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Research Team Develops Improved Production Method to Create Synthetic Silk Fibers

NDSU researchers created a patent pending 3-D printed silk spinning device that mimics the natural gland structures of the spider and the silkworm

by North Dakota State University
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April 13, 2018 – Fargo, North Dakota – Nobody does it better than nature, but North Dakota State University researchers are getting a step closer.

Bradley HoffmannBradley Hoffmann, a pharmaceutical sciences graduate research assistant at NDSU.Photo courtesy of North Dakota State UniversityWhile Spider-Man shoots silk from his wrists, real spiders and silkworms have a better way and researchers in the pharmaceutical sciences lab of Dr. Amanda Brooks at NDSU have developed a method to improve the production of synthetic silk fibers.

Results of the research titled “Using hydrodynamic focusing to predictably alter the diameter of synthetic silk fibers” is published in PLOS ONE.

The goal of the research is to ultimately develop synthetic silk fibers to use in a variety of commercial, military and biomedical applications such as infection responsive drug-releasing bubbles, drug-releasing silk fibers, and silk protein to bind heparin and prevent infection.

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Study authors at NDSU include Bradley Hoffmann, a pharmaceutical sciences graduate research assistant from Bismarck, North Dakota and graduate student in mechanical engineering; Catherine Gruat-Henry, formerly in electrical engineering; Pranothi Mulinti, pharmaceutical sciences graduate student; Long Jiang, associate professor of mechanical engineering; Benjamin D. Brooks in mechanical engineering; and Amanda E. Brooks, assistant professor of pharmaceutical sciences.

Spiders use a unique interplay of chemistry, biology, and mechanical shear when they produce silk through glands located at the tip of their abdomen. Their complex natural spinning systems result in strong, consistent strands. Spider silk by weight is estimated to be three times tougher than Kevlar® and five times stronger than steel.

Related Article: Spider-Man Science: Tunable Web Glue and Smart Adhesives

The search for a way to mimic spider silk has led to different systems such as electrospinning, wet-spinning, dry-spinning, and microfluidic spinning. Though each method works, none has produced the strength and elasticity of natural silk fibers.

“Previous systems neglect the shear flow and chemical gradients that spiders’ biological systems possess, so the man-made systems often produce inconsistent or inferior fibers,” said Bradley Hoffmann, lead author of the research.

NDSU researchers created a patent pending 3-D printed silk spinning device that mimics the natural gland structures of the spider and the silkworm.

“We also control the fluid flow through the device, which allows us to even more closely mimic natural silk spinning to produce fibers with smaller diameters and higher strength,” said Hoffmann. “The significance of this research is two-fold and includes applying fluid focusing in silk spinning and producing predictable fiber outputs. The combination of predictability and tailorability allows higher quality engineered silks.”

Using hydrodynamic fluid focusing in unison with a biomimetic spinning system allows NDSU researchers to produce silk fibers with geometry closer to natural fibers.

“This research sets the stage for continued advancement of biomimetic spinning that can provide insight into manufacturing high performance materials for different applications,” said Hoffmann.

Though the research team achieved decreased diameters and higher quality, the strength and elasticity of the synthetic fibers is still not a match for their natural counterpart.

“Future study will focus on integrating chemical stimuli which could increase protein alignment and improve the fiber’s mechanical performance,” said Hoffmann.

Some estimates peg synthetic spider silk to become a multi-billion dollar industry. The research at NDSU was funded by the National Science Foundation award number 1746111, NDSU Department of Mechanical Engineering, ND NASA EPSCoR, and North Dakota Department of Commerce Phase 1 Venture Grant.