Preparing for Space Travel

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In the 1960s, a team of men from Gallaudet University in Washington, D.C., helped scientists study how space travel could affect the body. Each team member had lost his hearing in childhood in a way that affected his body’s ability to develop motion sickness. Pictured, some of the Gallaudet team prepare for a zero-gravity airplane flight.

Motion sickness isn’t fun. When traveling in a car, airplane, or boat, it can start suddenly. At first you might feel queasy and start sweating. These sensations can then lead to stronger symptoms, such as dizziness, nausea, and vomiting.

Ancient Greek sailors recognized the connection between sea travel and motion sickness. The English words nautical and nausea share the same Ancient Greek root word naus, meaning ship. The Ancient Greek word nausia meant ship-sickness. Today, we call motion sickness caused by boat travel seasickness. However, people can experience similar symptoms when traveling in airplanes or in cars.

Motion sickness occurs when the body sends the brain conflicting messages. For example, when you read a text on your phone in a moving car, your brain receives two inputs. Since your eyes are focused on your phone’s screen and not the passing scene, the eyes tell the brain that nothing is moving. However, while your eyes don’t sense movement, your body does. When the brain receives different messages from the eyes and the body, a person may start to feel physically sick.

The ear plays a key role in motion sickness. Along with hearing, the ear’s other role is to sense whether the body is balanced. The inner ear includes the body’s vestibular system. The vestibular system lets the body know if the head is moving side to side or up and down.

The ear’s vestibular system includes three fluid-filled canals. When your head moves from side to side or up and down, so does the fluid in these canals. Fluid in two small organs in your ear help detect when your head moves in a line, such as when you are walking or jumping up and down.  The canals or organs all activate a nerve called the vestibular nerve. The vestibular nerve tells the nervous system how your head is moving. This information helps us control our eyes and bodies when we move our heads. For example, it is your vestibular systems that allows you to maintain focus on an object while moving your head from side to side.

The Problems of Space Travel

In 1957, the Soviet Union launched a satellite called Sputnik. Since the Soviet Union beat the United States into space, the U.S. quickly turned its attention to space travel.

The newly formed National Aeronautics and Space Administration (NASA) was especially concerned about motion sickness. In space, the human body would feel weightless. In addition, while astronauts’ bodies might feel movement, their eyes might not detect it.  These conflicting messages might make astronauts very sick. Without understanding motion sickness, people might not stay physically well enough to travel in space.

In order to understand how bodies respond to motion, NASA needed two groups of people. One group included people who could get motion sickness, while the other group included people who could not. By comparing the reactions of each group, scientists hoped to learn more about motion sickness as a way to further space exploration.

Assembling a Team

NASA scientists knew that the human ear played a large role in motion sickness. They needed to find a group of people whose vestibular systems were damaged, preventing them from becoming motion sick.

NASA and the U.S. Naval School of Aviation Medicine contacted Gallaudet College (now called Gallaudet University). Gallaudet teaches students who have hearing impairments like deafness. NASA and the Navy wanted men who were physically fit, but men who could also withstand intense movement and gravitational forces. In addition, the subjects would need good writing skills so they could describe what they noticed and felt during the tests.

Scientists screened more than 100 Gallaudet students, faculty, and staff. Screening tested applicants’ balance and ability to withstand motion. In another test, subjects had very cold water dripped into their ears. One team member, Donald Peterson, said that this odd test originally had a different purpose. “Our eyes never moved, even when the temperature of the water was 32 degrees,” said Peterson. “They told us that the test was used to catch draft dodgers during World War II who claimed to be deaf, but were not.”

With Gallaudet’s help, NASA was able to assemble a team of 11 men who were deaf and fit the criteria NASA needed for the tests. Most of the men lost their hearing in a specific way that affected their ability to feel motion sickness. All but one member of the team had contracted a disease in childhood called spinal meningitis. Spinal meningitis is an infection which affects the fluid and membranes around the brain and spinal cord. If patients do not receive immediate treatment in a hospital, their brains can quickly become damaged, and they can die within hours.

