Schwann cells: left is real; right is a replica, middle is a mold
Dr. Hoffman-Kim and colleagues at Brown University have created a novel molding process to make replicas of real cells. Their two step molding technique has been described in the latest Langmuir. And what would you use plastic fake cells for? Apparently, there are plenty of possible applications:

A description of the replicas, their ability to support cell growth, and their possible applications in science and medicine are published in Langmuir, a journal of the American Chemical Society.
The main cells used in the experiments were Schwann cells, which protect peripheral nerves by wrapping around their axons to create insulating myelin sheaths. Schwann cells also direct axon growth during cell development and repair.
Hoffman-Kim, an assistant professor in the Department of Molecular Pharmacology, Physiology and Biotechnology and the Division of Engineering, said the realistic replicas could be used in laboratories to help scientists understand how these critical support cells sustain and direct nerve growth.
The replicas could also, eventually, be used in hospitals to help doctors regenerate nerves. If a patient’s nerves are severed during an auto accident or other injury, a device coated with the imitation cells — a contraption called a nerve guidance channel — could be implanted into the injured area to help stimulate nerve growth and repair damaged tissue…
But the cell duplication technique could have all sorts of applications. In the Langmuir article, Hoffman-Kim and her team also show results from experiments in which smooth muscle cells were reproduced. Researchers plan to experiment with other cell types.
“What’s exciting about the approach is that it could be broadly applied in both bench science and in tissue engineering,” she said. “Researchers are always trying to get cells to grow well outside the body. A lot of factors affect that growth, like air temperature or the carbon dioxide supply in the lab incubator. Topography, or the surfaces cells grow on, also plays a role.”
Jan Bruder, a graduate student in Brown’s Artificial Organs, Biomaterials and Cellular Technology program, is the lead author of the journal article. With Hoffman-Kim, Bruder came up with the idea for the two-step molding process — one akin to making sculpture.
Cells were grown in the lab then preserved in chemicals for stiffening. Next, researchers poured liquid silicon over the cells and let the mixture harden. Now for the tricky part — peeling the thin, transparent membrane off without tearing it. The result: An impression. To make a relief, which would show shapes rising up from the surface, the pour-and-peel process was repeated.
To see if the cells looked authentic, the team had to pinpoint cells on the original model and find those same cells on the replica. Then, using four kinds of microscopes, they measured the cells’ length and height for comparison. The fakes were the same size — and they looked arrestingly real, right down to tiny bumps in the nucleus. The team then used the replicas to grow neurons taken from rats. The experiments worked.

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