The exercise aims to investigate whether different probiotic strains of bacteria can be used to make yoghurt directly in space.
NASA ISS
It is probably no surprise that keeping healthy in space is incredibly important. And without the typical resources found on Earth, creative solutions have to be explored.
Right now, some excited Class 10 and Class 11 students from around Victoria in Australia are waiting with anticipation as their space-made yoghurt – fresh off the International Space Station – heads back to Australia from the National Aeronautics and Space Administration facilities in the United States.
The students worked with researchers at the Swinburne University of Technology to design an experiment investigating the nutritional values of space-made yoghurt. The results could provide insight into how to best help astronauts with vital nutrition during long-haul spaceflight.
It is probably no surprise that keeping healthy in space is incredibly important. And without the typical resources found on Earth, creative solutions have to be explored.
Right now, some excited Class 10 and Class 11 students from around Victoria in Australia are waiting with anticipation as their space-made yoghurt – fresh off the International Space Station – heads back to Australia from the National Aeronautics and Space Administration facilities in the United States.
The students worked with researchers at the Swinburne University of Technology to design an experiment investigating the nutritional values of space-made yoghurt. The results could provide insight into how to best help astronauts with vital nutrition during long-haul spaceflight.
Human gut
A critical factor in human health is the overall health of our gut microbiome, which is estimated to host more than 100 trillion bacteria.
Maintaining the health and diversity of these bacteria might be even more important in space than on Earth. In 2019, NASA released groundbreaking results from a year-long study on astronaut twins Mark and Scott Kelly.
In 2016, Scott spent 365 days on the space station, experiencing reduced gravity, while Mark remained on Earth. A fascinating result from the study was that Scott experienced significant changes to his gastrointestinal microbiome when in space – and which did not persist after he returned to Earth.
A critical factor in human health is the overall health of our gut microbiome, which is estimated to host more than 100 trillion bacteria.
Maintaining the health and diversity of these bacteria might be even more important in space than on Earth. In 2019, NASA released groundbreaking results from a year-long study on astronaut twins Mark and Scott Kelly.
In 2016, Scott spent 365 days on the space station, experiencing reduced gravity, while Mark remained on Earth. A fascinating result from the study was that Scott experienced significant changes to his gastrointestinal microbiome when in space – and which did not persist after he returned to Earth.
In 2016, Mark and Scott Kelly were part of a study on how living in space can affect the human body.
Photo credit: Robert Markowitz/ NASA
It is theorised the changes in microbiome experienced by astronauts are due to the lack of exposure to the “everyday” microbes encountered on Earth. Additionally, astronauts in space are exposed to less gravity, and high levels of radiation, which increase as they travel further away.
Understanding how to supplement astronauts’ gut bacteria and sustain its health is one of NASA’s current research goals. NASA is exploring this through both the use of capsule probiotics and simulated gravity experiments.
It is theorised the changes in microbiome experienced by astronauts are due to the lack of exposure to the “everyday” microbes encountered on Earth. Additionally, astronauts in space are exposed to less gravity, and high levels of radiation, which increase as they travel further away.
Understanding how to supplement astronauts’ gut bacteria and sustain its health is one of NASA’s current research goals. NASA is exploring this through both the use of capsule probiotics and simulated gravity experiments.
Why yoghurt?
Yoghurt is made by the bacterial fermentation of milk. The lactic acid produced in this process acts on the milk’s proteins to create yoghurt’s signature tart taste and thick texture. We wanted to see how this process is affected in the space environment.
Our student-led experiment is investigating whether different probiotic strains of bacteria can be used to make yoghurt directly in space. The ideal outcome would be to show that healthy, living bacteria cultures can be generated from frozen bacteria and milk products sent to space. This has not yet been achieved, although yoghurt has been made using bacteria returned from space previously.
This would be hugely beneficial during long space flights, where fresh food is limited and typical probiotic capsules would lose potency. Yoghurt also offers the nutritional benefits of the milk the bacteria are feeding off.
Road to space
Our brilliant students began this journey via two paths. Through the ongoing Swinburne Haileybury International Space Station Experiment program, six exceptional STEM students from Victoria’s Haileybury school worked with Swinburne staff and student mentors to develop, prototype and produce an experiment for the space station.
In the past, this program has sent human teeth, chia seeds and magnetorheological fluid to the International Space Station. For the 2021-’22 experiment, the students had 24 five-millilitre vials (things have to be tiny in space) in which to build their detailed experiment.
