Something Is Malfunctioning With Astronauts’ Brains

New research reveals astronauts experience slowed cognitive processing during space missions, though their accuracy remains intact and these effects appear to be temporary once they return to Earth.

The human brain is remarkably adaptable, even when floating 250 miles above Earth in microgravity.

But exactly how space changes our cognitive abilities has remained a crucial question as we push toward longer missions and more distant destinations like Mars.

Now, groundbreaking research from NASA’s Behavioral Health and Performance Laboratory provides some answers—and a mix of reassurance and caution for future space explorers.

Temporary Slowdown, Not Permanent Damage

In a comprehensive study published in the journal Frontiers, researchers led by Sheena Dev tested 25 professional astronauts before, during, and after their six-month stays aboard the International Space Station (ISS).

The results challenge previous concerns about permanent cognitive impairment from extended space missions.

“We show that there is no evidence of any significant cognitive impairment or neurodegenerative decline in astronauts spending six months on the ISS,” explained Dev in a statement accompanying the research. “Living and working in space was not associated with widespread cognitive impairment that would be suggestive of significant brain damage.”

This finding represents a significant relief for space agencies and astronauts alike.

However, the study did identify notable changes while astronauts were in orbit.

Four Key Cognitive Domains Affected

The researchers found that certain cognitive abilities consistently slowed down during space missions, with four domains particularly vulnerable:

1. Processing speed – How quickly astronauts could complete cognitive tasks
2. Visual working memory – The ability to temporarily hold and manipulate visual information
3. Sustained attention – Maintaining focus on a task for extended periods
4. Risk-taking propensity – Decision-making patterns in uncertain situations

“These may be the cognitive domains most susceptible to change in Low Earth Orbit for high-performing, professional astronauts,” the researchers noted in their paper.

Interestingly, while astronauts’ cognitive processing was slower, their accuracy remained unaffected. They could still perform complex tasks correctly—it just took them longer to do so.

Timing of Cognitive Changes

One of the study’s most fascinating findings was that different cognitive functions showed changes at different points in the mission.

“Slowed performance on attention, for example, was only observed early during the mission while slowed performance on processing speed did not return to baseline levels until after the mission ended and crew were back on Earth,” Dev explained.

This suggests the brain adapts to some aspects of the space environment over time, while other effects persist throughout the mission and briefly afterward.

The temporary nature of these changes parallels what happens during significant stress on Earth—your brain prioritizes accuracy over speed when faced with challenging circumstances.

Space Stress vs. Earth Stress

The researchers noted striking similarities between cognitive changes in space and those experienced during stressful situations on Earth.

“The most vulnerable domains while astronauts are aboard the ISS are the same as those that are more susceptible to stressors on Earth,” said Dev.

Anyone who’s pulled an all-nighter or worked under extreme pressure might recognize this pattern. When you’re exhausted or stressed, tasks require more concentration and time, though you can still complete them correctly with effort.

“If you happen to have a really busy day but couldn’t get much sleep the night before, you might feel like it’s hard to pay attention or that you need more time to complete tasks,” Dev noted. “Other domains, such as memory, are less vulnerable to stressors.”

This alignment with terrestrial stress responses suggests space-related cognitive changes might stem from the overall demands of spaceflight rather than specific physiological changes to the brain.

Research Methods: Measuring the Astronaut Brain

The study employed a rigorous methodology to track cognitive performance throughout each astronaut’s journey.

Twenty-five professional astronauts underwent a battery of tests at multiple timepoints:

• Before launch
• Early in their mission
• Middle of their mission
• Late in their mission
• After returning to Earth

The tests were specifically designed to assess cognitive speed and accuracy across different domains, providing a comprehensive picture of how spaceflight affects brain function.

This longitudinal approach allowed researchers to identify which cognitive abilities were most affected during different mission phases and how quickly they recovered after returning to Earth.

The Space Health Puzzle

This research adds an important piece to our understanding of how space affects human health. We already know space travelers face numerous physiological challenges:

• Bone density loss of approximately 1-2% per month
• Muscle atrophy requiring daily exercise to counteract
• Cardiovascular changes as fluids shift toward the upper body
• Vision deterioration through a condition called Spaceflight Associated Neuro-ocular Syndrome (SANS)
• Immune system alterations making astronauts more susceptible to illness

Now we can add temporary cognitive slowing to this list—though reassuringly, without evidence of permanent damage after six months in space.

Implications for Deep Space Missions

While the results are encouraging for current ISS missions, they raise important questions about longer journeys to destinations like Mars, which could take years rather than months.

