Development of neuroprotection approaches for long-term space missions

Pub Date : 2022-12-08 DOI:10.15407/knit2022.06.052
A. Pastukhov, N. Krisanova, O. Pylypchuk, N. Pozdnyakova, R. Sivko, A. Nazarova, L. M. Kalynovska, Т. Borisova
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Abstract

The study aimed to develop a strategy and methodology for neuroprotection during long-term space missions, which is based on a comprehensive study of the impact of therapeutic hypothermia combined with the action of neuroactive drugs on the key characteristics of synaptic transmission in brain nerve terminals, which change under the influence of planetary dust and conditions of altered gravity. Development of neurotoxicity under conditions of altered gravity may result from excess extracellular glutamate caused by the reverse functioning of glutamate transporters. Under conditions of moderate and deep hypothermia, a gradual decrease in the transporter-mediated release of L-[14C]glutamate from nerve terminals was demonstrated, which is stimulated by plasma membrane depolarization with KCl and dissipation of the proton gradient of synaptic vesicles by the protonophore FCCP. This fact indicates a neuroprotective effect, which increases when hypothermia changes from moderate to deep. The possible risks of using hypothermia in space medicine have been determined. Hypothermia is not able to reduce the extracellular level of L-[14C]glutamate and [3H]GABA, which increases under the conditions of exposure to carbon-containing planetary dust. Hypothermia can lead to a further decrease in the rate of accumulation of neurotransmitters in the presence of carbon-containing planetary dust and to contribute to the development of neurotoxicity, which is a possible risk of using hypothermia in space medicine. In this context, it is important to choose the optimal individual temperature regime for each astronaut.
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长期太空任务神经保护方法的发展
该研究旨在制定长期太空任务期间神经保护的战略和方法,其基础是对治疗性低温结合神经活性药物对脑神经末梢突触传递关键特征的影响的综合研究,这些特征在行星尘埃和重力变化条件的影响下发生变化。在重力改变的情况下,神经毒性的发展可能是由于谷氨酸转运体的反向功能导致的细胞外谷氨酸过量。在中度和深度低温条件下,转运体介导的神经末梢L-[14C]谷氨酸释放逐渐减少,这是由KCl的质膜去极化和质子团FCCP耗散突触囊泡的质子梯度刺激的。这一事实表明,当体温从中度降至深度时,神经保护作用会增强。在太空医学中使用低温疗法的可能风险已经确定。低温不能降低细胞外L-[14C]谷氨酸和[3H]GABA水平,而在暴露于含碳行星尘埃的条件下,细胞外L-[14C]谷氨酸和[3H]GABA水平会升高。在含碳行星尘埃存在的情况下,低温可导致神经递质积累速度进一步下降,并导致神经毒性的发展,这是在空间医学中使用低温的一个可能风险。在这种情况下,为每个宇航员选择最佳的个人温度制度是很重要的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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