Squid, what is it good for? You can eat it and you can make ink or dye
from it, and now a Penn State team of researchers is using it to make a
thermoplastic that can be used in 3-D printing.
"Most of the companies looking into this type of material have
focused on synthetic plastics," said Melik C. Demirel, professor of
engineering science and mechanics. "Synthetic plastics are not rapidly
deployable for field applications, and more importantly, they are not
eco-friendly."
Demirel and his team looked at the protein complex that exists in the
squid ring teeth (SRT). The naturally made material is a thermoplastic,
but obtaining it requires a large amount of effort and many squid.
"We have the genetic sequence for six squid collected around the
world, but we started with the European common squid," said Demirel, who
with his team collected the cephalopods.
The researchers looked at the genetic sequence for the protein
complex molecule and tried synthesizing a variety of proteins from the
complex. Some were not thermoplastics, but others show stable thermal
response, for example, the smallest known molecular weight SRT protein
was a thermoplastic. The results of their work were published in today's
(Dec. 17) issue of Advanced Functional Materials and illustrates the cover.
Most plastics are currently manufactured from fossil fuel sources
like crude oil. Some high-end plastics are made from synthetic oils.
Thermoplastics are polymer materials that can melt, be formed and then
solidify as the same material without degrading materials properties.
This particular thermoplastic can be fabricated either as a
thermoplastic, heated and extruded or molded, or the plastic can be
dissolved in a simple solvent like acetic acid and used in film casting.
The material can also be used in 3D printing machines as the source
material to create complicated geometric structures.
To manufacture this small, synthetic SRT molecule, the researchers
used recombinant techniques. They inserted SRT protein genes into E.
coli, so that this common, harmless bacteria could produce the plastic
molecules as part of their normal activity and the thermoplastic was
then removed from the media where the E. coli lived. Wayne Curtis,
professor of chemical engineering and Demirel collaborating on this
project together with their students worked on this aspect of the
project.
"The next generation of materials will be governed by molecular
composition -- sequence, structure and properties," said Demirel.
The thermoplastic the researchers created is semi-crystalline and can
be rigid or soft. It has a very high tensile strength and is a wet
adhesive; it will stick to things even if it is wet.
This thermoplastic protein has a variety of tunable properties, which
can be adjusted to individual requirements of manufacturing. Because it
is a protein, it can be used for medical or cosmetic applications.
"Direct extraction or recombinant expression of protein based
thermoplastics opens up new avenues for materials fabrication and
synthesis, which will eventually be competitive with the high-end
synthetic oil based plastics," the researchers report.
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