A doughnut created in a lab and made of silk on the outside and collagen gel where the jelly ought to be can mimic the basic function of brain tissue, scientists have found.
Bioengineers produced a kind of rudimentary grey matter and white matter in a dish, along with rat neurons that signalled one another across the doughnut’s centre. When the scientists dropped weights on the material to simulate traumatic injury, the neurons in the three-dimensional brain model emitted chemical and electrical signals similar to those in the brains of injured animals.
It is the first time scientists have been able to so closely imitate brain function in the laboratory, experts said. If researchers can replicate it with human neurons and enhance it to reflect other neurological functions, it could be used for studying how disease, trauma and medical treatments affect the brain —without the expense and ethical challenges of clinical trials on people.
“In terms of mechanical similarity to the brain, it’s a pretty good mimic,” said James J Hickman, a professor of nanoscience technology at the University of Central Florida, who was not involved in the research. “They’ve been able to repeat the highest level of function of neurons. It’s the best model I’ve seen.”
The research, led by David Kaplan, the chairman of the biomedical engineering department at Tufts University, and published in the journal PNAS, is the latest example of biomedical engineering being used to make realistic models of organs such as the heart, lungs and liver.
Most studies of human brain development rely on animals or on slices of brains taken after death; both are useful but have limitations.
Brain models have been mostly two-dimensional or made with neurons grown in a three-dimensional gel, said Rosemarie Hunziker, programme director of tissue engineering and biomaterial at the National Institute of Biomedical Imaging and Bioengineering, which funded Kaplan’s research.
None of those systems replicates the brain’s grey or white matter, or how neurons communicate, Hunziker said.
“Even if you get cells to live in there, they don’t do much,” she said. “It is spectacularly difficult to do this with the brain.”
Kaplan’s team found that a spongy silk material coated with a positively charged polymer could culture rat neurons, a stand-in for grey matter. By itself, though, the silk material did not encourage neurons to produce axons, branches that transmit electrical pulses to other neurons.
The researchers formed the silk material into a doughnut and added collagen gel to the centre. Axons grew from the ring through the gel — the white matter substitute — and sent signals to neurons across the circle.
They got “these neurons talking to each other,” Hunziker said. “No one’s really shown that before.”
Gordana Vunjak-Novakovic, a biomedical engineering professor at Columbia who has collaborated with Kaplan on other studies, described the model as a kind of “Lego approach”, a “modular structure” that can be expanded and made more complex.
“This is not normal tissue, but it is the first proof of a principle that something like this can be achieved outside ofthe body,” she said.
Hickman said future experiments would need to study human brain tissue, including other cells and regions in the brain.
“There are some limitations, but they seem to have gotten the mechanics right,” he said. “They’ve set up an architecture so some clever person in the future could then do it.”
Kaplan said his team was working on sustaining the brainlike tissue for six months — and with human neurons created from stem cells by other scientists. He plans to add a model of the brain’s vascular system, so researchers can study what happens when drugs cross the blood-brain barrier.
Ultimately, he hopes the bioengineered model can be used “to study everything from drugs to disease to surgical effects to electrode implants”, he said. “I mean, the list is endless.”