91av

Stretchy chips to monitor the brain

The first flexible silicon microchips could be used in seizure-detection circuitry attached to the brain
Stretchy chips to monitor the brain

BENDY, stretchable computer chips have been made that could one day allow gadgets to be integrated with clothing, or even take electronics to the surface of the human brain.

“We’d like to have an electric circuit that could wrap around part of the brain and detect signal patterns to predict the onset of a seizure before it happens,” says of the University of Illinois, Urbana-Champaign, who led the team that developed the bendy chips.

“For a chip that can wrap around someone’s brain, you need stretchability”

Rogers and colleagues use a stamping technique to transfer ultrathin silicon ribbons, grown at high temperature on glass, to a plastic film. They then add trace amounts of silicon dioxide, silver and chromium to form a network of transistors and interconnecting wires. The entire assembly ends up just 1.5 micrometres thick.

“Making it thin makes it bendable, just as a piece of paper is bendable whereas a piece of wood is not,” Rogers says. Relative to what his team produces, conventional silicon chips are about as flexible as the piece of wood.

To make the chips stretchable, the team binds the silicon-plastic layer to a sheet of rubber that has been stretched by 15 per cent in two dimensions. Once the materials are stuck together, the researchers allow the rubber to snap back to its pre-stretched state. Though this compresses the electronics, it does not damage them and the chips can be stretched out again by the same amount without fracturing, Rogers says (Science, ).

Flexible chips made from semiconducting plastics are also in development, but these aren’t stretchable. For a chip that can be wrapped around someone’s brain you really need stretchability, says Rogers. Silicon has another advantage over plastic: as the standard material in conventional microchips, its properties are well understood.

The stretchy circuits will “fill an important gap, where regular semiconductors cannot go”, says of the University of Wisconsin-Madison, who is also working on stretchable chips.

Topics: Mental health