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Home NEWS Science News Health

Revolutionizing Disease Detection: Harnessing the Power of a Single Molecule

Bioengineer by Bioengineer
January 2, 2025
in Health
Reading Time: 4 mins read
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Scientists at the University of California, Riverside have introduced a groundbreaking nanopore-based technology designed to revolutionize the realm of diagnostic testing. This innovative tool allows for the detection of diseases with unprecedented speed and accuracy by capturing electrical signals from individual molecules. Unlike current diagnostic tests that rely on the presence of millions of molecules—typically DNA or proteins—this new approach leverages the remarkable sensitivity of nanopore sensors, paving the way for earlier and more accurate disease detection.

At the core of this breakthrough lies the unique properties of the nanopore itself—a minuscule opening through which the targeted biomolecules can pass one at a time. These biomolecules, which often measure about one billionth of a meter wide, generate extremely faint electrical signals as they traverse the pore. The challenge has always been to develop detection instruments sensitive enough to pick up these delicate signals, a feat that the UC Riverside team has now accomplished.

Kevin Freedman, an assistant professor of bioengineering and the lead author of a recently published paper in Nature Nanotechnology, posits that current disease detection methods are fundamentally limited by their reliance on larger quantities of molecules. His team’s research demonstrates that valuable diagnostic data can derive from the passage of a single molecule through the nanopore, a significant advancement in the field of molecular diagnostics. According to Freedman, this enhanced level of sensitivity could substantially improve disease diagnostics.

In their pursuit of refining electronic detection methods, Freedman’s laboratory is focusing on creating detectors that emulate neuronal behavior. These devices retain memory of the molecules that have passed through them, adding a new layer of complexity and capability to diagnostic testing. To achieve this ambitious goal, the UCR scientists developed an intricate circuit model specifically tailored to account for the subtle variations in the sensor’s behavior when detecting biosignals.

When biological samples pass through the circuit, they are introduced with ionic salts that dissociate into charged particles. As proteins or DNA strands traverse the nanopore, they temporarily obstruct the flow of ions, resulting in a measurable decrease in ion current. Freedman explains that the device meticulously tracks this reduction in flow, translating it into an electrical signal that indicates the presence of a specific molecule. This granular approach allows the system to capture even the faintest signals from individual nucleic acids or proteins, enhancing diagnostic precision.

Notably, this nanopore technology is designed not only to function as a sensor but also to filter out extraneous background noise that could dilute or obscure critical signals from other molecules present in a sample. Traditional sensors often rely on external filters to eliminate unwanted signals; however, these can inadvertently discard essential data. On the other hand, Freedman’s nanopore mechanism ensures that every molecule’s signal is preserved, significantly boosting the accuracy and reliability of diagnostic applications.

Envisioning a future where this tool could be utilized in portable diagnostic kits, Freedman highlights the potential for these sensors to be as compact as a USB drive. Such devices could dramatically reduce the time needed to detect infections, transitioning from traditional testing methods that often require days for results to a scenario where diagnosis could occur within a mere 24 to 48 hours. This rapid turnaround time would represent a paradigm shift in how we approach fast-spreading diseases, providing clinicians with the ability to intervene and treat patients much earlier.

“The essence of nanopore technology lies in its ability to catch infections sooner—potentially before symptoms manifest or diseases spread,” Freedman asserts. This breakthrough not only aims to transform viral infection diagnostics but could also be pivotal in addressing chronic conditions, emphasizing the assay’s versatility and utility in modern medicine.

In addition to its diagnostic capabilities, this nanopore device holds immense promise for advancing protein research. Proteins are fundamental to cellular processes, and slight modifications in their structures can significantly affect health outcomes. Conventional diagnostic tools frequently struggle to differentiate between healthy and pathogenic proteins due to their structural similarities. However, the nanopore technology can discriminate between individual proteins by examining their distinctive signals, opening pathways for more tailored and effective treatments.

The quest for single-molecule protein sequencing—a longstanding challenge in molecular biology—has also been reinvigorated through this innovative research. While DNA sequencing offers crucial insights into genetic instructions, the ability to sequence proteins sheds light on how these instructions are expressed and modified in real time. Liberating this knowledge could lead to earlier disease detection and the development of highly personalized therapies, a critical advancement in the field of precision medicine.

Freedman’s team has received a research grant from the National Human Genome Research Institute, aimed at pushing the boundaries of nanopore technology to achieve effective single protein sequencing. The foundational work on enhancing the sensing capacity of nanopores for various molecular types has set the stage for these future advancements.

The research emphasizes the continuing exploration of molecular underpinnings that drive health and disease, and Freedman believes that this innovative technology is a strategic step towards realizing the goals of personalized medicine. By examining the specific molecular characteristics of individual patients, therapeutic interventions can be optimized for maximum efficacy.

As nanopore technology becomes increasingly affordable and accessible, Freedman predicts it will soon integrate into everyday health diagnostics, transforming outpatient care and even personal health monitoring at home. “I am confident that nanopores will become an integral part of daily life,” he remarks, embodying the optimism surrounding the implications of this discovery.

In summary, the innovative nanopore-based diagnostic tool developed at UC Riverside represents a potential breakthrough in disease detection. By capturing signals from individual molecules and filtering out background noise, this technology could facilitate earlier and more accurate diagnostics, marking a significant leap in personalized medicine and enhancing our understanding of biomolecular interactions and their implications for health.

Subject of Research: Nanopore-Based Diagnostics
Article Title: Negative memory capacitance and ionic filtering effects in asymmetric nanopores
News Publication Date: 2-Jan-2025
Web References: DOI
References: Nature Nanotechnology
Image Credits: University of California – Riverside

Keywords: Nanopore technology, diagnostic testing, single molecule detection, personalized medicine, protein sequencing, viral infections, biomedical research

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