×
ADVERTISEMENT
ADVERTISEMENT
ADVERTISEMENT

3-D printing bio-electronic implants

ROBO ID?
Last Updated 29 December 2014, 15:31 IST

Researchers are refining ways to combine electronics with biocompatible materials and even living tissue, which could pave the way for exotic new implants, writes  Katherine Bourzac

A 3-D printer can already make a prototype or spare part out of a metal or polymer. Researchers at Princeton University have now taken an important step toward expanding the technology’s potential by developing a way to print functioning electronic circuitry out of semiconductors and other materials.

They are also refining ways to combine electronics with biocompatible materials and even living tissue, which could pave the way for exotic new implants.

With cartridges full of semi-conductor “inks”, it should be possible to print circuits for all sorts of tasks, said Michael McAlpine, an assistant professor at Princeton, who led the work. To demonstrate the feat, the researchers printed a light-emitting diode within a contact lens.

The processors and display circuitry inside a computer don’t lend themselves to 3-D printing, because they require many complex components fabricated on the nanoscale. But it could be used to make medical devices or implants that incorporate electronics. Researchers might, for example, print a scaffold for growing nerve tissues, McAlpine said.

And if they could also print LEDs and circuits within the scaffold, the light could stimulate the nerves, and the electronics could be used to interface with a prosthetic arm, he suggested.

Last year, McAlpine used 3-D-printing to make a “bioelectronic” ear. The ear was made from living cells, with a supportive matrix of gooey hydrogel; it also had conductive ink, made from a suspension of silver nanoparticles, which formed an electrical coil that could receive radio signals.

Since then, McAlpine’s group has been working to expand 3-D printing to semiconducting materials that would allow a printed device to process incoming sounds.

To broaden the 3-D-printing palette, McAlpine’s group built its own printer; most of the ones on the market today are only designed to print plastic. “If you try to put other stuff in it, it will jam,” he said.

They also needed to be able to print at a higher resolution. The bionic ear, for instance, had features on the millimeter scale — and to make LEDs they had to go to the micrometer sale.

To make the LED, the Princeton researchers chose quantum dots — semiconducting nanoparticles that emit very bright light in response to electrical current. They also used two kinds of metal to make electrical leads and contacts for the devices, as well as polymers and a silicone matrix to hold it all together.

One challenge when printing with so many inks is the risk that they will bleed into each other. So the researchers had to make sure to suspend each material in a solvent that would not mix with any of the others.

McAlpine’s group made a cube of eight green and orange LEDs stacked two-by-two-by-two. The researchers printed the LEDs on a contact lens after scanning it to make the shape of the printed devices match the curvature of the lens surface.

“The LED is just part of the puzzle of 3-D-printing active electronics,” McAlpine said. Once researchers can print active electronic materials, they should be able to make information-processing circuits, sensors, light detectors and other elements — and integrate them with biological tissues, he said.

McAlpine is using the new technique to make customised biomedical devices, some of which are being tested in animal studies. He declined to share the details of the unpublished work, but he added that he’s also started making complex
electronic devices using living cells.
NYT

ADVERTISEMENT
(Published 29 December 2014, 15:31 IST)

Follow us on

ADVERTISEMENT
ADVERTISEMENT