A new material that packs deadly heat for viruses on its outer surface while staying cool on the reverse side could transform the way we make and use personal protective equipment (PPE), cutting down the pollution and carbon footprint associated with current materials and practices.
The composite, textile-based material developed by Rice University engineers uses Joule heating to decontaminate its surface of coronaviruses like SARS-CoV-2 in under 5 seconds, effectively killing at least 99.9% of viruses. Wearable items made from the material can handle hundreds of uses with the potential for a single pair of gloves to prevent nearly 20 pounds of waste that would have resulted from discarded single-use nitrile gloves.
“The surge in magnitude of PPE waste and problems caused by supply chain shortages during the pandemic made us realize the need for reusable PPE,” said Marquise Bell, a Rice mechanical engineering graduate student who is the lead author on a study on the material published in ACS Applied Materials and Interfaces. “This work paves the way for a systemic shift away from single-use disposable PPE.
“The best part is you don’t even need to take off the gloves or other protective garments in order to clean them. This material allows you to decontaminate in seconds, so you can get back to the task at hand.”
Using electrical current, the material rapidly heats up its outer surface to temperatures above 100 degrees Celsius (212 Fahrenheit), while remaining close to normal body temperature on the reverse side near the user’s skin where it reaches a maximum of about 36 C (97 F).
“The device has to get hot enough to effectively kill viruses, but not so hot that it causes burns or discomfort for the user,” Bell said. “We included safety mechanisms to make sure the latter doesn’t happen.”
Compared to other decontamination methods, dry heat tends to be both reliable and less likely to damage protective equipment. However, making wearables that heat up to adequate temperatures quickly has required a lot of work.
“Our lab has looked a lot at the thermal inactivation of viruses,” said Daniel Preston, an assistant professor of mechanical engineering who is an author on the study. “We started during the pandemic with support from a National Science Foundation grant, trying to understand the mechanism by which these viruses are inactivated and how it’s accelerated at higher temperatures.”
The earlier research helped lead to the design of the material. Yizhi Jane Tao , a professor of biosciences whose virology lab conducted experiments to confirm the material’s powers of self-decontamination, said she was impressed by how closely experimental data matched predictions.
“We’re very happy that we can contribute our expertise toward this new material,” Tao added.
Kai Ye, a graduate student in the Tao lab who helped with the research, said the gloves handled “the infectivity test” well and promise to protect against other similar viruses.
Considering the temperature difference between its outer and inner surfaces, the material is surprisingly supple and lightweight ⎯ a feat that feeds directly into Bell’s research focus on smart textile materials.
“I study the mechanics, thermodynamics and heat transfer processes of soft goods that can be layered for use in wearable assistive devices,” said Bell, who is funded by a NASA Space Technology Graduate Research Opportunities fellowship. “Spacesuits, for instance, are made up of many layers: The innermost layers are where a lot of the functionality happens, close to the human body. Then you have a lot of thermally insulating layers in between, topped off with firmer, more protective layers on the outside of the suit.
“I look at how we can use smart textile materials and integrate them into spacesuits to decrease their weight while adding multifunctionality.”
Bell participated in this year’s NextProf Nexus, a competitive workshop that is part of a “nationwide effort to strengthen and diversify the next generation of academic leaders in engineering,” according to the program.
Co-organized by the University of Michigan, University of California, Berkeley and Georgia Institute of Technology, NextProf Nexus helps prepare engineering students from underrepresented groups for navigating the academic job market, from researching open positions and funding opportunities to crafting effective application materials.
This year, NextProf was hosted by Georgia Tech and welcomed its largest cohort ⎯ roughly 70 participants out of more than 300 applicants.
“It’s becoming more real that I’m now in the latter part of my Ph.D.,” Bell said. “The workshop was a more comprehensive, in-depth experience than I initially expected, and I’m really glad I had the opportunity to participate.”
The research was supported by the National Science Foundation (2030023), the Welch Foundation (C-1565), NASA (80NSSC21K1276), the National GEM Consortium, the Rice Academy of Fellows and the Shared Equipment Authority.
Rapid In Situ Thermal Decontamination of Wearable Composite Textile Materials. ACS Applied Materials & Interfaces. 11 September 2023.
Summary: Pandemics stress supply lines and generate shortages of personal protective equipment (PPE), in part because most PPE is single-use and disposable, resulting in a need for constant replenishment to cope with high-volume usage. To better prepare for the next pandemic and to reduce waste associated with disposable PPE, we present a composite textile material capable of thermally decontaminating its surface via Joule heating. This material can achieve high surface temperatures (>100 °C) and inactivate viruses quickly (<5 s of heating), as evidenced experimentally with the surrogate virus HCoV-OC43 and in agreement with analytical modeling for both HCoV-OC43 and SARS-CoV-2. Furthermore, it does not require doffing because it remains relatively cool near the skin (<40 °C). The material can be easily integrated into clothing and provides a rapid, reusable, in situ decontamination method capable of reducing PPE waste and mitigating the risk of supply line disruptions in times of need.