Articles
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Cellular & Tissue Engineering
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Chromosomal positioning and epigenetic architecture influence DNA methylation patterns triggered by galactic cosmic radiation
Chromosomal positioning and epigenetic architecture influence DNA methylation patterns triggered by galactic cosmic radiation
Cellular & Tissue Engineering
Abstractive Summary
Study examining chromosomal positioning and epigenetic architecture influence dna methylation. Exposure to cosmic radiation causes substantial DNA damage and oxidative stress, with repair mechanisms partially effective. Cell cycle checkpoints and apoptosis are activated, but long-term cancer risk remains elevated at 3-5% for Mars missions. Effective radiation countermeasures are critical for deep space exploration.
Extractive Summary
Study examining chromosomal positioning and epigenetic architecture influence dna methylation. Cosmic radiation exposure caused significant DNA damage with increased double-strand breaks. Cellular repair mechanisms were partially effective but overwhelmed at higher doses. Oxidative stress markers were elevated substantially. Cell cycle checkpoints showed prolonged activation. Apoptosis rates increased dose-dependently. Long-term cancer risk estimates ranged from 3-5% for Mars missions.
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Keywords
chromosomal, positioning, epigenetic, architecture, influence, methylation, patterns, triggered, galactic, cosmic, increased, study, examining, chromosomal, positioning, epigenetic, architecture, influence, methylation, cosmic, radiation, effective, study, examining, chromosomal, positioning, epigenetic, architecture, influence, methylation
Abstractive Keywords
radiation, effective, study, examining, chromosomal, positioning, epigenetic, architecture, influence, methylation
Extractive Keywords
increased, study, examining, chromosomal, positioning, epigenetic, architecture, influence, methylation, cosmic
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