A team of ΒιΆΉΣ³»΄«Γ½ researchers have proven the efficacy of a nanomaterial-based disinfectant they developed to combat the spread of the COVID-19 virus. Through their experiments, they found that the disinfectant was able to kill several serious viruses including SARS and Zika. The results of their findings were recently published in ACS Applied Materials and Interfaces.
βIt is always a delight to have our research work featured in a reputed journal,β said Udit Kumar, a doctoral student in the (MSE) and the lead author of the journal article. βGiven the theme and possible impact of antiviral research in current times, our article will definitely aid our fight against global pandemics.β
The paper outlines the most recent study from a multidisciplinary team of researchers that includes Sudipta Seal, the chair of the MSE department, and Griff Parks, a College of Medicine virologist and director of the . They experimented with the nanomaterial yttrium silicate, which has antiviral properties that are activated by white light, such as sunlight or LED lights. As long as there is a continuous source of light, the antiviral properties regenerate, creating a self-cleaning surface disinfectant.
βYttrium silicate acts as a silent killer, with antiviral properties constantly recharged by the light,β Kumar says. βIt is most effective in minimizing surface to the surface spread of many viruses.β
Kumar says their test of yttrium silicate in white light disinfected surfaces with high viral loads in approximately 30 minutes. Additionally, the nanomaterial was able to combat the spread of other viruses including parainfluenza, vesicular stomatitis, rhinovirus, Zika and SARS.
βThis disinfectant technology is an important achievement for both engineering and health because we all were affected during the pandemic,β Seal says. βCOVID is still ongoing and who knows what other illnesses are on the horizon.β
Other ΒιΆΉΣ³»΄«Γ½ researchers, including , nanotechnology student Balaashwin Babu β20 and materials science and engineering student Erik Marcelo, are co-authors on the paper.
βThis publication is the culmination of timely insight by the investigators as to the importance of rapid development of broad-spectrum anti-microbials, as well as hard work in the lab to show the potency of our new materials,β Parks says. βThis is an outstanding example of the power of cross-discipline research β in this case, materials science and microbiology researchers from CECS and COM.β
The research is funded by the U.S. National Science Foundationβs RAPID program.
Seal joined ΒιΆΉΣ³»΄«Γ½βs Department of Materials Science and Engineering and the Advanced Materials Processing Analysis Center, which is part of ΒιΆΉΣ³»΄«Γ½βsΒ College of Engineering and Computer Science, in 1997. He has an appointment at theΒ College of MedicineΒ and is a member of ΒιΆΉΣ³»΄«Γ½βs prosthetics clusterΜύ΅ώΎ±Ύ±΄Η²ΤΎ±³ζ. He is the former director of ΒιΆΉΣ³»΄«Γ½βs NanoScience Technology Center and Advanced Materials Processing Analysis Center. He received his doctorate in materials engineering with a minor in biochemistry from the University of Wisconsin and was a postdoctoral fellow at the Lawrence Berkeley National Laboratory at the University of California Berkeley.
Parks is theΒ College of MedicineβsΒ associate dean forΒ Research. He came to ΒιΆΉΣ³»΄«Γ½ in 2014 as director of the Burnett School of Biomedical Sciences after 20 years at the Wake Forest School of Medicine, where he was professor and chairman of the Department of Microbiology and Immunology. He earned his doctorate in biochemistry at the University of Wisconsin and was an American Cancer Society Fellow at Northwestern University.
Study title: Potent Inactivation of Human Respiratory Viruses Including SARS-CoV-2 by a Photoactivated Self-Cleaning Regenerative Antiviral Coating
