Most existing bioprinting techniques depend on scaffolding, which is solution made from biomaterials such as collagen or hydrogel. The solution is required to hold together the seed cells that will be grown into tissues or organs. With the Kenzan method, no scaffolding is needed. “Kenzan” is Japanese for “needle array,” and an array of needles form the basis of the process. Cyfuse’s Regenova bioprinter works by gathering cell aggregates, or spheroids, onto a series of needles in a pattern predetermined by 3D software. The needles are so close together that the cells they hold will fuse together into solid, firm tissue when placed in a bioreactor.
Cyfuse began marketing the Regenova printer not long ago, and now a new partnership with San Diego-based Cell Applications, Inc. will make tissue produced by the Kenzan method available to North American researchers – the first time the Regenova printer will be used outside of Japan.
“The Regenova 3D Bio Printer, combined with Cell Applications’ comprehensive, high-quality primary cell bank, offers researchers streamlined access to a nearly limitless selection of three dimensional tissues including those mimicking blood vessels, human neural tissue and liver constructs,” said Koji Kuchiishi, CEO of Cyfuse Biomedical. “The collective strengths of both our companies will serve the growing demand for viable engineered tissues and accelerate scientific discovery in North America, taking us one step closer to making regenerative medicine a reality.”
“In addition to customized cell isolation and assay services, Cell Applications is now able to provide researchers with an integrated cell-engineering solution that utilizes our expansive primary cell bank and the innovative Kenzan bioprinting method,” said James Yu, founder and CEO of Cell Applications. “Having the Regenova 3D Bio Printer at our San Diego headquarters with our vast array of primary cells is a powerful combination. We’re very pleased to offer researchers an end-to-end, customized solution for creating scaffold-free, 3D-engineered tissues that reduce costs by minimizing the lengthy processes typical in pharmaceutical drug discovery.”
So far, academic research institutions have been using the Kenzan method to print nerves, blood vessels, and liver-like tissue. The potential future applications of the technique are numerous – pancreatic islets, cardiac muscles, and production of skin, spinal cord, and other types of tissues for drug screening. And, like all other bioprinting organizations, Cyfuse hopes that their technology will eventually lead to the printing and regeneration of entire, functional human organs. Discuss this latest news in the Cyfuse 3D Bioprinter forum over at 3DPB.com.