Scientists map unprecedented detail of connections and visual perception in the mouse brain

In a collaborative study termed the MICrONS Consortium, hundreds of researchers have helped to map the connections between hundreds of thousands of neurons in the mouse brain and then overlaid their firing patterns in response to visual stimuli. This breakthrough is a critical piece of foundational science to build toward understanding how our brains process visual information to reconstruct the images we see every day.

The findings of this project, published in a package of 10 papers published in the Nature family of journals, represent more than seven years of work performed by more than 150 scientists around the world. The MICrONS Consortium et al. papers can be found here.

Information processing in the human brain occurs via electrical firing of 86 billion neurons that make trillions of connections with each other. The secrets of how our brain enables us to think, feel, and act lie hidden in the complexity of its wiring diagram and the barrage of electrical signals that move across it in millisecond time frames. While the current findings focus on a tiny fraction of the brain, they reveal the complex connections between the cells and show how those connections are wired to produce functional responses.

This information, which was previously beyond our reach, could help us understand how the brain functions normally and offer a guide to what goes wrong as the result of various disorders or injuries.

To carry out the study, researchers presented video clips to mice genetically engineered for their neurons to emit light when fired. The neuron firing patterns in areas on the brain surface that are associated with vision were optically recorded across a cubic millimeter—about the size of a grain of sand. Within this deceptively small amount of tissue lies remarkable complexity: four kilometers of axons, the processes that nerve cells use to communicate with each other, intertwined to make more than 524 million connections called synapses across more than 200,000 cells.

To map these connections, teams worked 12-hour shifts for 12 straight days to carefully cut and image ultra-thin slices of the brain tissue using electron microscopes (EM). Reconstruction was the most challenging next step, as it required accurate stitching together almost 28,000 EM images to align the connections crossing the volume of brain tissue. This was followed by months of tracing the connections using deep learning algorithms, followed by manual, and automated proofreading.

Deep-learning predictive models that explain visual information processing in the cortex were constructed and validated. In total, the sheer amount of data collected to create this tiny map comes out to 1.6 petabytes, roughly the equivalent of 22 years of continuous HD video.

These results come at a time when maps of neurons and their connections are increasingly revealing the mysteries of the brain. In 2023, research produced the first complete cell atlas of the mouse brain, including the types and locations surveyed from more than 32 million cells. Last year, the NIH BRAIN Initiative "Flywire" project led to the complete mapping of the common fruit fly brain, demonstrating the unique value of mapping the whole brain in its entirety.

The findings of this project, published in a package of 10 papers published in the Nature family of journals, represent more than seven years of work performed by more than 150 scientists around the world.

The mouse connectome data detailed in this press release can be visualized online using the MICrONS Explorer resource.

More information:
The MICrONS Consortium et al. papers can be found here.

Provided by National Institutes of Health