I am a scientifically minded person, curious to understand everything I can about the universe. We know there are trillions of stars, more than the number of grains of sand on planet Earth. Those stars make up less than 5 percent of the matter in the universe. The rest is dark matter and dark energy. The universe is so complex. Is it all an accident? I don’t know.
I was raised Catholic, and as is the case in many families, my parents were more dedicated to their children’s religious development than they were to their own. Mark and I attended catechism classes until one day in the ninth grade, when my mother got tired of driving us. She gave us the choice of whether to keep going or not, and, as many teenagers would, we chose to opt out. Since that day, organized religion has not been part of my life. When Samantha was ten years old, she asked me at dinner one evening what religion we were.
“Our religion is ‘Be nice to other people and eat all your vegetables,’?” I said. I was pleased with myself for describing my religious beliefs so concisely and that she was satisfied with it. I respect people of faith, including an aunt who is a nun, but I’ve never felt that faith myself.
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WE WILL be spending a lot of time this week working on an experiment called “Fluid Shifts Before, During, and After Prolonged Space Flight and Their Association with Intracranial Pressure and Visual Impairment”—“Fluid Shifts” for short. Misha and I are the subjects of the experiment, and it promises some of the most important results for the future of spaceflight.
Maybe the most troubling negative effect of long-duration missions in space has been damage to astronauts’ vision, including mine on my previous mission. At first, these changes were assumed to be temporary. Once astronauts started flying longer and longer missions, though, we showed more severe symptoms. For most, the changes gradually disappeared once the mission was over; for some, the symptoms seemed to be permanent. When I flew my first mission on the space shuttle, in 1999, I didn’t need corrective lenses, but while on the mission I realized things were getting blurry in the middle range, ten or twelve feet—across the flight deck of the space shuttle. Back on Earth, my symptoms quickly resolved. My second flight was eight years later, by which time I had started using reading glasses. After about three days in space, I no longer needed them. The improvement lasted for about three months after I returned to Earth.
Three years later, for my first long-duration flight, 159 days, I was wearing bifocals all the time. After a short period in orbit, my vision got worse, and I wore stronger lenses to correct for the change. When I returned to Earth, within a few months my vision returned to what it had been when I left. But I had other troubling signs: swelling of the optic nerve and what seemed to be permanent choroidal folds. (The choroid is a blood-filled layer in the eyeball between the retina and the sclera—the white part—that provides oxygen and nourishment to the outer layers of the retina. These folds in the choroid could damage the retina and cause blind spots.) My vision symptoms so far this year seem to be similar to the last time, though we are monitoring them closely to see whether they will get worse.
If long-term spaceflight could do serious damage to astronauts’ vision, this is one of the problems that must be solved before we can get to Mars. You can’t have a crew attempting to land on a faraway planet—piloting the spacecraft, operating complex hardware, and exploring the surface—if they can’t see well.
The leading hypothesis is that increased pressure in the cerebral fluid surrounding our brains is causing the vision changes. In space, we don’t have gravity to pull blood, cerebral fluid, lymphatic fluid, mucus, water in our cells, and other fluids to the lower half of our bodies like we are used to. So the cerebral fluid does not drain properly and tends to increase the pressure in our heads. We adjust over the first few weeks in space and pee away a lot of the excess, but the full-head sensation never completely goes away. It feels a little like standing on your head twenty-four hours a day—mild pressure in your ears, congestion, round face, flushed skin. As with so many other aspects of human anatomy, the delicate structures of our heads evolved under Earth’s gravity and don’t always respond well to having it taken away.
The increased fluid pressure may squish our eyeballs out of shape and cause swelling in the blood vessels of our eyes and optic nerves. This is all still a theory, as it’s hard to measure the pressure inside our skulls in space (the best way to measure intracranial pressure is a spinal tap, which I’d very much prefer not to have to undergo, or to perform on a crewmate, in space). It’s possible, too, that high CO2 is causing or contributing to changes in our vision, since it is known to dilate blood vessels. High sodium in our space diets could also be a factor, and NASA has been working to reduce that in order to test whether this makes a difference. Only male astronauts have suffered damage to their eyes while in space, so looking at the slight differences in the head and neck veins of male and female astronauts might also help scientists start to nail down the causes. If we can’t, we just might have to send an all-women crew to Mars.
Since it’s impossible to re-create the effects of zero gravity in a lab for sustained periods of time, scientists have conducted experiments on people with pressure sensors already installed in their skulls for other medical conditions. These people were taken up on an airplane that can create weightlessness for short periods in order to measure what happens inside their heads when they reach zero gravity. Their intracranial pressure dropped when they got to microgravity, rather than increasing as had been expected. Maybe it takes a while for the fluids to shift, or maybe the leading hypothesis is wrong. Before leaving for this mission, I volunteered to have a pressure sensor installed in my skull, but NASA declined my offer. The risks of drilling a hole in my head before sending me to space for a year were too great.
In the Fluid Shifts study, Misha and I will be subjects in an experiment that uses a device for relieving the intracranial pressure of spaceflight—pants that suck. This is not a metaphor. We will take turns donning a device, roughly the shape of a pair of pants, called Chibis (Russian for “lapwing,” a type of bird), that reduces the pressure on the lower half of our bodies. The pants look a lot like the bottom half of the robot from Lost in Space, or like Wallace and Gromit’s “wrong trousers.” Reducing the pressure on our lower bodies also reduces the amount of fluid in our heads. By studying the effects of Chibis on our bodies, we hope to understand more about this problem.