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Ultrasensitive Test Detects Early Onset of Infectious Diseases

Virus particles on a red background.
Credit: Gerd Altmann/ Pixabay
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Rutgers researchers have developed a way of detecting the early onset of deadly infectious diseases using a test so ultrasensitive that it could someday revolutionize medical approaches to epidemics.


The test, described in Science Advances, is an electronic sensor contained within a computer chip. It employs nanoballs – microscopic spherical clumps made of tinier particles of genetic material, each of those with diameters 1,000 times smaller than the width of a human hair – and combines that technology with advanced electronics.


“During the COVID pandemic, one of the things that didn’t exist but could have stemmed the spread of the virus was a low-cost diagnostic that could flag people known as the ‘quiet infected’ – patients who don’t know they are infected because they are not exhibiting symptoms,” said Mehdi Javanmard, a professor in the Department of Electrical and Computer Engineering in the Rutgers School of Engineering and an author of the study. “In a pandemic, pinpointing an infection early with accuracy is the Holy Grail. Because once a person is showing symptoms – sneezing and coughing – it’s too late. That person has probably infected 20 people.”


For the past 20 years, Javanmard has been developing biosensors – devices that monitor and transmit information about a life process. During the COVID-19 pandemic, he became disheartened about the extent of infections and the extreme loss of life. He believed there had to be a way of using biosensors as a test to detect illness earlier.

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Working with Muhammad Tayyab, a Rutgers doctoral student and co-author of the study, Javanmard and research colleagues at the Karolinska Institute in Sweden and Stanford and Yale universities started brainstorming.


“We thought: How is there a way where we can leverage our individual expertise to build something new?” Javanmard said.


The biosensor developed by the team works through a series of steps. First, it zeroes in on a virus’ characteristic sequence of nucleic acids – naturally occurring chemical compounds that serve as the primary information-carrying molecules in a cell. Next, because it amplifies any nucleic acid sequence found in the sample, it makes many more copies, as many as 10,000. Then, it clumps those thousands of specks of nucleic acids into nanoballs that are “large” enough to be detected.


The nanoballs are identified electrically when they are directed individually through minute channels containing electrodes on opposite sides. The process is akin to people walking single file through an airport security gate and being X-rayed one by one.


“Our method involves taking the viral nucleic acid material and rolling it up into a ball of DNA that is large enough to be detected by a cell measurement device known as an electronic cytometer,” Javanmard said. “As a result, we can flag the infection at its earliest stages when the concentration is still very low.”


The approach works in samples taken from blood and saliva and has been shown to detect early infections by several viruses, including the rhinovirus causing the common cold, and even bacterial infections such as tuberculosis. The technology, which has been miniaturized and is contained within a computer chip, is small enough to be portable and wearable.


The most immediate use, once commercialized, is expected to be the test’s efficacy in flagging viral infections at early stages. Ultimately, the technology also may be used to test bacteria-based illnesses as well as bacterial contamination found in food and water supplies, Javanmard said.


“These pathogens can be devastating to the economy, to people’s livelihoods, and to people’s health,” Javanmard said. “We should not stop preparing for this. We need to be creating the next generation of tools to stop them. And that’s really what this technology is.”


Reference: Tayyab M, Barrett D, van Riel G, et al. Digital assay for rapid electronic quantification of clinical pathogens using DNA nanoballs. Sci Adv. 2023;9(36):eadi4997. doi: 10.1126/sciadv.adi4997


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