Key Laboratory for Biomechanics and Mechanobiology of Ministry of Education, School of Biological Science and Medical Engineering, Beihang University, Beijing, 100083, China.
Beijing Advanced Innovation Centre for Biomedical Engineering, Beihang University, Beijing, 100083, China.
Neurotox Res. 2018 Aug;34(2):285-294. doi: 10.1007/s12640-018-9885-3. Epub 2018 Apr 7.
Nerve cells detect and respond to electric field stimulation and extrinsic chemical guidance cues during development and regeneration; therefore, the development and optimization of an approach for functional neuronal regeneration are necessary for a nerve injury. In this study, we proposed using electric field stimulation to repair a nerve injury triggered by serious mechanical stretch loading. A device that provides continuous mechanical stretch and constant electric field stimulation was designed. Primary dissociated spinal cord neurons were stimulated by mechanical stretch (tensile strain 2.5-10%) at different times (1, 4, 8, and 12 h) to set up a moderate nerve injury model. Stimulated samples were evaluated with respect to cell viability, density, and axonal elongation by the MTT and immunofluorescence assays. The results indicated that mechanical stretch (S, 5% tensile strain, 4 h) caused moderate axonal injury, resulting in significant loss of cell viability and a decrease in cell density. However, injured spinal cord neurons became viable after electric field stimulation (E, 33 mA/m, 4 h) in the fluorescein diacetate assay. In addition, neuronal viability, density, and elongation increased significantly after electric field stimulation compared with those of stretch-injured neurons. Moreover, electric field stimulation significantly activated the axonal guidance cues Netrin-1 and deleted in colorectal cancer (DCC) receptor expression compared with the stretch-injury group. These results indicate that electric stimulation activates synergistic guidance cues of expression to improve axonal growth relevant to nerve injuries. Our study provides new insight into neuronal regeneration.
神经细胞在发育和再生过程中检测和响应电场刺激和外源性化学导向线索;因此,为了实现神经损伤的修复,有必要开发和优化功能性神经元再生的方法。在这项研究中,我们提出利用电场刺激来修复严重机械拉伸加载引发的神经损伤。设计了一种提供连续机械拉伸和恒定电场刺激的装置。通过 MTT 和免疫荧光检测,对不同时间(1、4、8 和 12 小时)接受机械拉伸(拉伸应变 2.5-10%)刺激的原代分离脊髓神经元的细胞活力、密度和轴突伸长进行评估。结果表明,机械拉伸(S,5%拉伸应变,4 小时)导致中度轴突损伤,导致细胞活力显著丧失和细胞密度降低。然而,在荧光素二乙酸酯测定中,电场刺激(E,33 mA/m,4 小时)后受伤的脊髓神经元变得有活力。此外,与拉伸损伤神经元相比,电场刺激后神经元活力、密度和伸长显著增加。此外,与拉伸损伤组相比,电场刺激显著激活了轴突导向线索 Netrin-1 和结直肠癌缺失基因(DCC)受体的表达。这些结果表明,电刺激激活了协同表达的导向线索,以改善与神经损伤相关的轴突生长。我们的研究为神经元再生提供了新的见解。
