News Release

Eating your veggies, even in space

Researchers are developing the self-contained planters that will allow astronauts to grow food in space

Peer-Reviewed Publication

Norwegian University of Science and Technology

Lettuce on the Menu for Mars

image: Wolff found that the plants can "smell" or detect how much nutrition is available when she ran experiments in climate-regulated growth chambers in the Netherlands. Photo: Silje Wolff view more 

Credit: Silje Wolff, NTNU Social Research (CIRiS)

Fresh food is so attractive to astronauts that they toasted with salad when they were able to cultivate a few lettuce heads on the International Space Station three years ago.

In 2021, beans are on the menu to be grown in space, planted in high-tech planters developed at the Norwegian University of Science and Technology (NTNU).

"Astronauts like gardening and everything that reminds them of life on earth. They enjoy tending and watering the vegetables, and getting them to germinate," says Silje Wolff, a plant physiologist at the Centre for Interdisciplinary Research in Space (CIRiS), which is part of NTNU Social Research.

Wolff has just completed an experiment that involved growing lettuce for space. The lettuce was planted in artificial soil made from lava rock. The goal is for the plants to grow directly in water that is supplemented with plant nutrients.

"The dream of every astronaut is to be able to eat fresh food - like strawberries, cherry tomatoes or anything that's really flavorful. Someday that will certainly be possible. We envision a greenhouse with several varieties of vegetables," says Wolff.

The longest stays at the International Space Station have been six months. People travelling to Mars will need to be prepared to stay in space for at least a year.

The European Space Agency plans to build a lunar base in 2030 as a stopover on the way to Mars. NASA plans to fly directly to the planet with a target landing date of 2030.

"The way space travel works today, it's almost impossible to take along all the resources you need. That's why we have to develop a biological system so astronauts can produce their own food, and recycle all of the resources," says Wolff.

Today's astronauts eat only freeze-dried and vacuum-packed foods.

"Astronauts struggle with having little appetite. They often lose weight. Addressing the psychological aspect of eating something fresh is one of our goals. Vacuum-packed food doesn't really remind you of food. Having something fresh that triggers the appetite and the right receptors in the brain is important," Wolff says.

NTNU and CIRiS are collaborating with Italian and French researchers in their quest to cultivate plant-based food for long space journeys.

CIRiS tests the new equipment made by NTNU's technical workshop - very sophisticated planters that regulate all the water, nutrients, gas and air the plants need. In space, all the water and food has to be recovered. This means that plant fertilization needs to be as precise as possible.

Wolff has conducted experiments in climate-regulated growth chambers in the Netherlands as one aspect of this research.

Of all the nutrients plants use, they use nitrogen the most. During her experiments, Wolff looked at different nutrient doses and how they affected the plants' water uptake.

"We found that plants can, in a way, 'smell' the amount of nutrients available to them. When the nitrogen concentration is very low, the plant will absorb more water and thus more nitrogen until it reaches an optimal level. The plant has a mechanism that turns on when the nitrogen level is adequate. Then it adjusts both nitrogen and water absorption down," says Wolff.

Everything that can be tested on Earth has now been carried out. The next step is to grow beans in space to observe the effect of no gravity on plants' ability to transport water and absorb nutrients. Simulating the absence of gravity can't be done on Earth.

The beans are placed in a centrifuge to sprout and grow in the space station. The centrifuge is rotated to create different amounts of gravity.

"The art of getting something to grow in space can be transferred to our planet," Wolff said. "This is how we create a setup that produces both the microgravity conditions in the space station and the 1-g force that exists on Earth."

That will allow her to compare how the different gravitational levels affect the plants in space. On Earth, gravity causes warm air to rise while cold air sinks. In the space station, air is more stationary, causing astronauts to always have a low-grade fever. Plants are also affected.

"Stationary air affects a layer on the underside of the leaf where the stoma pores are located. When gravity disappears, the boundary layer in the slit-shaped apertures thickens. This reduces evaporation and causes the leaf temperature to increase. Water vapour diffusion to the environment is an important part of plant regulation and can be compared with sweating to cool the body in humans and animals," says Wolff.

Food production in cities offers an opportunity to produce more food in the most sustainable way. Cities don't have much soil for cultivation, but a lot becomes possible if you can plant directly in water in indoor closed systems where all aspects of the climate are regulated.

"Recycling and precise fertilization are key to achieving more sustainable food production. By growing plants directly in water with dissolved nutrients, fertilization and irrigation are much easier to control," says Wolff.

"The plants become less sensitive to nutritional deficiency because the roots are in direct contact with the nutrients. They're always able to access new nutrients through the water, and can use absolutely all the nutrients available - unlike with soil that binds the nutrients and affects their availability to the roots. And the roots don't rot when the water is mixed with a little oxygen," she says.

###

Reference: Testing New Concepts for Crop Cultivation in Space: Effects of Rooting Volume and Nitrogen Availability Silje A. Wolff, Carolina F. Palma, Leo Marcelis, Ann-Iren Kittang Jost and Sander H. van Delden. Life 2018, 8(4), 45; https://doi.org/10.3390/life8040045


Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert system.