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Lower Martian gravity would lead to weaker bones and muscles in children, making them too fragile for Earth's gravity. Furthermore, their immune systems would develop without Earth's microbial diversity, leaving them vulnerable to common microbes upon return, effectively making a trip to Earth a potential death sentence.
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The small, non-representative group of initial colonists will create a genetic bottleneck. Their specific genetic makeup will have an outsized influence on all subsequent generations born on Mars, leading to rapid evolutionary change and reduced overall genetic diversity compared to Earth's population.
Isolated on islands with limited resources, species undergo rapid size changes. While Homo floresiensis ('hobbits') and pygmy elephants shrank, other species like Komodo dragons and tortoises became giants. This evolutionary pressure applies to any isolated population, including future human colonists on Mars.
In microgravity, fluids shift to the head ('space face'). The body interprets this as excess fluid and responds by reducing blood plasma and red blood cell production. This adaptation means astronauts often return to Earth anemic, which has significant health implications for recovery.
Living in a sterile Martian habitat, colonists would only be exposed to a tiny fraction of Earth's microbes. Their immune systems would be unprepared for Earth's vast microbial diversity, making a return journey potentially fatal. This creates a permanent biological quarantine that would accelerate human speciation.
A human born and raised in Mars's one-third gravity would likely not develop the bone density and muscular strength required to withstand Earth's gravity. The physical stress would be painful and potentially debilitating, effectively trapping them on their home planet for life.
Despite decades of spaceflight, there is almost no research on conception, pregnancy, childbirth, and child development in a low-gravity environment. Our assumption that humans can successfully reproduce off-world is a massive, unverified leap of faith and the single biggest unknown for establishing a permanent settlement.
Since Mars cooled and had water before Earth, Avi Loeb argues life likely started there first. This primordial life could have been transported to Earth inside rocks ejected by asteroid impacts. This makes humans descendants of Martian microbes and Elon Musk's mission a 'return to our childhood home'.
Animal studies suggest that when a mother's protein intake is low, it sends an epigenetic signal to the baby to "keep your muscles small" in anticipation of a nutrient-scarce world. This programming can result in smaller muscle mass throughout the child's life.
Women raised in one-third gravity may have bones too brittle for natural childbirth, risking fatal pelvic fractures. If C-sections become the norm, the evolutionary pressure that limits a baby's head size to fit the birth canal is removed. This could lead to the rapid evolution of larger-headed humans.
On Earth, we have non-genetic ways to improve lives. For a child born on Mars who can't escape the high-radiation, low-gravity environment, genetic engineering might be the only way to alleviate suffering. This flips the ethical question to whether it's unethical *not* to intervene genetically.