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neural connectivity

The Amazing Brain: Toward a Wiring Diagram of Connectivity

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It’s summertime and, thanks to the gift of COVID-19 vaccines, many folks are getting the chance to take a break. So, I think it’s also time that my blog readers finally get a break from what’s been nearly 18 months of non-stop coverage of COVID-19 research. And I can’t think of a more enjoyable way to do that than by taking a look at just a few of the many spectacular images and insights that researchers have derived about the amazing brain.

The Brain Research through Advancing Innovative Neurotechnologies® (BRAIN) Initiative, which is an NIH-led project aimed at revolutionizing our understanding of the human brain, happens to have generated some of the coolest—and most informative—imagery now available in neuroscience. So, throughout the month of August, I’ll share some of the entries from the initiative’s latest Show Us Your BRAINs! Photo and Video Contest.

With nearly 100 billion neurons and 100 trillion connections, the human brain remains one of the greatest mysteries in science. Among the many ways in which neuroscientists are using imaging to solve these mysteries is by developing more detailed maps of connectivity within the brain.

For example, the image featured above from the contest shows a dense weave of neurons in the anterior cingulate cortex, which is the part of the brain involved in learning, memory, and some motor control. In this fluorescence micrograph of tissue from a mouse, each neuron has been labeled with green fluorescent protein, enabling you to see how it connects to other neurons through arm-like projections called axons and dendrites.

The various connections, or circuits, within the brain process and relay distinct types of sensory information. In fact, a single neuron can form a thousand or more of these connections. Among the biggest challenges in biomedicine today is deciphering how these circuits work, and how they can misfire to cause potentially debilitating neurological conditions, including Alzheimer’s disease, Parkinson’s disease, autism, epilepsy, schizophrenia, depression, and traumatic brain injury.

This image was produced by Nicholas Foster and Lei Gao in the NIH-supported lab of Hong Wei Dong, University of California, Los Angeles. The Dong Lab is busy cataloging cell types and helping to assemble a wiring diagram of the connectivity in the mammalian brain—just one of the BRAIN Initiative’s many audacious goals. Stay tuned for more throughout the month of August!

Links:

Brain Research through Advancing Innovative Neurotechnologies® (BRAIN) Initiative (NIH)

Dong Lab (University of California, Los Angeles)

Show Us Your BRAINs! Photo and Video Contest (BRAIN Initiative/NIH)

NIH Support: National Institute of Mental Health


Snapshots of Life: Color Coding the Hippocampus

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Hippocampus

Credit: Raunak Basu, University of Utah, Salt Lake City

The final frontier? Trekkies would probably say it’s space, but mapping the brain—the most complicated biological structure in the known universe—is turning out to be an amazing adventure in its own right. Not only are researchers getting better at charting the brain’s densely packed and varied cellular topography, they are starting to identify the molecules that neurons use to connect into the distinct information-processing circuits that allow all walks of life to think and experience the world.

This image shows distinct neural connections in a cross section of a mouse’s hippocampus, a region of the brain involved in the memory of facts and events. The large, crescent-shaped area in green is hippocampal zone CA1. Its highly specialized neurons, called place cells, serve as the brain’s GPS system to track location. It appears green because these neurons express cadherin-10. This protein serves as a kind of molecular glue that likely imparts specific functional properties to this region. [1]


Snapshots of Life: Fisheye View

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Goldfish retina

Credit: Bryan William Jones and Robert E. Marc, University of Utah, Salt Lake City

It looks like a celebration with confetti and streamers that the photographers—among the winners of the Federation of American Societies for Experimental Biology’s 2013 BioArt Competition—captured in this image. But these dots and lines are actually cells in the retina of a goldfish. And what such images reveal may be far more than just a pretty picture.

NIH-funded researchers at the University of Utah used a set of tools called Computational Molecular Phenotyping (CMP) to take a snapshot of the amacrine cells in the retina. The retina is delicate, light-sensitive tissue in the back of the eye, and its amacrine cells are involved in processing and conveying signals from the light-gathering photoreceptor cells to the brain’s visual cortex, where the image is decoded. The colors in this photograph reveal the unique metabolic chemistry, and thus the identity, of each subtype of neuron. The red, yellow, and orange cells are amacrine neurons with a high level of the amino acid glycine; the blue ones have a lot of the neurotransmitter gamma-aminobutyric acid (GABA). The green color tells us something different: it provides a physiological snapshot revealing which neurons were active and talking to each other at the time the image was created.