Silas Busch at the University of Chicago captured this slightly eerie scene, noting it reminded him of people shuffling through the dark of night. What you’re really seeing are some of the largest neurons in the mammalian brain, known as Purkinje cells. The photo won first place this year in...
Silas Busch at the University of Chicago captured this slightly eerie scene, noting it reminded him of people shuffling through the dark of night. What you’re really seeing are some of the largest neurons in the mammalian brain, known as Purkinje cells. The photo won first place this year in the Brain Research through Advancing Innovative Neurotechnologies® (BRAIN) Initiative’s annual Show Us Your BRAINs! Photo and Video Contest.
While humans have them, too, the Purkinje cells pictured here are in the brain of a mouse. The head-like shapes you see in the image are the so-called soma, or the neurons’ cell bodies. Extending downwards are the heavily branched dendrites, which act like large antennae, receiving thousands of inputs from the rest of the body.
As I transition from my role as the Acting NIH Director, I’d like to thank you, the readers, for visiting the NIH Director’s Blog ever since I took the helm 22 months ago. From Long COVID to the opioid overdose epidemic to Alzheimer’s disease—we’ve covered a range of diseases and conditions, scientific advances, and programs. You were able to read about such a broad spectrum of science thanks in large part to the many Institute Directors at NIH who authored guest posts. I hope the blog has helped you learn more about what NIH does and the many ways that biomedical research impacts human health.
When you get a run-of-the-mill viral infection, after a few days of symptoms your immune system typically fends off the bug, and you’ll make a full recovery. In rare cases, a virus can infect the brain. This can lead to much bigger problems, including cognitive impairments known as “brain fog,” other neuropsychiatric symptoms, potentially irreversible brain damage, or even death. For this reason, the brain, more than other parts of the body, relies heavily on immune responses that can control viral infections immediately.
When NIH launched The BRAIN Initiative® a decade ago, one of many ambitious goals was to develop innovative technologies for profiling single cells to create an open-access reference atlas cataloguing the human brain’s many parts. The ultimate goal wasn’t to produce a single, static reference map, but rather to capture a dynamic view of how the brain’s many cells of varied types are wired to work together in the healthy brain and how this picture may shift in those with neurological and mental health disorders.
So I’m now thrilled to report the publication of an impressive collection of work from hundreds of scientists in the BRAIN Initiative’s Cell Census Network (BICCN), detailed in more than 20 papers in Science, Science Advances, and Science Translational Medicine.1Among many revelations, this unprecedented, international effort has characterized more than 3,000 human brain cell types. To put this into some perspective, consider that the human lung contains 61 cell types.2 The work has also begun to uncover normal variation in the brains of individual people, some of the features that distinguish various disease states, and distinctions among key parts of the human brain and those of our closely related primate cousins.