IIT Mandi researchers develop anti-bacterial, self-cleaning material for face masks, PPE equipment
The developed nanomaterial can be cleaned by hanging the mask in bright sunlight after which it is ready to wear again
Indian Institute of Technology Mandi researchers have reportedly developed a virus-filtering, self-cleaning and antibacterial material that can be used to make face masks and other PPE equipment. This path breaking development of Dr Amit Jaiswal, Assistant Professor, School of Basic Sciences, IIT Mandi, along with his research scholars, Praveen Kumar, Shounak Roy, and Ankita Sarkar comes at a time in which it has become imperative to develop techniques to stop the second wave of the COVID-19 pandemic in the country.
Results of this work have recently been published in the prestigious journal of the American Chemical Society – Applied Materials & Interfaces.
A media handout from the institution points out that facemasks have (or must) become a default piece of apparel to be worn in public in these pandemic times. They are largely designed to act as a physical barrier between the wearer and the external environment, but in reality, must also act as anti-microbial agents to inhibit or kill pathogens. This is especially important in the case of reusable masks, which are a necessary alternative to single use masks that add to littering and pollution issues, and secondary infections.
“Keeping the urgency of the pandemic situation and cost-effectiveness in mind, we have developed a strategy to repurpose existing PPEs, especially face masks, by providing an antimicrobial coating to these protective clothing/textiles,” said Dr Jaiswal. For this, the research team has used such materials that are a hundred thousand times smaller than the width of the human hair to confer antimicrobial properties to polycotton fabric.
Dr Jaiswal and his team has incorporated nanometre sized sheets of molybdenum sulphide, MoS2, the sharp edges, and corners of which act as tiny knives that pierce bacterial and viral membranes, thus killing them. “The ‘nanoknife’-modified fabrics demonstrated excellent antibacterial activity even after 60 cycles of washing,” said the lead researcher, which makes this an excellent way to reuse masks and reduce biological waste generation.
Dr Jaiswal reminded that improperly disposed off PPEs are a serious secondary source of transmission, and having reusable antimicrobial masks can help circumvent this risk. The reusability of the fabric will also enable it to be integrated with homemade masks.
In addition to puncturing the microbial membranes, the nanosheets of molybdenum sulfide enable disinfection when exposed to light. Molybdenum sulphide exhibits photothermal properties, i.e., it absorbs solar light and converts it into heat, which kills the microbes. “Within 5 min of solar irradiation, all the MoS2-modified fabrics showed 100per cent killing of both E. coli and S. aureus,” wrote the authors in their recently published paper. Thus, merely hanging out the masks in bright sunlight can clean the mask and make it ready to wear again.
The researchers have developed prototypes of a 4-layered face mask using the MoS2 modified fabric. They report that these masks, in addition to killing microbes and being light-cleanable, can also filter >96 per cent of particles that are in the size range of the COVID-19 virus (120 nanometres), without compromising on the breathability of the fabric, and could thus be a powerful tool to prevent the spread of coronavirus and other microbial infections.
“We expect that the impact of this innovation on society will be immense and immediate, considering the current situation of global COVID-19 pandemic,” said Dr Jaiswal. The proposed materials can also be used to fabricate screens/sheets for creation of makeshift isolation wards, containment cells and quarantines for holding individuals who come in contact with pathogens.
Video file of Dr Amit Jaiswal explaining his research available at this link:
https://fromsmash.com/d.t1MjOZhg-dt?e=a2FqYWwueWFkYXZAZm9vdHByaW50Z2xvYmFsLmNvbQper cent3Dper cent3D