"Kumar and the team didn't manage to mirror the aquaporin system exactly as planned. Instead, they discovered an even more effective water filtration process. Unlike the body's individual aquaporin cells, which function effectively independent of one another, the membranes developed by Kumar's research group didn't work well alone.
But, when he combined several of them to create networks of "water wires," they were highly effective at water transport and filtration. Water wires are densely connected chains of water molecules that move exceptionally fast, like a train and its individual cars.
...
"Our method is a thousand times more efficient than current desalination processes in terms of its selectivity and permeability," Kumar said. "For every 10,000 saltwater molecules that pass through current desalination systems, one salt molecule might not be filtered out. With our new membrane technology, one salt molecule for every 10 million water molecules would not be filtered out, while maintaining a water transport rate comparable to or better than current membranes.""
https://phys.org/news/2019-12-bodies-filtration-method.html
But, when he combined several of them to create networks of "water wires," they were highly effective at water transport and filtration. Water wires are densely connected chains of water molecules that move exceptionally fast, like a train and its individual cars.
...
"Our method is a thousand times more efficient than current desalination processes in terms of its selectivity and permeability," Kumar said. "For every 10,000 saltwater molecules that pass through current desalination systems, one salt molecule might not be filtered out. With our new membrane technology, one salt molecule for every 10 million water molecules would not be filtered out, while maintaining a water transport rate comparable to or better than current membranes.""
https://phys.org/news/2019-12-bodies-filtration-method.html