NASA's Space Biology Program
GPTKB entity
Statements (70)
| Predicate | Object |
|---|---|
| gptkbp:instance_of |
gptkb:software
|
| gptkbp:bfsLayer |
5
|
| gptkbp:bfsParent |
gptkb:Microgravity_Bioreactor_Experiment
gptkb:Destiny_Laboratory_Module |
| gptkbp:addresses |
biological challenges of long-duration spaceflight
|
| gptkbp:aims_to |
understand the effects of microgravity on living organisms
|
| gptkbp:analyzes |
plant growth in space
the interaction between plants and microbes in space the impact of space radiation on biological systems the effects of microgravity on cardiovascular health the potential for using microorganisms in space missions the impact of isolation on astronaut health the impact of microgravity on cellular signaling. the impact of microgravity on metabolic processes the impact of microgravity on muscle atrophy the impact of spaceflight on immune function the potential for using fungi in space missions the role of gravity in cellular processes the role of nutrition in space health the effects of space conditions on protein expression the genetic changes in organisms exposed to space conditions |
| gptkbp:collaborates_with |
international space agencies
various research institutions private sector companies universities and research centers |
| gptkbp:conducts |
experiments on the International Space Station
research on the effects of spaceflight on reproductive health research on the effects of spaceflight on bone density research on the effects of spaceflight on circadian rhythms research on animal models in space research on the microbiome in space studies on microbial resistance in space research on the psychological effects of space travel |
| gptkbp:contributed_to |
NASA's long-term space exploration goals
the understanding of astrobiology |
| gptkbp:develops |
biotechnology applications for space exploration
countermeasures for space-related health issues strategies for biological experiments in space |
| gptkbp:engages_in |
in public outreach and education
|
| gptkbp:enhances |
understanding of human adaptation to space environments
|
| gptkbp:explores |
the effects of microgravity on reproduction
the potential for biopharmaceuticals in space the potential for life support systems in space the potential for using algae in space missions the effects of space conditions on microbial diversity the potential for using plants in life support systems the potential for bioregenerative life support systems |
| gptkbp:focuses_on |
biological research in space
|
| https://www.w3.org/2000/01/rdf-schema#label |
NASA's Space Biology Program
|
| gptkbp:is_involved_in |
the study of extremophiles in space
|
| gptkbp:is_part_of |
NASA's broader research initiatives
|
| gptkbp:provides |
data for future Mars missions
insight into the evolution of life in space |
| gptkbp:publishes |
scientific findings in peer-reviewed journals
|
| gptkbp:receives_funding_from |
gptkb:NASA
research grants for space biology studies |
| gptkbp:research |
microbial behavior in microgravity
the effects of space radiation on DNA the effects of spaceflight on gene expression the effects of spaceflight on human physiology the effects of spaceflight on plant physiology the role of symbiosis in space environments |
| gptkbp:supports |
the development of space habitats
human health in space missions the health and safety of astronauts during missions the development of space agriculture the health and performance of astronauts the development of technologies for space agriculture the development of countermeasures for radiation exposure |
| gptkbp:utilizes |
advanced imaging technologies
|