Self-healing DNA may protect astronauts from killer radiation | Michelle Thaller | Big Think
So Peter, you ask a really good question about radiation perhaps being a limiting factor in human exploration. And honestly, this is something that people are working on very hard right now. It is indeed a challenge.
The astronauts on the space station are actually fairly well-protected from radiation. The Earth has a liquid metal core that generates a strong magnetic field around the Earth, and amazingly, the space station, which is about 200 miles above us, is still in that protective magnetic field. So when you’re just orbiting the Earth on a space station, the astronauts may get slightly higher doses of radiation, but they’re actually fairly well-protected.
What happens if you go beyond the Earth’s magnetic field, though, is that all of a sudden you’re vulnerable to the radiation of space. And specifically, it’s our wonderful friend the sun—I mean, none of us would be here without the energy and the light of the sun, but the sun actually outputs a lot of high-energy particles and these create high radiation levels anywhere where there isn’t a protected magnetic field.
So for example, if you went to the moon—and in fact, astronauts went to the moon in the 1960s and the 1970s—had there been a very powerful solar storm when the astronauts were there, it may have made them very sick and might have even killed them. So in some sense, it was good luck that when the astronauts were up on the moon, not protected by the Earth’s magnetic field, the sun was relatively quiet.
However, on a trip to Mars, which might take months (up to six months), you’re not going to be able to rely just on good luck. There will be solar activity. There will be bursts of high-energy particles from the sun. So how do you protect astronauts from that? And we’re working on technology.
In some cases, it’s a special kind of sleeping bag that you can get into and zip yourself up and have some protection. Other ideas—one of the best protectors against radiation is water. So if you have liquid water tanks on one side of your spacecraft, you might be able to shelter from a solar storm by putting the water tanks between you and the sun. But if you’re actually going to be living and working in space for a long time, this really is a problem.
If we were to send astronauts to Mars, for example, they wouldn’t be protected from the radiation unless they could dig under the ground and actually build their habitats—even just as much as ten feet down would be enough. But that’s hard. The Martian soil is very hard and rocky and not easy to dig through, and before you could go there, you’d have to send construction equipment to actually build all of these habitats.
So we understand that this is a problem. It’s one of the things that is limiting our exploration of the solar system. The robots that we build that go to Mars, like the Mars Rover or the spacecraft—there’s one orbiting Jupiter—they have to be extremely protected and shielded from the radiation of space. In fact, our mission to Jupiter right now is called Juno, and the instruments are inside a 700-pound box of almost pure titanium to protect it from the radiation around Jupiter.
Even with that protection, we only expect the instruments to last about two years; the radiation is that intense. So you could not go to visit Jupiter in a spacecraft and just happily sit there and watch this beautiful planet below you; you’d be dead in probably something like a day. So this really is a difficulty in sending astronauts out to the surface of the moon, to Mars, and if we ever do go, beyond.
So, what are some of the very, very long-range ideas? Obviously, we’re talking about shielding, about how we maybe could get astronauts protected under the ground, but there’s even stranger ideas that probably won’t come to fruition for centuries even, but they’re still neat ideas. We are observing some microorganisms that are very, very good at protecting themselves from radiation.
And one of them is my personal favorite animal—I have like a stuffed animal version of this. It’s a tiny, tiny little microscopic animal called a water bear or a tardigrade. And tardigrades are just little microscopic animals with six little arms, and they live on moss; all they do is suck nutrients off of moss. That’s all they do.
But a single tardigrade could take radiation levels that would kill a herd of a hundred elephants. This tiny little animal is almost completely resistant to radiation, and its DNA works in a really cool way. Radiation breaks up DNA. It’s one of the reasons you die when there’s a lot of radiation around, and somehow, tardigrade’s DNA knows how to heal itself right back up.
So we’re studying how tardigrade DNA works in the hopes that maybe someday we could even repair radiation damage to human DNA. There was a Star Trek episode, I remember, where Dr. McCoy gives people a shot to protect them from radiation. Could that someday happen? Well, maybe.
And we’re going to get there by starting to look at these microorganisms that are resistant to radiation, figure out how they do it, and—could we do that too? Maybe.