Rather than just leaving \u201cflags and footprints\u201d as the Apollo missions did, Nasa wants to establish a sustained human presence on the Moon, beginning at the lunar South Pole.<\/p>\n
The programme unfolds in stages. In 2022, the Artemis I mission successfully tested the Space Launch System (SLS) rocket and Orion spacecraft as an integrated system on an uncrewed mission around the Moon. <\/p>\n
On April 1, 2026, Nasa launched Artemis II<\/a> a ten-day mission, carrying four astronauts around the Moon.<\/p>\n The four Artemis II astronauts arrived at Kennedy Space Center in Florida on March 27, 2026 to begin final preparations for launch. As Nasa\u2019s first crewed flight of Orion and SLS, Artemis II is a pivotal mission designed to verify that life-support systems, navigation, thermal protection and deep-space operations all function safely with humans onboard. <\/p>\n Before astronauts can live on the Moon, the journey there must be proven reliable.<\/p>\n Beyond these early missions, Nasa\u2019s long-term vision<\/a> extends far beyond a single landing. Nasa plans to spend<\/a> US$20 billion (\u00a315 billion) on a lunar surface base, intended to support repeated and progressively longer surface stays. This is designed to teach us how to operate sustainably beyond Earth \u2013 knowledge that will ultimately feed forward to future human missions to Mars, the horizon goal.<\/p>\n Health challenges<\/p>\n Living on the Moon will challenge every organ system in the human body. The lunar environment exposes astronauts to a unique space exposome<\/a> \u2013 the combined set of Regular exercise will be critical for staying healthy on the Moon. Here, Japanese astronaut Satoshi Furukawa works out on the International Space Station. These include reduced gravity (about one-sixth of Earth\u2019s), chronic exposure to cosmic radiation, extreme temperature swings, toxic lunar dust, isolation, disrupted sleep-wake cycles, and prolonged confinement.<\/p>\n Unlike astronauts in low-Earth orbit, lunar crews operate largely outside Earth\u2019s protective magnetic field<\/a>. This increases exposure to space radiation<\/a>, which can damage DNA, disrupt immune function and affect the brain and cardiovascular system in subtle but potentially serious ways.<\/p>\n Reduced gravity also fundamentally alters how blood, oxygen and fluids move around the body. Microgravity can disrupt how blood, oxygen and glucose are delivered to the brain, potentially increasing vulnerability to neurological and vascular dysfunction over time.<\/p>\n This figure was modified with permission. To properly understand these risks, we need to look beyond individual organs and instead consider the space integrome<\/a> \u2013 the way that the brain, heart, blood vessels, muscles, bones, immune system and metabolism interact as an integrated whole under space conditions. A small disturbance in one system sends ripples through others.<\/p>\n One of the most challenging aspects is that many space-related physiological changes develop insiduously. Astronauts may feel well while complications simmer beneath the surface, only becoming apparent months or even years later. <\/p>\n That is why Nasa places such emphasis on long-term physiological monitoring and human risk mitigation in its Artemis science strategy.<\/p>\n Read more: Reducing the risk<\/p>\n The encouraging news is that humans are remarkably adaptable. The challenge is guiding that adaptation in safe and sustainable ways. Space countermeasures<\/a> are the tools used to reduce risk and preserve astronaut health. <\/p>\n Exercise remains the cornerstone. On the International Space Station, astronauts spend around two hours per day<\/a> exercising to protect muscle mass, bone density and cardiovascular function. On the Moon, however, exercise systems must be redesigned for partial gravity, where familiar Earth-based loading no longer applies.<\/p>\n Lunar regolith (soil) could be used to create structures that protect habitats from radiation and micrometeoroids. Nutrition<\/a> is another powerful countermeasure. Diet influences bone health, muscle maintenance, immune resilience and even how the body responds to radiation. <\/p>\n Personalised nutrition strategies, tailored to individual physiology rather than a \u201cone-size-fits-all\u201d menu, are likely to become increasingly important during long lunar missions.<\/p>\n Artificial gravity<\/a> is also being explored. Short-radius centrifuges could expose astronauts to brief periods of increased gravitational loading, potentially helping stabilise cardiovascular and neurovascular systems. While still experimental, this approach may prove valuable for future surface missions.<\/p>\n Vegetables grown in a lunar base greenhouse could enhance astronaut nutrition. Radiation protection<\/a> will rely on multiple layers of defence: habitat shielding \u2013 potentially using structures made of lunar soil \u2013 early warning systems for solar storms, and operational strategies that limit exposure during high-risk periods.<\/p>\n Crucially, countermeasures should be proactive rather than reactive. Continuous physiological monitoring, wearable sensors and advanced data analytics may allow mission teams to detect early warning signs and intervene before small problems become mission-limiting ones.<\/p>\n Spending extended time on the Moon will be awe-inspiring. Imagine watching Earth hang motionless above a stark, silent horizon, or working under a sky that never turns blue. <\/p>\n A lunar base would teach humans how to operate sustainably beyond Earth.![\"\"](\"https:\/\/www.newsbeep.com\/il\/wp-content\/uploads\/2026\/04\/file-20260330-57-8iciqn.jpg\")
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\n NASA\/Jim Ross<\/a><\/p>\n
\nphysical, chemical, biological and psychological stressors encountered beyond Earth. <\/p>\n![\"Japanese](\"https:\/\/www.newsbeep.com\/il\/wp-content\/uploads\/2026\/04\/file-20260330-68-7waugb.jpg\")
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\n Nasa<\/a><\/p>\n![\"\"](\"https:\/\/www.newsbeep.com\/il\/wp-content\/uploads\/2026\/04\/file-20260114-56-2sfl7t.jpg\")
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\n The physiology of survival: Space.<\/a><\/p>\n
\n Nasa plans to have a permanent base on the Moon by 2030 \u2013 how it can be done<\/a><\/p>\n![\"\"](\"https:\/\/www.newsbeep.com\/il\/wp-content\/uploads\/2026\/04\/file-20260330-57-v7ymds.jpg\")
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\n Foster + Partners<\/a><\/p>\n![\"\"](\"https:\/\/www.newsbeep.com\/il\/wp-content\/uploads\/2026\/04\/file-20260330-57-vdc8wg.jpg\")
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\n Nasa<\/a><\/p>\n![\"Lunar](\"https:\/\/www.newsbeep.com\/il\/wp-content\/uploads\/2026\/04\/file-20260330-57-662oyx.jpg\")
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\n RegoLight, visualisation: Liquifer Systems Group, 2018<\/a><\/p>\n