In a world-first, researchers at the University of Auckland have demonstrated how to 3D print a ‘living’ resin, a novel
technique that enables the creation of ‘living’ and ‘self-repairing’ plastics, and could be a game changer in medical
implants and the recycling of plastics.
By ‘living’ resin the researchers mean a 3D printable material which can change its properties after it has been
produced; which includes the ability to ‘grow’ in size and mass, as well as ‘self-repair’ when damaged, which adds a new
dimension to the existing 3D printing process.
Honours students Chris Bainbridge, Kyle Engel and third-year undergraduate Briony Daley, under the supervision of Dr
Jianyong Jin and Dr Ali Bagheri of the School of Chemical Sciences from the Faculty of Science, accomplished a
world-first by producing an example of ‘living’ 3D printing using a technique known as RAFT (reversible addition
fragmentation chain transfer) polymerisation.
In 2018, the team came up with the idea of applying the RAFT technique to 3D printing and carried out research to
perfect the process, dubbing the project “THING” named after the 1982 movie.
“If 3D printing, often called additive manufacturing, is the new frontier of the fourth industrial revolution, this new
technique is at the forefront of that frontier.”, Dr Jin said.
3D printing is commonly done with polymerisation process in an uncontrolled fashion. The technique advances 3D printing
in two main ways with the big breakthrough being that the RAFT technique used produced objects that Dr Jin calls
‘dormant’. Traditionally 3D printing produces inert objects that cannot change. RAFT technique objects can 'grow',
'self-repair', and can insert new compounds to alter their properties. The novel technique, in effect, enables the
printing of 3D objects with the ability to transform after production. Additionally, traditional 3D printed objects are
‘cured’ or set with ultraviolet light.
Dr Ali Bagheri said this new technique pushes to use visible light, such as green and red, which requires less energy
and is safer. This potentially opens new opportunities in biomedical applications where it is not safe to use harmful UV
light.
Kyle gives a not entirely fanciful example. Shoes 3D printed with this technique, could be programmed to grow with the
wearer. Self-repairing plastic offers the potential to reduce plastic waste, the cost and time to recycle which often
means breaking down plastic objects into raw material for reuse. Chris said he is fascinated with this invention and
they are both eager to explore the sensing and soft robotics applications during their PhD studies.
The researchers demonstrated the technique by producing the word RAFT as a yellow 3D printed object, and then exposing
it to a growth medium. The recipe for the medium contained fluorescent compounds that were bound to the printed RAFT
word such that it began to ‘grow’ and glow blue.
The team’s seminal paper was submitted for publication to the Royal Society of Chemistry ‘s flagship polymer journal
“Polymer Chemistry” on 20 September, 2019 and was accepted for publication on 4 November, 2019 (DOI: 10.1039/C9PY01419E).
The University of Auckland team collaborated with researchers from the University of New South Wales and University of
Melbourne, and acknowledge support from the Endeavour Fund administered by the Ministry of Business, Innovation and
Employment.