Copenhagen, Denmark (CNN Business) Last month marked 20 years of continuous human presence on the International Space Station (ISS). Scientific research to improve life aboard the ISS has led to countless developments in space technology, but it has also brought benefits to people on Earth.
LED lighting technology developed to help astronauts avoid sleep deprivation has been adapted for domestic use; a weight-lifting system to keep astronauts fit in zero gravity is being used in home workouts.
Now a company that designed a water-purification system for the ISS is developing spin-off technologies with the potential to provide clean drinking water in the places that need it most.
Nature's filter
On the ISS, every drop of moisture, from humidity to urine, has to be filtered and reused. But the current system is very heavy, has to be replaced every 90 days, and fails to filter out certain contaminants, according to NASA.
Danish company Aquaporin A/S has developed a new system that uses proteins called aquaporins. "It is essentially the mechanism that allows water to cross the cell membrane of living cells," says Peter Holme Jensen, CEO of Aquaporin A/S. In nature, these proteins allow plant roots to absorb water from soil, and let the two human kidneys together filter about 45 gallons of fluid per day. They are also very selective, preventing contaminants from passing through.
Having tested it in space, NASA is considering replacing its current system with Aquaporin's, but the technology is also finding uses closer to home.
Space research may seem far removed from daily life, but a surprising amount of NASA technology has found more earthly uses. Today's wireless headsets are an updated version of technology developed for astronauts in the 1960s. Before then, headsets used by airplane pilots were bulky and uncomfortable, but NASA commissioned a headset that could be
implanted in an astronaut's helmet. It was used to transmit Neil Armstrong's words when he landed on the moon.
In the 1970s, former NASA engineer Frank Rudy developed
shock-absorbing, gas-filled membranes fitted into the soles of running shoes. The idea drew on a process called "blow rubber molding," used by NASA to create lightweight space helmets. It was the basis of the
"Nike Air" system, and was adapted by other shoe companies, helping protect runners' joints from impact injuries.
In the 1990s, NASA was looking into ways to create smaller cameras for spacecraft. It came up with the
"complementary metal oxide semiconductor" (CMOS) image sensor, which produced high-quality digital photographs. As the technology developed it was licensed by the likes of Sony and Samsung, according to NASA, and CMOS is now a standard in digital cameras and phones. But camera phones aren't just for fun. The "Eyephone" app, for example, scans eyes to detect diseases such as cataracts and glaucoma, and is aimed at people living in rural areas in developing countries.
This indoor vertical farm in Belgium grows lettuce using LED light rather than sunlight. Vertical farms do not require soil and use little water, controlling light, air, humidity and temperature to optimize growth.
NASA first developed this technology in the 1990s with the aim of growing plants in space.
Back in the 1960s NASA worked on
creating a device to purify drinking water for astronauts. It used silver ions to kill off bacteria without affecting the taste. The technology has since been used across the world for drinking water and in swimming pools. The PentaPure brand system was used to purify water
on Space Shuttle missions and is now used in homes and disaster relief efforts.
This ear thermometer is being used at a medical center in Paris. Thermometers that measure the infrared energy emitted from the eardrum were
developed in the early 1990s by Diatek Corporation, which was a part of a Technology Affiliates Program at NASA's Jet Propulsion Laboratory (JPL). The ear thermometers were based on technology JPL created for its Infrared Astronomical Satellite (IRAS), which remotely monitored the temperature of stars and planets from the infrared radiation they emit.
Superinsulators used in cold weather gear such as winter coats, boots and sleeping bags stem from a technology that was first used to combat extreme temperatures in space.
A material called "Radiant Barrier," developed by NASA in the 1960s, is now used in home insulation.
Cochlear implants can give a sense of sound to deaf people, by using electrodes to stimulate the auditory nerve. A rudimentary version was
trialled in the 1950s, and the idea was further developed by Adam Kissiah, a hard-of-hearing engineer at Kennedy Space Center. He had worked on sound and vibration sensor systems for
NASA in the 1970s and used his knowledge to develop the life-changing implant.
Tasked with feeding astronauts on long space missions while also minimizing the weight of food, NASA turned to freeze drying. It refined existing techniques to the point where it says it can now retain
98% of the nutrients at 20% of the original weight. NASA also developed
freeze-dried ice cream. These days, freeze-dried food is used in everything from emergency survival kits to disaster relief.
Foil blankets are used by paramedics to retain a person's body heat, and they're widely used to keep runners warm after a marathon. These metallic sheets originated from
NASA research in the 1960s, when it was looking to insulate spacecraft and protect astronauts and equipment from the extreme temperature changes of space.
In the 1960s
NASA developed Temper foam as a shock-absorbing filling to improve the comfort of its pilots' airplane seats. It has since been used to pad the helmets of football players, protect bedridden patients from bedsores, as molded seating for people with severe disabilities, and in memory foam mattresses.
Over 2 billion people worldwide don't have access to clean drinking water, and in developed countries, many people don't trust the safety of tap water. More than half of households in the United States are concerned about the quality of their water supply, and only 55% of Europeans drink water directly from the tap.
Aquaporin's technology could help. The company is working with wastewater companies — including BIOFOS, Denmark's largest state-owned wastewater utility, and UTB Envirotec in Hungary — to remove micropollutants and microplastics from wastewater, preventing them from flowing into the sea.
A study conducted at BIOFOS showed that aquaporins remove over 95% of microplastics and micropollutants in wastewater, using much less energy than traditional systems.
"It has an enormous potential," says BIOFOS innovation manager Dines Thornberg, who led the study. "I think the Aquaporin system could lead the way in actually creating clean, affordable drinking water from wastewater in the future. I am really optimistic that we can meet the challenges of water scarcity in many parts of the world with technologies like this."
Joerg Hess, COO of Aquaporin A/S, checks water that has been filtered using the aquaporin membrane.
Clean water at home
Jensen has also spotted an opportunity to enter the domestic water purification market — a sector that could be worth $24 billion by 2025, by one estimate.
Last month, Aquaporin A/S launched an under-the-sink household filtration system that works without electricity. The system costs €650 and the company is currently targeting the European market. It plans to expand to the United States, and then India and China in the next two years.
As production increases, its long-term goal is to offer an affordable product for water-stressed regions. "I really believe that we can make a difference," says Jensen.