Scientists at Washington University in St. Louis have developed a breath test that quickly identifies those who are infected with SARS-CoV-2. The device requires only one or two breaths and provides results in less than a minute.
The new study, available online in ACS Sensors, is about a breath test that could quickly diagnose people infected with the virus. If and when new strains of COVID-19 or other airborne pathogenic diseases arise, such devices also could be used to screen people at public events. Researchers said the breath test also has the potential to help prevent outbreaks in situations where many people live or interact in close quarters—for example aboard ships, in nursing homes, in residence halls at colleges and universities, or on military bases.
“With this test, there are no nasal swabs and no waiting 15 minutes for results, as with home tests,” said co-corresponding author Rajan K. Chakrabarty, PhD, the Harold D. Jolley Career Development associate professor of Energy, Environment & Chemical Engineering at the McKelvey School of Engineering. “A person simply blows into a tube in the device, and an electrochemical biosensor detects whether the virus is there. Results are available in about a minute.”
What is the underlying principle of the breath test device?
The biosensor used in the device was adapted from an Alzheimer’s disease-related technology developed by scientists at Washington University School of Medicine in St. Louis to detect amyloid beta and other Alzheimer’s disease-related proteins in the brains of mice. The School of Medicine’s John R. Cirrito, PhD, a professor of neurology, and Carla M. Yuede, PhD, an associate professor of psychiatry—both co-corresponding authors on the study—used a nanobody, an antibody from llamas, to detect the SARS-CoV-2 virus.
Chakrabarty and Cirrito said the breath test could be modified to simultaneously detect other viruses, including influenza and respiratory syncytial virus (RSV). They also believe they can develop a biodetector for any newly emerging pathogen within two weeks of receiving samples of it.
“It’s a bit like a breathalyzer test that an impaired driver might be given,” said Cirrito. “And, for example, if people are in line to enter a hospital, a sports arena, or the White House Situation Room, 15-minute nasal swab tests aren’t practical, and PCR tests take even longer. Plus, home tests are about 60–70 percent accurate, and they produce a lot of false negatives. This device will have diagnostic accuracy.”
The researchers began working on the breath test device—made with 3D printers—after receiving a grant from the National Institutes of Health (NIH) in August 2020, during the first year of the pandemic. Since receiving the grant, they’ve tested prototypes in the laboratory and in the Washington University Infectious Diseases Clinical Research Unit. The team continues to test the device, to further improve its efficacy at detecting the virus in people.
How does the breath test work?
For the study, the research team tested COVID-19-positive individuals, each of whom exhaled into the device two, four, or eight times. The breath test produced no false negatives and gave accurate reads after two breaths from each person tested. The clinical study is ongoing to test COVID-19-positive and -negative individuals to further test and optimize the device.
The researchers also found that the breath test successfully detected several different strains of SARS-CoV-2, including the original strain and the Omicron variant; their clinical studies are measuring active strains in the St. Louis area.
To conduct the breath test, the researchers insert a straw into the device. A patient blows into the straw, and then aerosols from the person’s breath collect on a biosensor inside the device. The device then is plugged into a small machine that reads signals from the biosensor, and in less than a minute, the machine reveals a positive or negative finding of COVID-19.
Clinical studies are underway and the researchers soon plan to employ the device in clinics beyond Washington University’s Infectious Diseases Clinical Research Unit. In addition, a New York-based company, has an exclusive option to license the technology. That company has consulted with the research team from the beginning of the project and during the device’s design stages to facilitate possible commercialization of the test in the future.
- This press release was originally published on the Washington University School of Medicine in St.Louis website