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John Toon  |  09/20/2010

John Toon’s picture

Bio

New Biosensing Technology Could Facilitate Personalized Medicine

Electronically detect markers that differentiate between healthy and diseased cells

The multiwelled microplate has long been a standard tool in biomedical research and diagnostic laboratories but could become a thing of the past, thanks to new electronic biosensing technology developed by a team of microelectronics engineers and biomedical scientists at the Georgia Institute of Technology.

Essentially arrays of tiny test tubes, microplates have been used for decades to simultaneously test multiple samples for their responses to chemicals, living organisms, or antibodies. Fluorescence or color changes in labels associated with compounds on the plates can signal the presence of particular proteins or gene sequences.

The researchers hope to replace these microplates with modern microelectronics technology, including disposable arrays containing thousands of electronic sensors connected to powerful signal processing circuitry. If they’re successful, this new electronic biosensing platform could help realize the dream of personalized medicine by making possible real-time disease diagnosis—potentially in a physician’s office—and by helping select individualized therapeutic approaches.

Pushing the edge in nanoelectronics technology

“This technology could help facilitate a new era of personalized medicine,” says John McDonald, chief research scientist at the Ovarian Cancer Institute in Atlanta and a professor in the Georgia Tech School of Biology. “A device like this could quickly detect in individuals the gene mutations that are indicative of cancer and then determine what would be the optimal treatment. There are a lot of potential applications for this that cannot be done with current analytical and diagnostic technology.”

The new electronic microplate is shown in front of the technology it aims to replace, the conventional microplate.

Fundamental to the new biosensing system is the ability to electronically detect markers that differentiate between healthy and diseased cells. These markers could be differences in proteins, mutations in DNA, or even specific levels of ions that exist at different amounts in cancer cells. Researchers are finding more differences such as these, which could be exploited to create fast and inexpensive electronic detection techniques that don’t rely on conventional labels.

“We have put together several novel pieces of nanoelectronics technology to create a method for doing things in a very different way than what we have been doing,” says Muhannad Bakir, an associate professor in Georgia Tech’s School of Electrical and Computer Engineering. “What we are creating is a new, general-purpose sensing platform that takes advantage of the best of nanoelectronics and three-dimensional electronic system integration to modernize and add new applications to the old microplate application. This is a marriage of electronics and molecular biology.”

Maintaining usability for researchers

Postdoctoral fellow Kenneth Scarberry uses bioconjugate techniques to bind ligands to silicon nanowires, while graduate research assistant Ramasamy Ravindran observes

The 3-D sensor arrays are fabricated using conventional low-cost, top-down microelectronics technology. Though existing sample preparation and loading systems may have to be modified, the new biosensor arrays should be compatible with existing workflows in research and diagnostic labs.

“We want to make these devices simple to manufacture by taking advantage of all the advances made in microelectronics, while at the same time not significantly changing usability for the clinician or researcher,” says Ramasamy Ravindran, a graduate research assistant in Georgia Tech’s Nanotechnology Research Center and the School of Electrical and Computer Engineering.

A key advantage of the platform is that sensing will be done using low-cost, disposable components, while information processing will be done by reusable conventional integrated circuits connected temporarily to the array. Ultra-high density, spring like, mechanically compliant connectors and advanced “through-silicon vias” will make the electrical connections while allowing technicians to replace the biosensor arrays without damaging the underlying circuitry.

Separating the sensing and processing portions allows fabrication to be optimized for each type of device, notes Hyung Suk Yang, a graduate research assistant also working in the Nanotechnology Research Center. Without the separation, the types of materials and processes that can be used to fabricate the sensors are severely limited.

Potential benefits

The sensitivity of the tiny electronic sensors can often be greater than current systems, potentially allowing diseases to be detected earlier. Because the sample wells will be substantially smaller than those of current microplates—allowing a smaller form factor—they could permit more testing to be done with a given sample volume.

The technology could also facilitate use of ligand-based sensing that recognizes specific genetic sequences in DNA or messenger RNA. “This would very quickly give us an indication of the proteins that are being expressed by that patient, which gives us knowledge of the disease state at the point-of-care,” explains Ken Scarberry, a postdoctoral fellow in McDonald’s lab.

So far, the researchers have demonstrated a biosensing system with silicon nanowire sensors in a 16-well device built on a 1-centimeter × 1-centimeter chip. The nanowires, just 50 nanometers × 70 nanometers, differentiated between ovarian cancer cells and healthy ovarian epithelial cells at a variety of cell densities.

Silicon nanowire sensor technology can be used to simultaneously detect large numbers of different cells and biomaterials without labels. Beyond that versatile technology, the biosensing platform could accommodate a broad range of other sensors—including technologies that may not exist yet. Ultimately, hundreds of thousands of different sensors could be included on each chip, enough to rapidly detect markers for a broad range of diseases.

“Our platform idea is really sensor agnostic,” says Ravindran. “It could be used with a lot of different sensors that people are developing. It would give us an opportunity to bring together a lot of different kinds of sensors in a single chip.”

Genetic mutations can lead to a large number of different disease states that can affect a patient’s response to disease or medication, but current labeled sensing methods are limited in their ability to detect large numbers of different markers simultaneously.

Mapping single nucleotide polymorphisms (SNPs), variations that account for approximately 90 percent of human genetic variation, could be used to determine a patient’s propensity for a disease, or their likelihood of benefiting from a particular intervention. The new biosensing technology could enable caregivers to produce and analyze SNP maps at the point-of-care.

Though many technical challenges remain, the ability to screen for thousands of disease markers in real time has biomedical scientists like McDonald excited.

“With enough sensors in there, you could theoretically put all possible combinations on the array,” McDonald says. “This has not been considered possible until now because making an array large enough to detect them all with current technology is probably not feasible. But with microelectronics technology, you can easily include all the possible combinations, and that changes things.”

Papers describing the biosensing device were presented at the Electronic Components and Technology Conference and the International Interconnect Technology conference in June 2010. The research has been supported in part by the National Nanotechnology Infrastructure Network (NNIN), Georgia Tech’s Integrative BioSystems Institute (IBSI), and the Semiconductor Research Corp.

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About The Author

John Toon’s picture

John Toon

John Toon is manager of the Research News and Publications office and editor of Research Horizons magazine of the Georgia Institute of Technology. He oversees research, economic development, and technology transfer communications for Georgia Tech and its Enterprise Innovation Institute.

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