Tokyo: Scientists have developed a new method for identifying single virus particles based on changes in electrical current when they pass through ultra small pores, an advance which they claim may lead to new rapid COVID-19 tests.
The study, published in the journal ACS Sensors, demonstrated a new system for identifying single virus particles using an algorithm trained to detect changes in the current passing across silicon nanopores.
According to scientists, including those from Osaka University in Japan, the work may lead to fast and accurate screening tests for diseases like COVID-19 and influenza.
In the new method, the scientists said a layer of the compound silicon nitride just 50 nanometres (nm) thick has tiny nanopores added.
The layer is suspended on a silicon wafer, they said, adding that when a voltage difference is applied to the solution on either side of the wafer, ions travel through the nanopores in a process called electrophoresis.
According to the study, the motion of the ions can be monitored by the current they generate, and when a viral particle enters a nanopore, it blocks some of the ions from passing through, leading to a transient dip in the current.
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Each dip reflects the physical properties of the particle, such as volume, surface charge, and shape, the scientists said, adding that this measure can be used to identify the kind of virus.
Using artificial intelligence (AI), the research team built a classification algorithm trained with signals from known viruses to determine the identity of new samples.