A platform for single-molecule measurement of binding kinetics & enzyme activity.
The first molecular electronics chip has been developed, realizing a 50-year-old goal of integrating single molecules into circuits to achieve the ultimate scaling limits of Moore’s Law. Developed by Roswell Biotechnologies and a multi-disciplinary team of leading academic scientists, the chip uses single molecules as universal sensor elements in a circuit to create a programmable biosensor with real-time, single-molecule sensitivity and unlimited scalability in sensor pixel density. This innovation, appearing this week in a peer-reviewed article in the Proceedings of the National Academy of Sciences (PNAS), will power advances in diverse fields that are fundamentally based on observing molecular interactions, including drug discovery, diagnostics,
The molecular electronics platform consists of a programmable semiconductor chip with a scalable sensor array architecture. Each array element consists of an electrical current meter that monitors the current flowing through a precision-engineered molecular wire, assembled to span nanoelectrodes that couple it directly into the circuit. The sensor is programmed by attaching the desired probe molecule to the molecular wire, via a central, engineered conjugation site. The observed current provides a direct, real-time electronic readout of molecular interactions of the probe. These picoamp-scale current-versus-time measurements are read out from the sensor array in digital form, at a rate of 1000 frames per second, to capture molecular interactions data with high resolution, precision and throughput.
“The goal of this work is to put biosensing on an ideal technology foundation for the future of precision medicine and personal wellness,” added Roswell co-Founder and Chief Scientific Officer Barry Merriman, PhD, the senior author of the paper. “This requires not only putting biosensing on chip, but in the right way, with the right kind of sensor. We’ve pre-shrunk the sensor element to the molecular level to create a biosensor platform that combines an entirely new kind of real-time, single-molecule measurement with a long-term, unlimited scaling roadmap for smaller, faster and cheaper tests and instruments.”
The new molecular electronics platform detects multi-omic molecular interactions at the single-molecule scale, in real-time. The PNAS paper presents a wide array of probe molecules, including DNA, aptamers, antibodies, and antigens, as well as the activity of enzymes relevant to diagnostics and sequencing, including a CRISPR Cas enzyme binding its target DNA. It illustrates a wide range of applications for such probes, including the potential for rapid COVID testing, drug discovery, and proteomics.
The paper also presents a molecular electronics sensor capable of reading DNA sequence. In this sensor, a DNA polymerase, the enzyme that copies DNA, is integrated into the circuit, and the result is direct electrical observation of the action of this enzyme as it copies a piece of DNA, letter by letter. Unlike other sequencing technologies that rely on indirect measures of polymerase activity, this approach achieves direct, real-time observation of a DNA polymerase enzyme incorporating nucleotides. The paper illustrates how these activity signals can be analyzed with machine learning algorithms to allow reading of the sequence.
“The Roswell sequencing sensor provides a new, direct view of polymerase activity, with the potential to advance sequencing technology by additional orders of magnitude in speed and cost,” said Professor George Church, a co-author of the paper, member of the National Academy of Sciences, and a Roswell Scientific Advisory Board member. “This ultra scalable chip opens up the possibility for highly distributed sequencing for personal health or environmental monitoring, and for future ultra-high throughput applications such as Exabyte-scale DNA data storage.”
Reference: “Molecular electronics sensors on a scalable semiconductor chip: A platform for single-molecule measurement of binding kinetics and enzyme activity” by Carl W. Fuller, Pius S. Padayatti, Hadi Abderrahim, Lisa Adamiak, Nolan Alagar, Nagaraj Ananthapadmanabhan, Jihye Baek, Sarat Chinni, Chulmin Choi, Kevin J. Delaney, Rich Dubielzig, Julie Frkanec, Chris Garcia, Calvin Gardner, Daniel Gebhardt, Tim Geiser, Zachariah Gutierrez, Drew A. Hall, Andrew P. Hodges, Guangyuan Hou, Sonal Jain, Teresa Jones, Raymond Lobaton, Zsolt Majzik, Allen Marte, Prateek Mohan, Paul Mola II, Paul Mudondo, James Mullinix, Thuan Nguyen, Frederick Ollinger, Sarah Orr, Yuxuan Ouyang, Paul Pan, Namseok Park, David Porras, Keshav Prabhu, Cassandra Reese, Travers Ruel, Trevor Sauerbrey, Jaymie R. Sawyer, Prem Sinha, Jacky Tu, A. G. Venkatesh, Sushmitha VijayKumar, Le Zheng, Sungho Jin, James M. Tour, George M. Church, Paul W. Mola and Barry Merriman, 24 January 2022, Proceedings of the National Academy of Sciences.DOI: 10.1073/pnas.2112812119
About Roswell Biotechnologies
Roswell Biotechnologies is digitizing biology with molecular electronics to predict, prevent, and cure disease. The company has developed the world’s first molecular electronics chip, the Roswell ME Chip™, which integrates single-molecules into standard semiconductor chip technology to deliver a programmable biosensor that converges a broad range of biosensing applications and omics measurements onto one platform. The Roswell ME Platform is being commercialized for applications in drug research and discovery, molecular diagnostics, sequencing, and DNA digital data storage. Roswell Biotechnologies was founded in 2014 by industry leaders in genomic technologies and is headquartered in San Diego, California.