The second path was via the inaugural Swinburne Youth Space Innovation Challenge, which provides the opportunity to send an experiment to space as part of the Swinburne/Rhodium Scientific payload.
Teams from four Victorian schools undertook an 11-week crash course in space applications before pitching their dream experiment. The winning team from Viewbank College was assigned six dedicated experimental vials, with all other teams also awarded a vial – all working towards the goal of investigating probiotics, bacteria and yoghurt in space.
The 2021 Swinburne Youth Space Innovation Challenge winning team from Viewbank College blew the judges away with their insightful idea of investigating magnetic fields on plant growth in space.
Pictured (L-R): Tarnie Jones, Belle Shi, Madeline Luvaul and Paisley Noble. Photo credit: Author provided
Aboard the ISS
Once ready for flight, the final bacteria samples were prepared and put into deep freeze by our Rhodium Scientific partners at the Kennedy Space Centre in the United States.
The experiment samples were prepared at the Kennedy Space Centre (left), which involved putting them through a rapid-spinning vortex procedure (right).
Photo credit: Rhodium Scientific
All 33 vials boarded their rideshare to the International Space Station via the SpaceX Crew Dragon 24 and were launched on December 24. Once onboard, the samples were removed from the deep freeze by Astronaut Mark Vande Hei and set aside in a room-temperature experiment chamber in the Japanese Experiment Module, named Kibo.
After the allotted 48- and 72-hour timestamps (the time it takes to typically make yoghurt on Earth) the samples were placed back in deep freeze to preserve the progress. It is expected they would have become yoghurt during this time.
The samples returned to Earth in late January and will be investigated by staff and students in the coming months, once they return to Australia.
All 33 vials boarded their rideshare to the International Space Station via the SpaceX Crew Dragon 24 and were launched on December 24. Once onboard, the samples were removed from the deep freeze by Astronaut Mark Vande Hei and set aside in a room-temperature experiment chamber in the Japanese Experiment Module, named Kibo.
After the allotted 48- and 72-hour timestamps (the time it takes to typically make yoghurt on Earth) the samples were placed back in deep freeze to preserve the progress. It is expected they would have become yoghurt during this time.
The samples returned to Earth in late January and will be investigated by staff and students in the coming months, once they return to Australia.
The Rhodium Probiotic Challenge samples were boarded on the SpaceX Crew Dragon 24 spacecraft.
Likely findings
The students chose to explore six different bacteria strains mixed together in various combinations, as well as certain strains isolated. With both the space-based experiment and control experiments conducted on Earth, we will be able to determine whether the bacteria sent to the International Space Station were significantly affected by reduced gravity.
Working from the lab at Swinburne, we will use methods such as DNA sequencing to isolate any variations in the genetic makeup of the bacteria, and investigate how many generations (or cell divisions) have occurred in the samples.
The students also purposely designed the experiment to test both dairy and non-dairy milk options, to see the potential differences in nutritional output. But perhaps the most exciting part for all involved will be the final taste test – and finding out if space yoghurt really is out of this world.
Sara Webb is Postdoctoral Research Fellow at the Centre for Astrophysics and Supercomputing and Rebecca Allen is Coordinator, Swinburne Astronomy Online, Program Lead of Microgravity Experimentation, Space Technology and Industry Institute at Swinburne University of Technology.
This article first appeared on The Conversation.
The students chose to explore six different bacteria strains mixed together in various combinations, as well as certain strains isolated. With both the space-based experiment and control experiments conducted on Earth, we will be able to determine whether the bacteria sent to the International Space Station were significantly affected by reduced gravity.
Working from the lab at Swinburne, we will use methods such as DNA sequencing to isolate any variations in the genetic makeup of the bacteria, and investigate how many generations (or cell divisions) have occurred in the samples.
The students also purposely designed the experiment to test both dairy and non-dairy milk options, to see the potential differences in nutritional output. But perhaps the most exciting part for all involved will be the final taste test – and finding out if space yoghurt really is out of this world.
Sara Webb is Postdoctoral Research Fellow at the Centre for Astrophysics and Supercomputing and Rebecca Allen is Coordinator, Swinburne Astronomy Online, Program Lead of Microgravity Experimentation, Space Technology and Industry Institute at Swinburne University of Technology.
This article first appeared on The Conversation.
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