Shreyas Suryanarayana
@shreyasms.bsky.social
Neuroscientist @Duke Neurobiology, Postdoc with Josh Huang. Interested in cortex, thalamus, motor control, development and evolution.
📊 Data:
🧠 36 brains imaged by whole-brain LSFM (shoutout @LifeCanvasTech)
🔬 40 brains imaged with confocal
📍 Anterograde tracing from 8 isocortical areas
📍 Retrograde labeling from 4 brainstem/spinal targets
🧵 More to come—read the preprint
☝️
*
(5/5)
🧠 36 brains imaged by whole-brain LSFM (shoutout @LifeCanvasTech)
🔬 40 brains imaged with confocal
📍 Anterograde tracing from 8 isocortical areas
📍 Retrograde labeling from 4 brainstem/spinal targets
🧵 More to come—read the preprint
☝️
*
(5/5)
July 25, 2025 at 10:45 AM
📊 Data:
🧠 36 brains imaged by whole-brain LSFM (shoutout @LifeCanvasTech)
🔬 40 brains imaged with confocal
📍 Anterograde tracing from 8 isocortical areas
📍 Retrograde labeling from 4 brainstem/spinal targets
🧵 More to come—read the preprint
☝️
*
(5/5)
🧠 36 brains imaged by whole-brain LSFM (shoutout @LifeCanvasTech)
🔬 40 brains imaged with confocal
📍 Anterograde tracing from 8 isocortical areas
📍 Retrograde labeling from 4 brainstem/spinal targets
🧵 More to come—read the preprint
☝️
*
(5/5)
We demonstrate how these two neurogenic programs—with distinct evolutionary histories—differentially shape isocortical output architecture, establishing it as the apex of hierarchical sensorimotor integration.
*
(4/5)
*
(4/5)
July 25, 2025 at 10:45 AM
We demonstrate how these two neurogenic programs—with distinct evolutionary histories—differentially shape isocortical output architecture, establishing it as the apex of hierarchical sensorimotor integration.
*
(4/5)
*
(4/5)
This expansion is area-specific—reflecting the functional specialization of each region across motor, sensory, and associative areas.
It’s shaped by pruning of a pan-isocortex corticospinal axonal scaffold in indirect, but not direct, ET neurons.
*
(3/5)
It’s shaped by pruning of a pan-isocortex corticospinal axonal scaffold in indirect, but not direct, ET neurons.
*
(3/5)
July 25, 2025 at 10:45 AM
This expansion is area-specific—reflecting the functional specialization of each region across motor, sensory, and associative areas.
It’s shaped by pruning of a pan-isocortex corticospinal axonal scaffold in indirect, but not direct, ET neurons.
*
(3/5)
It’s shaped by pruning of a pan-isocortex corticospinal axonal scaffold in indirect, but not direct, ET neurons.
*
(3/5)
Using novel genetic access to directly- and indirectly-generated extratelencephalic (ET) neurons in the same mouse, we find:
🧠 Direct ET neurons: Project primarily to forebrain & midbrain
🧠 Indirect ET neurons: Amplify these projections and massively expand to hindbrain & spinal cord
*
(2/5)
🧠 Direct ET neurons: Project primarily to forebrain & midbrain
🧠 Indirect ET neurons: Amplify these projections and massively expand to hindbrain & spinal cord
*
(2/5)
July 25, 2025 at 10:45 AM
Using novel genetic access to directly- and indirectly-generated extratelencephalic (ET) neurons in the same mouse, we find:
🧠 Direct ET neurons: Project primarily to forebrain & midbrain
🧠 Indirect ET neurons: Amplify these projections and massively expand to hindbrain & spinal cord
*
(2/5)
🧠 Direct ET neurons: Project primarily to forebrain & midbrain
🧠 Indirect ET neurons: Amplify these projections and massively expand to hindbrain & spinal cord
*
(2/5)