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Improving DNA-detecting transistors using graphene

  • Writer: Marine Le Bouar
    Marine Le Bouar
  • Feb 27, 2017
  • 2 min read


Schematic of a graphene-based field-effect transistor (left) and an atomic force microscopy image of graphene covered with single-stranded probe DNA (right).

Graphene-based transistors could soon help diagnose genetic diseases. Researchers in India and Japan have developed an improved method for using graphene-based transistors to detect disease-causing genes.

Researchers in India and Japan have developed an improved method for using graphene-based transistors to detect disease-causing genes.

Graphene field-effect transistors (GFETs) can detect harmful genes through DNA hybridization, which occurs when a ‘probe DNA’ combines, or hybridizes, with its complementary ‘target DNA.’ Electrical conduction changes in the transistor when hybridization occurs.

Nobutaka Hanagata of Japan’s National Institute for Materials Science and colleagues improved the sensors by attaching the probe DNA to the transistor through a drying process. This eliminated the need for a costly and time-consuming addition of ‘linker’ nucleotide sequences, which have been commonly used to attach probes to transistors.

The research team designed GFETs that consist of titanium-gold electrodes on graphene—a one-atom-thick layer of carbon—deposited on a silicon substrate. Then they deposited the DNA probe, in a saline solution, onto the GFET and left it to dry. They found that this drying process led to direct immobilization of the probe DNA on the graphene surface without a need for linkers. The target DNA, also in saline solution, was then added to the transistor and incubated for four hours for hybridization to occur.

The GFET operated successfully using this preparation method. A change in electrical conduction was detected when the probe and target combined, signaling the presence of a harmful target gene. Conduction did not change when other non-complementary DNA was applied.

DNA hybridization is usually detected by labelling the target with a fluorescent dye, which shines brightly when it combines with its probe. But this method involves a complicated labelling procedure and needs an expensive laser scanner to detect fluorescence intensity. GFETs could become a cheaper, easier to operate, and more sensitive alternative for detecting genetic diseases.

“Further development of this GFET device could be explored with enhanced performance for future biosensor applications, particularly in the detection of genetic diseases,” conclude the researchers in their study published in the journal Science and Technology of Advanced Materials.

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