From Electrical Brain Maps to Learning More About Migraines
Posted on by Dr. Francis Collins
One of life’s greatest mysteries is the brain’s ability to encode something as complex as human behavior. In an effort to begin to unravel this mystery, neuroscientists often zoom in to record the activities of individual neurons. Sometimes they expand their view to look at a specific region of the brain. But if they zoom out farther, neuroscientists can observe many thousands of neurons across the entire brain firing at once to produce electrical oscillations that somehow translate into behaviors as distinct as a smile and a frown. The complexity is truly daunting.
Rainbo Hultman, University of Iowa Carver College of Medicine, Iowa City, realized years ago that by zooming out and finding a way to map all those emergent signals, she could help to change the study of brain function fundamentally. She also realized doing so offered her an opportunity to chip away at cracking the complicated code of the electrical oscillations that translate into such complex behaviors. To pursue her work in this emerging area of “electrical connectomics,” Hultman recently received a 2020 NIH Director’s New Innovator Award to study the most common human neurological disorder: migraine headaches.
A few years ago, Hultman made some impressive progress in electrical connectomics as a post-doctoral researcher in the lab of Kafui Dzirasa at Duke University, Durham, NC. Hultman and her colleagues refined a way to use electrodes to collect electrical field potentials across an unprecedented seven separate mouse brain regions at once. Using machine learning to help make sense of all the data, they uncovered a dynamic, yet reproducible, electrical brain network encoding depression [1].
What’s more, they found that the specific features of this brain-wide network could predict which mice subjected to chronic stress would develop signs of major depressive disorder. As Hultman noted, when measured and mapped in this way, the broad patterns of electrical brain activity, or “Electome factors,” could indicate which mice were vulnerable to stress and which were more resilient.
Moving on to her latest area of research, Hultman is especially intrigued by the fact that people who endure regular migraine attacks often pass through a characteristic sequence of symptoms. These symptoms can include a painful headache on one side of the head; visual disturbances; sensitivity to light, odors, or sound; mood changes; nausea; trouble speaking; and sometimes even paralysis. By studying the broad electrical patterns and networks associated with migraine in mice—simultaneously capturing electrical recordings from 14 brain regions on a millisecond timescale—she wants to understand how brain circuits are linked and work together in ways that produce the complex sequences of migraine symptoms.
More broadly, Hultman wants to understand how migraine and many other disorders affecting the brain lead to a state of heightened sensory sensitivity and how that emerges from integrated neural circuits in the brain. In her studies of migraine, the researcher suspects she might observe some of the same patterns seen earlier in depression. In fact, her team is setting up its experiments to ensure it can identify any brain network features that are shared across important disease states.
By the way, I happen to be one of many people who suffer from migraines, although fortunately not very often in my case. The visual aura of flashing jagged images that starts in the center of my visual field and then gradually moves to the periphery over about 20 minutes is pretty dramatic—a free light show! I’ve wondered what the electrical component of that must be like. But, even with treatment, the headache that follows can be pretty intense.
Hultman also has seen in her own life and family how debilitating migraines can be. Her goal isn’t just to map these neural networks, but to use them to identify where to target future therapeutics. Ultimately, she hopes her work will pave the way for more precise approaches for treating migraine and other brain disorders that are based on the emergent electrical characteristics of each individual’s brain activity. It’s a fascinating proposition, and I certainly look forward to where this research leads and what it may reveal about the fundamentals of how our brains encode complex behaviors and emotions.
Reference:
[1] Brain-wide electrical spatiotemporal dynamics encode depression vulnerability. Hultman R, Ulrich K, Sachs BD, Blount C, Carlson DE, Ndubuizu N, Bagot RC, Parise EM, Vu MT, Gallagher NM, Wang J, Silva AJ, Deisseroth K, Mague SD, Caron MG, Nestler EJ, Carin L, Dzirasa K. Cell. 2018 Mar 22;173(1):166-180.e14.
Links:
Migraine Information Page (National Institute of Neurological Disorders and Stroke/NIH)
Laboratory for Brain-Network Based Molecular Medicine (University of Iowa, Iowa City)
Hultman Project Information (NIH RePORTER)
NIH Director’s New Innovator Award (Common Fund)
NIH Support: Common Fund; National Institute of Mental Health
Electrical activity of the brain in modulating behavior brings up the topic of other modalities in use such as acupuncture. What is known about the science of how these needle placements can effect pain, depression, insomnia? Also brings up a practice used by monks called tummo which can control sensory input.
So much of science is dictated by curiosity and serendipity, however, much of how one chooses to define observations, hypothesis driven or otherwise, is usually dictated by the biases of the scientist as well. NIH, obviously is well aware of the effects of diversity in scientific thinking in terms of supporting the Fogarty Fellowship.
I was searching for a proper explanation about Migraine Thanks for sharing such wonderful content on this topic . . .
Hello, thank you so much for sharing this informative article about electrical brain and migraines. This is really interesting to read about everything migraines.
We should be able to ingest metamaterials to lens MRI magnetic fields for medical imaging. Now, new materials are being developed which are used as structural scaffolding between MRI magnets and the body to yield mildly sharper images. If we were to admit nanotechnology crystals or metals that act to lens a certain area; to track the progress of an Alzheimer’s treatment, or to image a tumour while it is just starting to become more dense than surrounding tissue, many early stage techniques could be prototyped. A sphere, cylinder or cross (for quadrature) of the particles in our blood would be centered around the tissue of interest (and throughout other volumes of the body to be ignored). The crystals would have the ability to minutely alter their geometries in real-time to keep the magnetic field focus to cubic millimeters or microns. Their constituent atoms and metabolic molecules all the way to the complexity of the ingested nanotechnology, would need to be safe to consume or as safe as are existing radical treatments. As the particle circulates in the blood it alters its angle to keep the focus on the emergent tumour or neuro-ailment of interest. With electricity, there is sweat and tics and body movement.
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