Along with affecting hearing, spinal meningitis can also damage the ear’s vestibular system. If the disease kills cells and nerves that compose the vestibular system, the brain cannot receive information about balance or motion. With damaged vestibular systems, the 11 men on the team would not experience motion sickness. The one team member who did not have spinal meningitis felt motion sickness to only a small degree. “We were different in a way they needed,” said Harry Larson, one of the Gallaudet team members.

The Study

The 11 men from Gallaudet helped test machines NASA would use to simulate space travel. Since none of them could develop motion sickness, the team could report on the physical effects of the simulators without becoming nauseous. In one test, four of the team members spent 12 straight days inside a a special room that spun 10 times each minute. While that spinning would make most people sick, none of the men from Gallaudet were bothered by it.

As in a house, the rotating room had a stove, refrigerator, sink, toilet, shower, table, and chairs. It was also stocked with scientific equipment with which the subjects would conduct experiments. In order to test how spinning affected brain function, scientists had team members in the spinning room type sequences of letters or numbers on keypads or open locks with memorized codes. Scientists tested the team members’ physical dexterity by examining their ability to hold a stylus still inside a small opening without it touching the edges. Since the team could not get motion sickness, scientists could instead focus on the other ways that prolonged spinning affected the body.

Another test examined ocular counter-rolling, or when the eye rotates backwards because of gravitational pull. The test subjects rode in an airplane while the pilot spun and dipped the plane. These aerial stunts affected gravity on the plane“There was a doctor sitting, facing me while I rode backwards, and the pilot did aerobatics,” described team member Jerald Jordan. “Nothing happened, of course, except I had a great time.”


Another test might have seemed familiar to Ancient Greek sailors. Scientists placed a group of 20 people with healthy vestibular systems along with the team from Gallaudet on a wooden cargo ship off the Atlantic coast of Canada. Winds tossed the ship across the icy and turbulent waters. Scientists compared how each group reacted to the rough seas.

By the time the test ended, 15 out of the 20 hearing participants had become very seasick. In contrast, the Gallaudet team spent their time on board playing card games. Their only complaint? Fear of sinking because the ocean was so rough. “In retrospect, yes, it was scary,” said test participant Barron Gulak. “But at the same time we were young and adventurous.”

While on board the ship, scientists collected data by studying subjects’ blood pressure, eye movement, and digestion. Eventually the tests had to stop—the scientists themselves became too sick to continue!

Gallaudet team member Donald Peterson prepares to be lowered into a centrifuge tank. Since team members could not get motion sickness, scientists could instead focus on their bodies’ other reactions to movement and gravity changes.

Contributions Celebrated

The team from Gallaudet continued to participate in tests throughout the 1960s. With their help, NASA was able to learn a lot about how the body reacts to environments with gravity different from that on Earth. By learning more about motion sickness, the scientists could study how the human body adapts to spaceflight.

In 2017, the Gallaudet University Museum opened an exhibition honoring the team of 11 men called Deaf Difference + Space Survival. The exhibit was curated by Gallaudet student Maggie Kopp. Three of the 11 team members were in attendance at the exhibit’s opening in April 2017. “I am so grateful to the bioastronauts who shared their amazing stories about this chapter of American history, and the families who donated photographs, personal letters, documents, and film,” Kopp said. “This unforgettable experience helped shape my career plans. I also gained some friends and mentors I’ll hold dear.”

Additional Resources

Read more about how the team from Gallaudet College helped NASA scientists learn about motion sickness at Discover and NASA.

Learn how the body can feel movement at Britannica and the American Speech-Language-Hearing Association.

Discover how people who are deaf have contributed to history at WETA Radio and Virginia Commonwealth University.

Images and Sources

All photos: Gallaudet University Archive
Photo license: Creative Commons 3.0