'Hibernating' Astronauts May Be Key to Mars Colonization

Artist's illustration of a "Mars Transfer Habitat" that could carry 100 colonists — 96 of them in a hibernation-like torpor state — to Mars. 

Credit: SpaceWorks Enterprises   

Colonizing Mars may require humanity to tap into its inner bear.

Researchers are working on ways to induce a hibernation-like torpor state in astronauts — a breakthrough they say would slash costs and make the long journey to the Red Planet safer and far less taxing for crewmembers.

Such benefits could help lay the foundation for the first footsteps on Mars, and they're essential to the establishment of a long-term human outpost there, project team members said. [Red Planet or Bust: 5 Crewed Mars Mission Ideas]

"We're not going to colonize Mars, or really settle it, sending four or six or eight people at a time every two years; we're going to have to send larger numbers," principal investigator John Bradford, president and chief operating officer of SpaceWorks Enterprises in Atlanta, said last week at the 2016 NASA Innovative Advanced Concepts (NIAC) symposium in Raleigh, North Carolina. "I don't know any other way that you're going to send hundreds of people to Mars."

A long sleep

With current rocket technology, a one-way trip to Mars takes six to nine months. That's a long time to keep astronauts alive, healthy and happy, Bradford said. He and his team think there's a way to ease this journey — lowering astronauts' body temperatures by about 9 degrees Fahrenheit (5 degrees Celsius). This would induce a "hypothermic stasis" that cuts crewmembers' metabolic rates by 50 to 70 percent, Bradford said.
"That reduces the need for consumables in both nutrition and hydration, [and] oxygen demand," he said during the NIAC talk. "That translates to mass, and mass is a critical item trying to support these Mars missions."

 Astronauts in stasis also wouldn't need as much room to move around, Bradford added. Indeed, the required living space of the habitat that would help transport six crewmembers to Mars could be cut by a factor of 40, from about 12,350 cubic feet (350 cubic meters) to 280 cubic feet (8 cubic m), he said. The smaller habitat would weigh just 12.7 tons, compared to 40.6 tons for the "standard" one.
Allowing astronauts to more or less sleep through the long trek would also minimize the psychological and social challenges of a crewed Mars mission, Bradford said.
"You kind of get mad at somebody; there's really no place to go," he said. "These are real issues associated with extended-duration spaceflight. If we can cut out the transit phases, we think they'll be much happier when they get to Mars, [and] much more productive." [Buzz Aldrin: How To Get Your Ass To Mars (Video)]

How to do it

Bradford and his team have received two rounds of funding through NIAC, a NASA program that seeks to encourage the development of potentially revolutionary space exploration technologies.
The researchers don't think any huge leaps should be required to make their vision a reality. They're not shooting for a sci-fi-like "suspended animation" state; rather, they seek to leverage the "therapeutic hypothermia" that's already common practice in hospitals around the world, often as a way to help people recover from traumatic injuries, Bradford said.
"We're trying to pull on this technology that's already in use," he said.
Therapeutic-hypothermia patients generally endure the treatment for just a few days, but there's no reason to think it couldn't be applied to astronauts for much longer durations, Bradford added. (He said he'd like to be able to put Mars crewmembers in stasis for the entire journey but that cycling periods of two weeks or so would have significant benefits as well.)
Stasis could be induced in astronauts via evaporative cooling systems already in use for therapeutic hypothermia — for example, two small tubes inserted into the nose that pump in inert gas, cooling the brain. (Sedatives would also be administered to dampen the body's instinctual shivering response.)
Crewmembers would be fed intravenously and catheterized; they would also be "lightly restrained" within the habitat to prevent them from floating around, Bradford said.
Extended exposure to microgravity conditions has a variety of negative health effects, from muscle atrophy and bone weakening to vision problems. But torpid astronauts wouldn't have to worry about such issues, because their habitat would be rotated, generating artificial gravity on board, Bradford said.
There are some inherent challenges in the torpor approach, of course. For example, while the process of going into hypothermic stasis is relatively rapid, waking up from such a state appears to be quite slow; research suggests that body temperature can be safely raised by only about 0.9 degrees Fahrenheit (0.5 degrees Celsius) every hour, Bradford said.
And it's unclear just how long the recovery process would take, or what the long-term mental effects of prolonged hypothermic stasis would be, he added. In addition, significantly cooling the body suppresses immune function, so torpid astronauts would likely be more susceptible to infections.
But Bradford and his team are attempting to address such issues via their NIAC-funded work, and they haven't found any deal breakers yet.
"It's all manageable," Bradford said. "We think this is a very promising approach."