Defining cell types
Recent articles
This series explores how new high-throughput technologies are changing the way we define brain-cell types—and the challenges that remain.
From genes to dynamics: Examining brain cell types in action may reveal the logic of brain function
Defining brain cell types is no longer a matter of classification alone, but of embedding their genetic identities within the dynamical organization of population activity.
From genes to dynamics: Examining brain cell types in action may reveal the logic of brain function
Defining brain cell types is no longer a matter of classification alone, but of embedding their genetic identities within the dynamical organization of population activity.
Knowledge graphs can help make sense of the flood of cell-type data
These tools, widely used in the technology industry, could provide a foundation for the study of brain circuits.
Knowledge graphs can help make sense of the flood of cell-type data
These tools, widely used in the technology industry, could provide a foundation for the study of brain circuits.
Where do cell states end and cell types begin?
High-throughput transcriptomics offers powerful new methods for defining different types of brain cells. But we need to think more explicitly about how we use these data to distinguish a cell’s permanent identity from its transient states.
Where do cell states end and cell types begin?
High-throughput transcriptomics offers powerful new methods for defining different types of brain cells. But we need to think more explicitly about how we use these data to distinguish a cell’s permanent identity from its transient states.
Building a brain: How does it generate its exquisite diversity of cells?
High-throughput technologies have revealed new insights into how the brain develops. But a truly comprehensive map of neurodevelopment requires further advances.
Building a brain: How does it generate its exquisite diversity of cells?
High-throughput technologies have revealed new insights into how the brain develops. But a truly comprehensive map of neurodevelopment requires further advances.
Welcome to the second single-cell revolution: New high-throughput technologies are transforming how we define neurons
This ongoing essay series will explore questions these technologies raise, as well as opportunities they provide for understanding development, evolution and disease.
Welcome to the second single-cell revolution: New high-throughput technologies are transforming how we define neurons
This ongoing essay series will explore questions these technologies raise, as well as opportunities they provide for understanding development, evolution and disease.
Explore more from The Transmitter
Frameshift: Raphe Bernier followed his heart out of academia, then made his way back again
After a clinical research career, an interlude at Apple and four months in early retirement, Raphe Bernier found joy in teaching.
Frameshift: Raphe Bernier followed his heart out of academia, then made his way back again
After a clinical research career, an interlude at Apple and four months in early retirement, Raphe Bernier found joy in teaching.
Organoid study reveals shared brain pathways across autism-linked variants
The genetic variants initially affect brain development in unique ways, but over time they converge on common molecular pathways.
Organoid study reveals shared brain pathways across autism-linked variants
The genetic variants initially affect brain development in unique ways, but over time they converge on common molecular pathways.
Single gene sways caregiving circuits, behavior in male mice
Brain levels of the agouti gene determine whether African striped mice are doting fathers—or infanticidal ones.
Single gene sways caregiving circuits, behavior in male mice
Brain levels of the agouti gene determine whether African striped mice are doting fathers—or infanticidal ones.