBM-exposed tubulin vs. unexposed tubulin samples, using tubulin resuspended to final concentrations of ~ 22.7 μM and ~ 45.5 μM in the same buffer solution as before. Compared to the unexposed control samples, absorbance measurement results demonstrated a slower rate and reduced overall amount of polymerization in the less concentrated tubulin samples exposed to PBM for 30 min with the parameters mentioned above. Paradoxically, the opposite effect was observed in the 45.5 μM tubulin samples, demonstrating a remarkable increase in the polymerization rates and total polymer mass achieved after exposure to PBM. These results on the effects of PBM on living cells, tubulin, and microtubules are novel, further validating the modulating effects of PBM and contributing to designing more effective PBM parameters. Finally, potential consequences for the use of PBM in the context of neurodegenerative diseases are discussed.
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活细胞、微管蛋白和微管的近红外光生物调节
我们报告了一项实验研究的结果,该实验涉及到缓冲溶液中活细胞、微管蛋白和微管的光生物调节(PBM),该缓冲溶液暴露于810 nm LED发出的近红外(NIR)光下,其功率密度为25 mW/cm2,脉冲频率为10 Hz。在第一组实验中,我们测量了HeLa和U251癌细胞在50-100 kHz范围内的交流电(AC)离子电导率的变化,这些活细胞暴露在PBM中60分钟,与对照细胞相比,观察到它们的电阻增加。在第二组实验中,我们研究了暴露于PBM下微管的稳定性和聚合。所使用的蛋白质缓冲溶液是布里顿-罗宾逊缓冲液(BRB又名PEM)和微管缓冲液的混合物。紫杉醇稳定的微管(~2 μM微管)在LED下暴露120分钟,荧光显微镜图像显示微管逐渐解体。这些结果与微管保持稳定的对照组进行了比较。在第三组实验中,我们在整个微管蛋白聚合过程中进行了浊度测量,以量化pbm暴露的微管蛋白与未暴露的微管蛋白样品的聚合速率和聚合量,在相同的缓冲溶液中,将微管蛋白重悬至最终浓度为~ 22.7 μM和~ 45.5 μM。与未暴露的对照样品相比,吸光度测量结果表明,浓度较低的微管蛋白样品在PBM中暴露30分钟后,聚合速度较慢,聚合总量减少。相反,在45.5 μM微管蛋白样品中观察到相反的效果,表明暴露于PBM后聚合速率和聚合物总质量显著增加。这些关于PBM对活细胞、微管蛋白和微管影响的结果是新颖的,进一步验证了PBM的调节作用,并有助于设计更有效的PBM参数。最后,讨论了在神经退行性疾病中使用PBM的潜在后果。
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来源期刊
CiteScore
3.70
自引率
0.00%
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0
审稿时长
13 weeks
期刊最新文献
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