New Technique Sheds Light on Human Neural Networks
A new technique, developed by researchers in the Quantitative Light Imaging Laboratory at the Beckman Institute, provides a method to noninvasively measure human neural networks in order to characterize how they form.
Using spatial light interference microscopy (SLIM) techniques developed by Gabriel Popescu, director of the lab, the researchers were able to show for the first time how human embryonic stem cell derived neurons within a network grow, organize spatially, and dynamically transport materials to one another.
“Because our method is label-free, we’ve imaged these type of neurons differentiating and maturing from neuron progenitor cells over 12 days without damage,” said Popescu. “I think this (technique) is pretty much the only way you can monitor for such a long time.”
Using time-lapse measurement, the researchers are able to watch the changes over time. “We’ve been looking at the neurons every 10 minutes for 24 hours to see how the spatial organization and mass transport dynamics change,” said Taewoo Kim, one of the lead authors on the paper.
The SLIM technique measures the optical path length shift distribution, or the effective length of the path that light follows through the sample. “The light going through the neuron itself will be in a sense slower than the light going through the media around the neuron,” explains Kim. Accounting for that difference allows the researchers to see cell activity—how the cells are moving, forming neural clusters, and then connecting with other cells within the cluster or with other clusters of cells.
“Individual neurons act like they are getting on Facebook,” explains Popescu. “In our movies you can see how they extend these arms, these processes, and begin forming new connections, establishing a network.” Like many users of Facebook, once some connections have been made, the neurons divert attention from looking for more connections and begin to communicate with one another—exchanging materials and information. According to the researchers, the communication process begins after about 10 hours; for the first 10 hours the studies show that the main neuronal activity is dedicated to creating mass in the form of neural extensions or neurites, which allows them to extend their reach.
“Since SLIM allows us to simultaneously measure several fundamental properties of these neural networks as they form, we were able to for the first time understand and characterize the link between changes that occur across a broad range of different spatial and temporal scales. This is impossible to do with any other existing technology,” explains Mustafa Mir, a lead author on the study.
