Microtubes create cozy space for neurons to grow, and grow fast
Liz Ahlberg, U. of I. News Bureau
- Neurons grow in the cozy, soft, three-dimensional environment of the brain, and a team co-led by Xiuling Li has figured out how to recreate those conditions to study neuron growth.
- The team does this by using an array of silicon nitride microtubes about as wide as a neuron, and neurons grow along and inside the tubes.
- Learning more about how neurons grow could eventually help scientists understand how diseases can start forming in brain cells, and possibly help them find ways to remedy them.
Tiny, thin microtubes could provide a scaffold for neuron cultures to grow so that researchers can study neural networks, their growth and repair, yielding insights into treatment for degenerative neurological conditions or restoring nerve connections after injury.
Researchers at the University of Illinois at Urbana-Champaign and the University of Wisconsin-Madison created the microtube platform to study neuron growth. They posit that the microtubes could one day be implanted like stents to promote neuron regrowth at injury sites or to treat disease.
“This is a powerful three-dimensional platform for neuron culture,” said Xiuling Li, the ECE professor who co-led the study along with UW-Madison Professor Justin Williams. “We can guide, accelerate and measure the process of neuron growth, all at once.”
The team published the results in the journal ACS Nano.
“There are a lot of diseases that are very difficult to figure out the mechanisms of in the body, so people grow cultures on platforms so we can see the dynamics under a microscope,” said ECE graduate student Paul Froeter, the first author of the study. “If we can see what’s happening, hopefully we can figure out the cause of the deficiency and remedy it, and later integrate that into the body.”
The biggest challenge facing researchers trying to culture neurons for study is that it’s very difficult to recreate the cozy, soft, three-dimensional environment of the brain. Other techniques have used glass plates or channels carved into hard slabs of material, but the nerve cells look and behave differently than they would in the body. The microtubes provide a three-dimensional, pliant scaffolding, the way that the cellular matrix does in the body.
The team uses an array of microtubes, made with a technique pioneered in Li’s lab for electronics applications such as 3-D inductors. Very thin membranes of silicon nitride roll themselves up into tubes of precise dimensions. The tubes are about as wide as the cells, as long as a human hair is wide, and spaced apart about as far as they are long. The neurons grow along and through the microtubes, sending out exploratory arms across the gaps to find the next tube.
See a YouTube video of a neuron growing from tube to tube.
“Having the ability to see through both the tube and the underlying substrate has been really enlightening,” said Williams, a professor of biomedical engineering at UW-Madison. “Without this we may have noticed an overall increase in growth rates, but we never would have observed the dramatic changes that occur as the cells transition from the flat regions to the tube inlets.”
The microtubes not only provide structure for the neural network, guiding connections, but also accelerate the nerve cells’ growth – and time is crucial for restoring severed connections in the case of spinal cord injury or limb reattachment.
Because they are so thin, the microtubes are flexible enough to wrap around the cells without damaging or flattening them. The researchers found that the axons, the long branches the nerve cells send out to make connections, grow through the microtubes like a sheath – and at up to 20 times the speed of growing across the gaps.
“It’s not surprising that the axons like to grow within the tubes,” Williams said. “These are exactly the types of spaces where they grow in vivo. What was really surprising was how much faster they grew. This now gives us a powerful investigative tool as we look to further optimize tube structure and geometry.”
The microtube arrays can be tuned to any dimensions needed, since nerve cells vary greatly in size from small brain cells to large muscle-controlling nerves. Li and Froeter have already sent microtube arrays of various dimensions to other research groups studying neural networks for diverse applications.
“If we place electrodes inside the tube, since they are directly in contact with the axon, we will be able to study signal conduction much better than conventional methods,” Li said.
They also are working to stack the microtubes in multiple layers so that bundles of nerves can grow in a 3-D network.
“If we can grow lines of neurons together in a bundle, we could simulate what’s going down your spine or going to your limbs,” Froeter said. “Then we can take mature cultures and sever them, then introduce the microtubes and see how they regrow.”
“Getting to the clinic will take a long time, but that is what keeps us motivated,” Li said.
ECE's Andrew T. Yang Research Award, the National Science Foundation, and the National Institutes of Health supported this work. Li also is affiliated with the Micro and Nanotechnology Laboratory, the Frederick Seitz Materials Research Laboratory, the department of mechanical science and engineering and the Beckman Institute at Illinois. Other Illinois authors included bioengineering and cell and developmental biology professor Martha Gillette and graduate students Olivia Cangellaris and Wen Huang. Wisconsin postdoctoral researcher Yu Huang was a co-first author.