Neurons can rapidly rebalance their communication using a structural signal rather than electrical activity, overturning long-held assumptions about how synapses maintain stability.

Scientists can finally hear the brain’s quietest messages—unlocking the hidden code behind how neurons think, decide, and ...

Scientists have engineered a protein able to record the incoming chemical signals of brain cells (as opposed to just their ...

Every movement you make and every memory you form depends on precise communication between neurons. When that communication is disrupted, the brain must rapidly rebalance its internal signaling to ...

Memories and learning processes are based on changes in the brain’s neuronal connections and, as a result, in signal transmission between neurons. For the first time, DZNE researchers have observed an ...

Closely related subtypes of dopamine-releasing neurons may play entirely separate roles in processing sensory information, ...

Memories and learning processes are based on changes in the brain's neuronal connections and, as a result, in signal transmission between neurons.

Imagine watching a conversation between brain cells, seeing chemical messages pass from one neuron to another. Scientists can ...

An interactive toolbox for standardizing, validating, simulating, reducing, and exploring detailed biophysical models that can be used to reveal how morpho-electric properties map to dendritic and ...

Closely related dopamine-releasing neurons in the olfactory bulb behave in fundamentally different ways depending on their physical structure.

Every movement you make and every memory you form depends on precise communication between neurons. When that communication ...

A new bioluminescent tool allows neurons to glow on their own, letting scientists track brain activity without harmful lasers ...