Researchers Develop Membrane Coating for Virus Removal

Ben-Gurion University and University of Illinois create hydrogel coating to repel viruses in ultrafiltration

research, membranes, ultrafiltration, hydrogel, virus removal, contamination

Researchers from Ben-Gurion University of the Negev (BGU) and the University of Illinois at Urbana-Champaign (UIUC) have developed ultrafiltration membranes that significantly improve the virus-removal process from treated municipal wastewater used for drinking water in water-scarce cities.

Current membrane filtration methods require intensive energy to adequately remove pathogenic viruses without using chemicals like chlorine, which can contaminate the water with disinfection byproducts. Researchers at UIUC and BGU collaborated on the approach for virus pathogen removal, which was published in the current issue of Water Research.

"This is an urgent matter of public safety," said researchers. "Insufficient removal of human Adenovirus in municipal wastewater, for example, has been detected as a contaminant in U.S. drinking water sources, including the Great Lakes and worldwide."

The norovirus, which can cause nausea, vomiting and diarrhea, is the most common cause of viral gastroenteritis in humans, and is estimated to be the second leading cause of gastroenteritis-associated mortality. Human adenoviruses can cause a wide range of illnesses that include the common cold, sore throat (pharyngitis), bronchitis, pneumonia, diarrhea, pink eye (conjunctivitis), fever, bladder inflammation or infection (cystitis), inflammation of the stomach and intestines (gastroenteritis), and neurological disease.

In the study, Prof. Moshe Herzberg of the department of desalination and water treatment for the Zuckerberg Institute for Water Research at BGU and his group grafted a hydrogel coating onto a commercial ultrafiltration membrane. The "zwitterionic polymer hydrogel" repels the viruses from approaching and passing through the membrane. It contains both positive and negative charges and improves efficiency by weakening virus accumulation on the modified filter surface. The result was a significantly higher rate of removal of waterborne viruses, including human norovirus and adenovirus.

"Utilizing a simple graft-polymerization of commercialized membranes to make virus removal more comprehensive is a promising development for controlling filtration of pathogens in potable water reuse," said Nguyen, department of chemical engineering at UIUC.

Source: 
Science Daily

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