Temp-Controlled 'Nanopores' May Allow Detailed Blood Analysis

Tiny biomolecular chambers called nanopores that can be selectively heated may help doctors diagnose disease more effectively if recent research by a team at the National Institute of Standards and Technology (NIST), Wheaton College, and Virginia Commonwealth University (VCU) proves effective. Though the findings may be years away from application in the clinic, they may one day improve doctors' ability to search the bloodstream quickly for indicators of disease -- a longstanding goal of medical research.

The team has pioneered work on the use of nanopores -- tiny chambers that mimic the ion channels in the membranes of cells -- for the detection and identification of a wide range of molecules, including DNA. Ion channels are the gateways by which the cell admits and expels materials like proteins, ions and nucleic acids. The typical ion channel is so small that only one molecule can fit inside at a time.

Previously, team members inserted a nanopore into an artificial cell membrane, which they placed between two electrodes. With this setup, they could drive individual molecules into the nanopore and trap them there for a few milliseconds, enough to explore some of their physical characteristics.

Then the team expanded their measurement capability by attaching gold nanoparticles to engineered nanopores, which provides another means to discriminate between various molecular species via temperature control. These gold nanoparticles were attached to the nanopore via tethers made from complementary DNA strands. Gold's ability to absorb light and quickly convert its energy to heat that conducts into the adjacent solution allows the team to alter the temperature of the nanopore with a laser at will, dynamically changing the way individual molecules interact with it.