Simple, Inexpensive Electrochemical Diagnostics

A team of chemists from the University of Montreal have developed a DNA-based electrochemical diagnostic test that is inexpensive and can provide results in just a few minutes. This development has the potential to lead to point-of-care medical devices that can provide results for diagnoses ranging from cancer to autoimmune diseases in just minutes.

Not only is this development exciting for the advancement of the scientific community, it also has the potential to impact global health due to the low cost and ease of use of the test. The new development could help cut lag time and expenses between diagnosis and treatment for both communicable and non-communicable diseases on a global level.

Molecular Diagnostics at Home

“Despite the power of current diagnostic tests, a significant limitation is that they still require complex laboratory procedures. Patients typically must wait for days or even weeks to receive the results of their blood tests,” Alex Vallée-Bélisle said, head of the research team.

At the core of the DNA-based device is one of the simplest forces in chemistry: steric effects. Essentially, the new development focuses on the phenomenon of atoms getting too close to one another and using force to push off each other. This reaction allows researchers to detect a wide array of protein markers.

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Lab-on-a-Chip to Improve Clinical Diagnostics

The new method, which uses beads and microfluidics can change the way we study mixed populations of cells, such as those of tumors. Image: EPFL

The new method, which uses beads and microfluidics can change the way we study mixed populations of cells, such as those of tumors.
Image: EPFL

Scientist have developed a process that has the potential to make the study of tumor cells significantly more efficient.

They call it a “lab-on-a-chip,” and it’s allowing scientist to isolate single cells for study. The key here is in the difficulty that scientists typically face when attempting to study a single cell in a population. Due to factors such as variation of the isolated cell’s biochemistry and function, and technological and physical limitation dealing with size and fragility of the cells, studying at the single-cell level has always proven to be difficult.

In order to combat this issue, Ecole Polytechnique Federale de Lausanne (EPFL) scientists have combined affinity beads with microfluidics to produce an integrated, highly sensitive method for studying single cells – which has the potential to be adopted into clinical diagnostics.

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