Several factors could make cognitive effects more pronounced during deep space exploration:

• Increased radiation exposure beyond Earth’s protective magnetosphere
• Extended isolation and confinement far from home with no possibility of quick return
• Communication delays of up to 40 minutes round-trip, eliminating real-time support
• Autonomous operations requiring quick decision-making without ground control

“These findings help establish a baseline for six-month missions in Low Earth Orbit,” says aerospace medicine specialist Dr. James Keller, who wasn’t involved in the research. “But we must be cautious about extrapolating these results to multi-year deep space missions where conditions are significantly different.”

The Radiation Question

One factor not fully addressed in this study is space radiation—a primary concern for brain health during long-duration missions.

ISS astronauts receive higher radiation doses than people on Earth but are still protected by Earth’s magnetosphere. In deep space, cosmic radiation exposure increases dramatically.

“Radiation affects the brain differently than microgravity,” explains radiation biologist Dr. Maria Chen. “Animal studies suggest high-energy cosmic particles can damage neural connections and potentially accelerate cognitive aging. Future research needs to examine these combined effects.”

NASA and other space agencies continue developing technologies to shield astronauts from radiation, including novel materials and habitat designs that might reduce exposure during deep space journeys.

Developing Countermeasures

Understanding these cognitive changes allows researchers to develop targeted countermeasures for future missions.

Potential interventions might include:

• Cognitive training programs designed to strengthen vulnerable domains
• Mission scheduling that accounts for adaptation periods
• Automated systems to detect cognitive slowing and adjust workload accordingly
• Novel pharmaceuticals that may protect neural function
• Virtual reality systems providing psychological support and cognitive stimulation

“When we understand exactly how and why these changes occur, we can develop precise countermeasures,” says Dev. “For example, if we know processing speed slows most significantly in the middle of a mission, we could adjust task scheduling during that period.”

Individual Differences Matter

The researchers also noted significant variation among individual astronauts, suggesting some people may be more resilient to space-related cognitive changes than others.

“While we observed consistent patterns across the group, some astronauts showed minimal changes while others experienced more pronounced effects,” explains Dev. “Understanding these individual differences could help us select and prepare crews for different mission profiles.”

This variability highlights the importance of personalized approaches to astronaut health monitoring and support.

Broader Implications on Earth

Beyond space exploration, this research offers insights into how the human brain responds to extreme environments and stress on Earth.

The findings may benefit people working in isolated, confined, and extreme environments such as:

• Antarctic research stations
• Submarine crews
• Military personnel in remote outposts
• Emergency responders during extended crises

“The parallels between space-induced cognitive changes and Earth-based stress responses suggest common mechanisms,” notes neuroscientist Dr. Rebecca Huang. “Interventions developed for astronauts could potentially help people in high-stress occupations maintain optimal cognitive performance.”

Looking Forward: Mars and Beyond

As space agencies prepare for missions to Mars and beyond, understanding and mitigating cognitive effects becomes increasingly critical.

A successful Mars mission would require astronauts to maintain peak cognitive performance for up to three years while dealing with unprecedented challenges and complete autonomy.

“Six months is just the beginning,” says Dev. “We need to extend this research to understand how these effects might evolve during longer durations and whether there are cumulative impacts from multiple missions.”

Several space agencies are currently conducting analog missions—Earth-based simulations of long-duration spaceflight—to study these effects. NASA’s Human Research Program continues investigating ways to protect astronaut brain health during extended missions.

The Ultimate Frontier: The Human Mind

As we look toward establishing permanent human presence beyond Earth, this research reminds us that the greatest challenges may not be technological but biological.

The human brain evolved over millions of years in Earth’s gravity, atmosphere, and radiation environment. Taking it elsewhere represents one of the boldest experiments in human history.

Yet this research offers optimism: our brains appear remarkably adaptable, maintaining accuracy even when processing slows, and returning to baseline after returning to Earth.

“The brain’s resilience is our greatest asset for space exploration,” concludes Dev. “Understanding its vulnerabilities allows us to support and protect this extraordinary organ as we venture into the cosmos.”

For now, astronauts returning from six-month ISS missions can take comfort in knowing their cognitive abilities appear to fully recover—another testament to the remarkable adaptability of the human brain, even when tested against the harshest frontier of all.

References

1. Dev, S., et al. (2023). Cognitive Performance During and After Long-Duration Spaceflight. Frontiers in Physiology, 14, 1135876.
2. NASA Human Research Program. (2024). Evidence Report: Risk of Adverse Cognitive or Behavioral Conditions and Psychiatric Disorders.
3. Garrett-Bakelman, F.E., et al. (2019). The NASA Twins Study: A multidimensional analysis of a year-long human spaceflight. Science, 364(6436).
4. Roberts, D.R., et al. (2022). Effects of Spaceflight on Astronaut Brain Structure. New England Journal of Medicine, 386(12), 1150-1159.
5. Blue, R.S., et al. (2023). Space radiation and central nervous system function: A review of human and animal studies. Frontiers in Neuroscience, 17, 1224503.