A tree grows strong from years of generating its own food. Now imagine if products could be strengthened with the same living materials that provide nutrients to strengthen trees. This is the work of USC Viterbi School of Engineering Civil and Environmental Engineering Professor Qiming Wang whose research lab is one of the first to infuse 3-D printer ink with living material. The material has potential for greater strength, to be flexible and self-heal.
The idea for this bio-inspired ink came from trees that harness the power of photosynthesis to produce glucose that transform to cellulose and strengthen the plant’s cell structure. “When trees are young,” says Wang, “they are flexible, when they are mature, they are rigid.”
“The research idea is also inspired by Popeye the Sailor, the animated character who can strengthen his muscles by eating spinach,” says Wang, whose research is focused on bioinspired manufacturing and mechanics of unprecedented materials and structures that can potentially address engineering challenges in infrastructure, energy, robotics, healthcare and the environment.
“Now, we are using scientific innovation to realize our childhood imagination,” says Wang.
The research team behind this study, which includes USC Viterbi Ph.D. students Kunhao Yu and Zhangzhengrong Feng as lead authors along with Professor Nicholas X. Fang of Massachusetts Institute of Technology and Professor Chiara Daraio of California Institute of Technology, used a centrifuge to extract chloroplasts from spinach purchased from Trader Joe’s. They blended the spinach chloroplasts with a newly invented 3D-printable polymer ink. Then they used the ink to 3D-print structures. By applying light to the 3-printed structure, they created conditions to generate plant-based glucose which reacts with the polymer to make the material become stronger and stronger.
By applying two to four hours of light and mimicking the power of photosynthesis, the researchers believe this “living material” can self-strengthen to be six times its original strength. What’s more, the strengthening effect induced by the living chloroplasts can be temporarily suspended by freezing the material at 0℃ (the chloroplasts are temporarily slowed down at freezing). Once the temperature returns to room temperature, the strengthening effect can be resumed.
“The material behaves like a snake that hibernates through the winter,” Wang says.
“Such a temporary ‘suspending behavior’ has never been demonstrated in existing engineering materials,” Wang adds.
Yu, a lead author on the paper notes, “This technology with gradient light illumination can create engineering structures with gradient stiffness, which exhibit an exceptional ‘cushioning’ property far beyond that of the homogeneous ones.
“Another striking finding is that the strengthening effect can be tuned by external force,” said Feng, the paper’s other lead author.
“When you hang a weight on a tree branch, that branch will become much stronger than other branches, a process called “mechanotransduction.” The same phenomenon happens here.
The team envisions applying photosynthesis to materials to design a custom 3D-printed sneaker sole that molds to one’s foot and has a customized stiffness.
Some plants exhibit a self-healing capability during grafting and wound repairing. According to the researchers, the “living material”infused with chloroplasts in a lab at USC also presents an outstanding self-repairing property. Such a property is induced by the photosynthesis-produced glucose that creates the molecular process of cross-linking (in essence equivalent to creating sutures). Such crack-repairing capability could be applied in boat propellers or even drones.
Above: Video illustrates the photosynthesis-assisted healing of a dumbbell-shaped sample. The sample was 3D-printed with a polymer ink with free NCO groups and 5 wt% embedded chloroplasts. Then, the sample was cut into two parts with a blade, followed by being brought into contact under 4-h light illumination and 4-h darkness. Then the healed sample was stretched by two twisters.
Above: Video illustrates the comparison of 3D-printed experimental and control propellers in healing fractures in their structures. In the first part, a 3D-print propeller with the experimental polymer ink with free NCO groups and 5 wt% embedded chloroplasts was damaged by making cracks in its sectors. The sector cracks were healed by a photosynthesis process with 4-h illumination and 4-h darkness. The healed propeller that was assembled on a remotely controlled boat could facilitate the forward movement of the boat. In the second part, a 3D-print propeller with the control polymer ink with free NCO groups but without embedded chloroplasts was damaged by making cracks on its sectors. The sector cracks could not be healed by a photosynthesis process with 4-h illumination and 4-h darkness. The unhealed propeller that was assembled on a remotely controlled boat could not facilitate the forward movement of the boat.
Publication: Proceedings of the National Academy of Sciences (2021)
Photosynthesis-assisted remodeling of three-dimensional printed structures
https://www.pnas.org/content/118/3/e2016524118
Source: University of Southern California
Even machines need their greens
https://phys.org/news/2021-01-machines-greens.html
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