Articles

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Radiation Biology & DNA Damage

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Spatially resolved multiomics on the neuronal effects induced by spaceflight in mice

Radiation Biology & DNA Damage

Abstractive Summary

Study examining spatially resolved multiomics on the neuronal effects induced. Spaceflight affects neurological function through multiple mechanisms, including cognitive decline, brain structure changes, and increased intracranial pressure. Vestibular adaptation and motor control are temporarily impaired. These findings are critical for understanding astronaut performance and long-term neurological health.

Extractive Summary

Study examining spatially resolved multiomics on the neuronal effects induced. Neurological function showed multiple alterations during spaceflight. Cognitive performance declined in attention and spatial processing tasks. Brain structure changes included gray matter volume shifts. Intracranial pressure increased with optic nerve changes. Vestibular system adaptation required 3-7 days. Motor control and coordination were temporarily impaired. Neurotransmitter levels fluctuated significantly.

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Keywords

spatially, resolved, multiomics, neuronal, effects, induced, spaceflight, mice, changes, study, examining, spatially, resolved, multiomics, neuronal, effects, induced, neurological, neurological, study, examining, spatially, resolved, multiomics, neuronal, effects, induced, spaceflight

Abstractive Keywords

neurological, study, examining, spatially, resolved, multiomics, neuronal, effects, induced, spaceflight

Extractive Keywords

changes, study, examining, spatially, resolved, multiomics, neuronal, effects, induced, neurological

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