First Step Achieved Towards Electronic DNA Sequencing: Translocation Through Graphene Nanopores

Researchers have developed a new, carbon-based nanoscale platform to detect single DNA molecules electrically.

Using electric fields, DNA strands are pushed through nanoscale-sized, atomically thin pores in a grapheme-nanopore platform that ultimately may be important for fast electronic sequencing of the four chemical bases of DNA based on their unique electrical signature. The pores, burned into graphene membranes using electron beam technology, provide physicists from the University of Pennsylvania (Philadelphia, USA) with electronic measurements of the translocation of DNA. The findings were published in the July 14, 2010, issue of the journal Nano Letters.

"We were motivated to exploit the unique properties of graphene--a two-dimensional sheet of carbon atoms--in order to develop a new nanopore electrical platform that could exhibit high resolution,” said Dr. Marija Drndic, associate professor in the department of physics and astronomy in Penn's School of Arts and Sciences and the article's senior author. "High resolution of graphene nanopore devices is expected because the thickness of the graphene sheet is smaller than the distance between two DNA bases. Graphene has previously been used for other electrical and mechanical devices, but up until now it has not been used for DNA translocation.”

The research team had made graphene nanopores in a study completed two years ago and in this study put the pores to work. To conduct the research, Dr. Drndic and other members from the Drndic lab made use of large-area graphene material developed by postdoctoral fellow Zhengtang Luo and Prof. A.T. Charlie Johnson, both physicists at Penn. The team employed a chemical vapor deposition (CVD) technique to grow large flakes of graphene and suspend them over a single micron-sized hole made in silicon nitride. An even smaller hole, the nanopore in the very center of the suspended graphene, was then drilled with an electron beam of a transmission electron microscope (TEM).

Solid-state nanopores are proving to be important tools for probing biology at the single-molecule level. Graphene nanopore devices developed by the Penn team, work in a simple manner. The pore divides two chambers of electrolyte solution and researchers apply voltage, which drives ions through the pores. Ion transport is measured as a current flowing from the voltage source. DNA molecules, inserted into the electrolyte, can be driven single file through such nanopores.

As the molecules translocate, they block the flow of ions and are detected as a drop in the measured current. Because the four DNA bases block the current differently, graphene nanopores with subnanometer thickness may provide a way to distinguish among bases, realizing a low-cost, high-throughput DNA sequencing technique.

Moreover, to increase the robustness of graphene-nanopore devices, Penn researchers also deposited an ultrathin layer, only a few atomic layers thick, of titanium oxide on the membrane that additionally generated a cleaner, more easily wettable surface that allows the DNA to go through it more easily. Although graphene-only nanopores can be used for translocating DNA, coating the graphene membranes with a layer of oxide effectively reduced the nanopore noise level and at the same time improved the robustness of the device.

Because of the ultrathin nature of the graphene pores, researchers were able to detect an increase in the magnitude of the translocation signals relative to previous solid-state nanopores made in silicon nitride, for similar applied voltages.

The Penn team is now working on improving the overall effectiveness of these devices and on utilizing the conductivity of the graphene sheet to create devices with transverse electrical control over DNA transport. In particular, this transverse electrical control may be achievable by carving graphene into nanoelectrodes and utilizing its conducting nature. Towards this goal, the investigators have previously demonstrated nanosculpting of graphene into arbitrary structures, such as nanoribbons, nanopores, and other shapes, creating a solid foundation for future research.

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