Repairing and reusing plastics and delivering cancer drugs more effectively are only two of many of the potential applications a new 3-D/4-D printing technology might have, thanks to the pioneering work of a research collaboration between UNSW Sydney and The University of Auckland.
The researchers have revealed the successful merging of 3-D/4-D printing and photo-controlled/living polymerization—a chemical process to create polymers—in a paper published in Angewandte Chemie International Edition on Friday.
4-D printing is a subset of 3-D printing where the printed object can transform its shape in response to certain conditions.
The new controlled polymerization method, where the researchers used visible light to create an environmentally friendly "living" plastic or polymer, opens a new world of possibilities for the manufacture of advanced solid materials.
Polymers can be synthetic, such as plastic, as well as biological, for example, DNA.
The research built upon the UNSW Sydney Boyer Lab's 2014 discovery of PET-RAFT polymerization (Photoinduced Electron/energy Transfer-Reversible Addition Fragmentation Chain Transfer polymerization), a new way to make controlled polymers using visible light, using the Reversible Addition Fragmentation Chain Transfer (RAFT) polymerization technique discovered by the CSIRO (Graeme Moad, San Thang and Enzo Rizzard).
Such polymers can be reactivated for further growth, unlike traditional polymers which are "dead" after being made.
Since this development, the technology has expanded and has proven useful for making well-controlled molecules for many applications, including drug delivery and other biomaterials.
Lead author Cyrille Boyer said his team's latest breakthrough was a world first in the development of a new 3-D printing system using PET-RAFT polymerization, to allow 3-D printed materials to be easily modified after printing.
"Controlled polymerization has never been used in 3-D and 4-D printing before, because the rates of typical controlled polymerization processes are too slow for 3-D/4-D printing, where the reaction must be fast for practical printing speeds," Prof Boyer said.
"After two years of research and hundreds of experiments, we developed a rapid process compatible with 3-D printing.
"In contrast to conventional 3-D printing, our new method of using visible light allows us to control the architecture of the polymers and tune the mechanical properties of the materials prepared by our process.
"This new process also gives us access to 4-D printing and allows the material to be transformed or functionalized, which was not previously possible."
UNSW's Nathaniel Corrigan, co-first author with UNSW Ph.D. candidate Zhiheng Zhang, said a bonus advantage of their new system was the ability to finely control all molecules in the 3-D-printed material.
"4-D printing is a subset of 3-D printing. But with 4-D printing, the 3-D-printed object can change its shape and chemical or physical properties and adapt to its environment," Dr. Corrigan said.
"In our work, the 3-D-printed material could reversibly change its shape when it was exposed to water and then dried.
"For example, the 3-D object starts as a flat plane and when exposed to certain conditions, it will start to fold—that's a 4-D material. So, the fourth dimension is time."
From reducing waste to biomedical applications
The researchers are hopeful that their new 3-D/4-D printing process using PET-RAFT polymerization will lead to the production of functional materials to solve many of the problems facing society today.
Prof Boyer said the new method had a multitude of applications for everyday items—particularly if a deformed or broken object needed to be repaired or modified.
"The main application is of course recycling, because instead of using a plastic object once, it can be repaired and reused," he said.
"For ordinary recycling you take the materials away and have to reconstruct them, but for the new 'living' material it will be able to repair itself.
"For example, if you want to put the UNSW logo on a mug, you can modify the surface of the object and grow the polymers to show UNSW because the object is not dead; it's a living object and can continue to grow and expand."
Dr. Corrigan said another major benefit of the new process was its compatibility with biomedicine, because extreme conditions were unnecessary.
"Current 3-D printing approaches are typically limited by the harsh conditions required, such as strong UV light and toxic chemicals, which limits their use in making biomaterials," he said.
"But with the application of PET-RAFT polymerization to 3-D printing, we can produce long polymer molecules using visible light rather than heat, which is the typical polymerization method.
"Using heat above 40 degrees kills cells, but for visible light polymerization we can use room temperature, so the viability of the cells is much higher."
Prof Boyer said objects made through this new process could more easily be used in advanced bio-applications, such as tissue engineering, for example, where a tissue structure is used to form new, viable tissue for medical purposes.
"Our new method targets small scale, niche applications in fields like microelectronics and biomedicine—a huge area for us—that require very advanced polymers," he said.
3-D and 4-D printing for everyone
Prof Boyer said their new technique would allow commercial and non-expert operators to produce materials with seemingly endless properties and applications.
"We want to explore our system to find and address any limitations to allow for better uptake and implementation of this technology," he said.
"There is so much we can do by combining 3-D and 4-D printing with controlled polymerization to make advanced and functional materials for many applications to benefit society."