News Release

Penn produces graphene nanoribbons with nanopores for fast DNA sequencing

Peer-Reviewed Publication

University of Pennsylvania

Drilling a Nanopore in a Graphene Nanoribbon -- while Blindfolded

image: Researchers at the University of Pennsylvania have made an advance towards realizing a new gene sequencing technique based on threading DNA through a tiny hole in a layer of graphene. Earlier versions of the technique only made use of graphene's unbeatable thinness, but the Penn team's research shows how the material's unique electrical properties may be employed to make faster and more sensitive sequencing devices. The technique involves drilling nanopores into ultra-thing graphene nanoribbons using the beam from a transmission electron microscope, but simply looking at such devices in a TEM produces defects in their atomic structure and damages their sensitivity. The Penn team got around this problem by taking a quick scan of the of ribbons, producing a highly pixelated image that didn't damage the ribbons and gave enough detail for the researchers to pick the spot they wanted to drill. view more 

Credit: University of Pennsylvania

The instructions for building all of the body's proteins are contained in a person's DNA, a string of chemicals that, if unwound and strung end to end, would form a sentence 3 billion letters long. Each person's sentence is unique, so learning how to read gene sequences as quickly and inexpensively as possible could pave the way to countless personalized medical applications.

Researchers at the University of Pennsylvania have now made an advance towards realizing a new sequencing technique based on threading that string through a tiny hole and using a nearby sensor to read each letter as it passes through.

Their DNA sensor is based on graphene, an atomically thin lattice of carbon. Earlier versions of the technique only made use of graphene's unbeatable thinness, but the Penn team's research shows how the Nobel Prize-winning material's unique electrical properties may be employed to make faster and more sensitive sequencing devices.

Critically, the team's latest study shows how to drill these nanopores without ruining graphene's electrical sensitivity, a risk posed by simply looking at the material through an electron microscope.

The team includes Marija Drndić, professor of physics in the School of Arts and Sciences, and members in her laboratory, including graduate student Matthew Puster and postdoctoral researchers Julio Rodríguez-Manzo and Adrian Balan.

Their research was published in the journal ACS Nano.

Drndić's group has previously demonstrated a series of advancements towards reading genes by passing them through a tiny hole, or nanopore. Their 2010 study involved drilling a hole in a sheet of graphene, then putting it in an ionic bath along with the strands of DNA to be detected. Because each of the four bases, the letters in DNA's alphabet, have a different size, a different number of ions would be expected to squeeze through along with each base as the strand passes through the pore. Researchers could then interpret the sequence of the DNA's bases by measuring the electrical signal of the ions. However, those current signals are weak, limiting the speed at which DNA could be sequenced.

Many research groups are now exploring multiple ways to improve the sensitivity and speed of the technique, including new materials and new ways of fashioning nanopores in them. Drndić's group has experimented with different membranes, as well as adding improved electronics to measure at faster speeds, but its latest study represents an entirely new way of generating an electrical signal unique to each base.

"Our latest attempt at improving the technique is a departure from our previous work, however," Drndić said. "We're now trying to measure current directly from the graphene, whereas before we measured ionic current in the solution as it goes through the pore."

The Penn team wanted to see if nanopores in graphene, the most conductive material known, would be capable of sensing the difference between bases directly. Instead of their different sizes, this method would rely on the bases altering the electric charge in the nearby material. In this case, the material would be a thin, wire-like ribbon of graphene. As each base passes through the pore, it would modulate the electrical current flowing through the ribbon. The changes in current would then be matched to their corresponding bases, allowing the researchers to decipher the sequence.

"The advantage," Balan said, "over the ionic method is that the current in the graphene ribbon is a thousand times higher. That means we can measure a thousand times faster. We wouldn't need to slow down the DNA to make an accurate measurement of each base."

After fabricating the graphene ribbons on a silicon nitride membrane and attaching metal contacts, the researchers wired them to measure their resistance and then put them in a transmission electron microscope, or TEM. This type of microscope uses a broad beam of electrons to produce images with nanoscale resolution by measuring the electrons as they pass through the sample, but it can also be used like a drill by focusing the beam.

The researchers had used a TEM to drill nanopores in sheets of graphene for their earlier sequencing experiments but encountered an unexpected challenge this time. When they put their ribbons in the TEM, they found resistances significantly increased, limiting sensitivity.

"Just looking at the graphene ribbons with the TEM caused them to degrade," Drndić said. "The wide beam we use for imaging was damaging them by introducing defects in the pattern of carbon atoms. It was almost not graphene any more."

"It didn't matter in our earlier experiments," Puster said, "since we were just using the graphene for its thinness and mechanical properties. We were creating these defects and raising the resistance, but we didn't realize it because we weren't measuring the graphene's electrical properties."

But with graphene's ultra-low resistance key to their proposed sequencing device, the team was presented with a quandary; they needed to poke a hole in a precise spot on a ribbon 10,000 times thinner than a human hair while effectively blindfolded.

"This was a real roadblock," Drndić said. "How were we going to drill these pores when just looking at the ribbon kills the device?"

The team's solution was to use a different imaging mode in the TEM, which produced a rough scan rather than high-definition picture.

"Instead of opening up the beam valve and flooding the ribbon with electrons," Rodríguez-Manzo said, "we use a scanning mode that just takes one snapshot. By taking the fuzziest picture that still tells us where the edge of the ribbon is, we limit the amount of electrons that hit it."

"The image we get back is very pixelated," Puster said. "But then we just need to pick the pixel where we want to put the pore or notch."

The team simultaneously measured the ribbons' resistances as they took these snapshots, clearly showing that they remained undamaged throughout the process. They also simulated the presence of a strand of DNA by using an electric field to test that the device would be sensitive enough to conduct DNA experiments with.

"I think this may solve problems for a lot of different nanosensors," Drndić said. "Whether they're made of graphene, nanowires, carbon nanotubes or other nanostructures, this will help keep them in working order while in a TEM. The main trick here is to drill the nanopore with as little imaging as possible, just taking a quick peek out from under the blindfold."

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Their research was supported by the National Science Foundation and the National Institutes of Health.


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