Striebel Johannes, Kalinski Laura, Sturm Maximilian, Drouvé Nils, Peters Stefan, Lichterfeld Yannick, Habibey Rouhollah, Hauslage Jens, El Sheikh Sherif, Busskamp Volker, Liemersdorf Christian
Department of Ophthalmology, Medical Faculty, University of Bonn, Bonn, Germany.
Department of Gravitational Biology, Institute of Aerospace Medicine, German Aerospace Center, Cologne, Germany.
Front Neurosci. 2023 Mar 8;17:1085282. doi: 10.3389/fnins.2023.1085282. eCollection 2023.
During spaceflight, humans experience a variety of physiological changes due to deviations from familiar earth conditions. Specifically, the lack of gravity is responsible for many effects observed in returning astronauts. These impairments can include structural as well as functional changes of the brain and a decline in cognitive performance. However, the underlying physiological mechanisms remain elusive. Alterations in neuronal activity play a central role in mental disorders and altered neuronal transmission may also lead to diminished human performance in space. Thus, understanding the influence of altered gravity at the cellular and network level is of high importance. Previous electrophysiological experiments using patch clamp techniques and calcium indicators have shown that neuronal activity is influenced by altered gravity. By using multi-electrode array (MEA) technology, we advanced the electrophysiological investigation covering single-cell to network level responses during exposure to decreased (micro-) or increased (hyper-) gravity conditions. We continuously recorded in real-time the spontaneous activity of human induced pluripotent stem cell (hiPSC)-derived neural networks . The MEA device was integrated into a custom-built environmental chamber to expose the system with neuronal cultures to up to 6 g of hypergravity on the Short-Arm Human Centrifuge at the DLR Cologne, Germany. The flexibility of the experimental hardware set-up facilitated additional MEA electrophysiology experiments under 4.7 s of high-quality microgravity (10 to 10 g) in the Bremen drop tower, Germany. Hypergravity led to significant changes in activity. During the microgravity phase, the mean action potential frequency across the neural networks was significantly enhanced, whereas different subgroups of neurons showed distinct behaviors, such as increased or decreased firing activity. Our data clearly demonstrate that gravity as an environmental stimulus triggers changes in neuronal activity. Neuronal networks especially reacted to acute changes in mechanical loading (hypergravity) or de-loading (microgravity). The current study clearly shows the gravity-dependent response of neuronal networks endorsing the importance of further investigations of neuronal activity and its adaptive responses to micro- and hypergravity. Our approach provided the basis for the identification of responsible mechanisms and the development of countermeasures with potential implications on manned space missions.
在太空飞行期间,由于与熟悉的地球条件存在偏差,人类会经历各种生理变化。具体而言,失重是返回地球的宇航员身上观察到的许多影响的原因。这些损伤可能包括大脑的结构和功能变化以及认知能力的下降。然而,潜在的生理机制仍然难以捉摸。神经元活动的改变在精神障碍中起核心作用,而神经元传递的改变也可能导致人类在太空中的表现下降。因此,了解重力改变在细胞和网络水平上的影响至关重要。以前使用膜片钳技术和钙指示剂的电生理实验表明,神经元活动受重力改变的影响。通过使用多电极阵列(MEA)技术,我们推进了电生理研究,涵盖了在暴露于降低(微)或增加(超)重力条件下从单细胞到网络水平的反应。我们实时连续记录了人类诱导多能干细胞(hiPSC)衍生神经网络的自发活动。MEA设备被集成到一个定制的环境舱中,以便在德国科隆DLR的短臂人体离心机上使神经元培养系统暴露于高达6g的超重力环境。实验硬件设置的灵活性有助于在德国不来梅落塔中4.7秒的高质量微重力(10至10g)下进行额外的MEA电生理实验。超重力导致活动发生显著变化。在微重力阶段,神经网络的平均动作电位频率显著增强,而不同的神经元亚组表现出不同的行为,例如放电活动增加或减少。我们的数据清楚地表明,重力作为一种环境刺激会触发神经元活动的变化。神经元网络尤其对机械负荷(超重力)或卸载(微重力)的急性变化做出反应。当前的研究清楚地表明了神经元网络对重力的依赖性反应,支持了对神经元活动及其对微重力和超重力的适应性反应进行进一步研究的重要性。我们的方法为确定相关机制以及开发对载人航天任务可能有潜在影响的对策提供了基础。
