Researchers in Texas have come up with a new method that allows them to insert tiny, flexible electrodes into the brain, reducing inadvertent damage. Just trying to push the electrodes into brain tissue doesn't work -- they buckle and can't get into the tissue. These researchers instead placed the electrodes inside small tubes and surrounded them with a viscous fluid. When the fluid was quickly pushed through the device, it pulled the electrode along with it and with enough force for the electrode to penetrate millimeters deep into tissue on its own.

"The electrode is like a cooked noodle that you're trying to put into a bowl of Jello," Jacob Robinson, a Rice University researcher on the project said in a statement. "By itself, it doesn't work. But if you put that noodle under running water, the water pulls the noodle straight." And the team pointed out that with flexible items, it's easier to pull them than push them. "That's why trains are pulled, not pushed," said Rice University chemist Matteo Pasquali. And because it surrounds the electrode, the fluid's pull is distributed all along the electrode, preventing it from buckling when it hits the tissue.

The team showed that their device could successfully insert a flexible electrode into a gel, a small, squishy, water-dwelling organism called a Hydra, slices of mouse brain and living rats' brains. In the Hydra, brain slices and rat brains, the researchers were able to record neuronal activity with the electrode.

This method could be very useful for scientists studying the brain and the researchers say it has the potential to be used in treatment applications that use electrodes to manage certain conditions like epilepsy or allow people to control artificial limbs.

The research was recently published in ACS Nano Letters. You can check out the fluidic microdrive in action in the video below.