Abstract
Microgravity is the key environment of weightlessness experienced by all astronauts during spaceflights that cause severe physiological alterations in the human body. The effect of microgravity on the nervous system has not been elucidated. In this study, hindlimb unloading rats were used as the simulated microgravity model, and self-designed novel microelectrode arrays were used as the essential tools. The special arrangement of detection sites and platinum nanoparticles modification made the electrodes have excellent performance at the neuron level. By comparing the changes of the neuroelectrophysiological signals in the CA1 regions of rats in different periods of long-term and short-term modeling, the following results were obtained. In the long-term model, the firing rates reached a peak after about seven days of modeling, and then kept decreasing till 28 days. The average firing rates and individual single cell firing rates of the acute model rose immediately after modeling. Analysis of power spectral density signals showed that the signals shifted to the low frequency band after both long-term and acute modeling. The neurons in the CA1 were classified into pyramidal cells and interneurons. The continuous observation of neurons under the acute modeling showed that the firing rates and amplitude of pyramidal cells have a greater increase than interneurons. The self-designed novel implantable microelectrode arrays provide an advanced tool for the detection of neurons in hindlimb unloading rats. The hippocampal nerve cells were impaired after modulation, and that pyramidal cells were more susceptible than interneurons.
Highlights
Gravity has modeled the evolution of life on earth, and provides the frame of reference for the body orientation and the integration of accelerations in the various planes of space[1]
The Microelectrode arrays (MEAs) were implanted into the CA1 region of the hippocampus as planned
The average firing rates of the five groups rats confirmed that the activity of neurons discharge reached a peak seven days after hindlimb unloading (HU) was made, and prolonged
Summary
Gravity has modeled the evolution of life on earth, and provides the frame of reference for the body orientation and the integration of accelerations in the various planes of space[1]. More than 40 years of space practice have confirmed that space flight can cause cephalad shifting of bodily fluids which ends up with various physiological and pathological changes such as cardiovascular dysfunction, bone loss, muscle atrophy, decreased immune function, endocrine dysfunction, and space movement disease[2], [3]. The clinical findings of affected astronauts are reminiscent of terrestrial pathologies such as idiopathic intracranial hypertension that are characterized by high intracranial pressure[4]. The study of the impact of the microgravity environment on brain neurons is an important prerequisite for ensuring the mental health of astronauts and the safe and efficient completion of missions. Studies in many aerospace laboratories have proved that the development of the animal nervous system has been severely affected by the weightless environment. The 16-day Neurolab Spacelab Mission STS-90, in 1998 was dedicated to studying how the nervous system develops and functions
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