April 4, 2013

Oxford University scientists have developed a custom-built programmable 3D printer that can create materials with several of the properties of living tissues.

The new type of material consists of thousands of connected water droplets that are encapsulated within lipid films, which can perform some of the functions of the cells inside our bodies.

Scientists say these printed 'droplet networks' could be the building blocks of a new kind of technology for delivering drugs to places where they are needed, or potentially one day replacing or interfacing with damaged human tissues.

"We aren't trying to make materials that faithfully resemble tissues but rather structures that can carry out the functions of tissues," said Professor Hagan Bayley of Oxford University's Department of Chemistry, who led the research.

"We've shown that it is possible to create networks of tens of thousands connected droplets. The droplets can be printed with protein pores to form pathways through the network that mimic nerves and are able to transmit electrical signals from one side of a network to the other."

Droplet network c.500 microns across with electrically conductive pathway between electrodes mimicking nerve.

(Credit: Oxford University/G Villar)

Researcher say that the tissues from their 3D printer are entirely synthetic, have no genome and do not replicate. And they could avoid some of the problems associated with other approaches to creating artificial tissues -- such as those that use stem cells.

Each droplet is an aqueous compartment about 50 microns in diameter. Although this is around five times larger than living cells the researchers believe there is no reason why they could not be made smaller.

Droplet network that has self-folded into a hollow ball c.400 microns across

The 3D printer was built by Gabriel Villar, a DPhil student in Professor Bayley's group and the lead author of the paper.

"We have created a scalable way of producing a new type of soft material. The printed structures could in principle employ much of the biological machinery that enables the sophisticated behaviour of living cells and tissues." Villar said.

The droplet networks remain stable for weeks and can be designed to fold themselves into different shapes after printing -- so, for example, a flat shape that resembles the petals of a flower is 'programmed' to fold itself into a hollow ball, which cannot be obtained by direct printing.

The folding, which resembles muscle movement, is powered by osmolarity differences that generate water transfer between droplets.

"Conventional 3D printers aren't up to the job of creating these droplet networks, so we custom built one in our Oxford lab to do it," said Professor Bayley.

"At the moment we've created networks of up to 35,000 droplets but the size of network we can make is really only limited by time and money. For our experiments we used two different types of droplet, but there's no reason why you couldn't use 50 or more different kinds."

 

 

Posted in 3D Printing Applications

 

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