How cell types shape human brain networks

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How cell types shape human brain networks

Researchers have uncovered how different types of brain cells work together to form large-scale functional networks in the human brain – interconnected systems that support everything from sensory processing to complex decision-making – paving the way for new insights into brain health and disease.

By pinpointing these cellular foundations, the study, published in Nature Neuroscience, offers a deeper understanding of the cellular foundations of cognition and mental health.

The brain’s functional properties arise from the varied cell types within its cortex, the outermost layer responsible for many complex mental tasks. A major goal in neuroscience research is to understand how our genetic, molecular and cellular processes support brain’s organization properties, as measured through functional magnetic resonance imaging.

Historically, scientists studied brain organization properties by examining tissue samples from post-mortem or by using invasive techniques in animals, such as studying tissue structure (histology), tracing neural pathways, measuring electrical activity (electrophysiology) or observing changes after specific areas were damaged (lesion methods).

Advances in genetics and technology now allow researchers to study how brain cells are organized in human tissue more precisely. In this study, researchers used recently developed post-mortem gene expression atlases, which map how genes are differentially expressed across brain regions, to explore how different types of cells may spatially align with brain networks studies in the general population.

Researchers found that certain cell-type distributions align with specific networks in the brain’s cortex, both at the level of individual cell types and multivariate cellular profiles, or fingerprints.

“These findings highlight a connection between the functional organization of the human brain and its cellular underpinnings,” said the senior author.

“The study has significant implications for understanding the cellular basis of brain functions across health and disease,” the author said.

This research sets the stage for future studies to explore how our diverse cell types work together within the brain’s networks and to test other potential models of how cells contribute to brain function.

Future studies should examine ways to integrate the hierarchical structure of these diverse cell definitions in analyses and consider alternate models of in vivo brain functioning, said the author.

https://www.nature.com/articles/s41593-024-01812-2

https://sciencemission.com/The-cell-type-underpinnings-of-the-human-functional-cortical-connectome