#neuralpopulation — Public Fediverse posts

🧠 New preprint by Lu et al: Recordings from the human #hippocampus and anterior cingulate #cortex during three distinct tasks reveal that #NeuralPopulation activity is not fully task-specific. About half of the low-dimensional #NeuralSubspace structure was shared across tasks, suggesting a stable population geometry that may support flexible #cognition across different #behaviors.

📝 https://doi.org/10.64898/2026.04.24.720703

#Neuroscience #NeuralDynamics #cogsci #Behavior

🧠 New preprint by Lu et al: Recordings from the human #hippocampus and anterior cingulate #cortex during three distinct tasks reveal that #NeuralPopulation activity is not fully task-specific. About half of the low-dimensional #NeuralSubspace structure was shared across tasks, suggesting a stable population geometry that may support flexible #cognition across different #behaviors.

📝 https://doi.org/10.64898/2026.04.24.720703

#Neuroscience #NeuralDynamics #cogsci #Behavior

🧠 New preprint by Lu et al: Recordings from the human #hippocampus and anterior cingulate #cortex during three distinct tasks reveal that #NeuralPopulation activity is not fully task-specific. About half of the low-dimensional #NeuralSubspace structure was shared across tasks, suggesting a stable population geometry that may support flexible #cognition across different #behaviors.

📝 https://doi.org/10.64898/2026.04.24.720703

#Neuroscience #NeuralDynamics #cogsci #Behavior

🧠 New preprint by Lu et al: Recordings from the human #hippocampus and anterior cingulate #cortex during three distinct tasks reveal that #NeuralPopulation activity is not fully task-specific. About half of the low-dimensional #NeuralSubspace structure was shared across tasks, suggesting a stable population geometry that may support flexible #cognition across different #behaviors.

📝 https://doi.org/10.64898/2026.04.24.720703

#Neuroscience #NeuralDynamics #cogsci #Behavior

🧠 New preprint by Lu et al: Recordings from the human #hippocampus and anterior cingulate #cortex during three distinct tasks reveal that #NeuralPopulation activity is not fully task-specific. About half of the low-dimensional #NeuralSubspace structure was shared across tasks, suggesting a stable population geometry that may support flexible #cognition across different #behaviors.

📝 https://doi.org/10.64898/2026.04.24.720703

#Neuroscience #NeuralDynamics #cogsci #Behavior

@LMPrida shares an inspiring perspective in @thetransmitter on how #neuron subtypes may control large-scale #NeuralPopulation activity, from #manifolds to #ripples:

🌍 https://www.thetransmitter.org/brain-inspired/liset-de-la-prida-explains-how-neuron-subtypes-may-control-the-activity-of-large-neural-populations-from-manifolds-to-ripples/

#CompNeuro #Neuroscience

@LMPrida shares an inspiring perspective in @thetransmitter on how #neuron subtypes may control large-scale #NeuralPopulation activity, from #manifolds to #ripples:

🌍 https://www.thetransmitter.org/brain-inspired/liset-de-la-prida-explains-how-neuron-subtypes-may-control-the-activity-of-large-neural-populations-from-manifolds-to-ripples/

#CompNeuro #Neuroscience

@LMPrida shares an inspiring perspective in @thetransmitter on how #neuron subtypes may control large-scale #NeuralPopulation activity, from #manifolds to #ripples:

🌍 https://www.thetransmitter.org/brain-inspired/liset-de-la-prida-explains-how-neuron-subtypes-may-control-the-activity-of-large-neural-populations-from-manifolds-to-ripples/

#CompNeuro #Neuroscience

@LMPrida shares an inspiring perspective in @thetransmitter on how #neuron subtypes may control large-scale #NeuralPopulation activity, from #manifolds to #ripples:

🌍 https://www.thetransmitter.org/brain-inspired/liset-de-la-prida-explains-how-neuron-subtypes-may-control-the-activity-of-large-neural-populations-from-manifolds-to-ripples/

#CompNeuro #Neuroscience

🧠 New work by Codol et al. who show that #MotorCortex dynamics are remarkably conserved across #mice, #monkeys, and #humans. Despite very different #behaviors, #NeuralPopulation activity follows similar dynamical rules on low-dimensional #manifolds. Species differences arise mainly from the geometry of trajectories within this shared #DynamicalSystem.

📄 https://doi.org/10.64898/2026.03.06.709637

#Neuroscience #CompNeuro #NeuralDynamics

🧠 New preprint by Chericoni et al: #NeuralPopulation activity in the #hippocampus encodes spatial information for different agents (self, prey, gaze) in distinct but related low-dimensional subspaces. The study shows that these representations can be linearly transformed between each other, suggesting a shared geometric code supporting flexible spatial #cognition and multi-agent navigation.

📄 https://arxiv.org/abs/2603.04747

#Neuroscience #CompNeuro #NeuralDynamics

🧠 New preprint by Chericoni et al: #NeuralPopulation activity in the #hippocampus encodes spatial information for different agents (self, prey, gaze) in distinct but related low-dimensional subspaces. The study shows that these representations can be linearly transformed between each other, suggesting a shared geometric code supporting flexible spatial #cognition and multi-agent navigation.

📄 https://arxiv.org/abs/2603.04747

#Neuroscience #CompNeuro #NeuralDynamics

🧠 New preprint by Chericoni et al: #NeuralPopulation activity in the #hippocampus encodes spatial information for different agents (self, prey, gaze) in distinct but related low-dimensional subspaces. The study shows that these representations can be linearly transformed between each other, suggesting a shared geometric code supporting flexible spatial #cognition and multi-agent navigation.

📄 https://arxiv.org/abs/2603.04747

#Neuroscience #CompNeuro #NeuralDynamics

🧠 New preprint by Chericoni et al: #NeuralPopulation activity in the #hippocampus encodes spatial information for different agents (self, prey, gaze) in distinct but related low-dimensional subspaces. The study shows that these representations can be linearly transformed between each other, suggesting a shared geometric code supporting flexible spatial #cognition and multi-agent navigation.

📄 https://arxiv.org/abs/2603.04747

#Neuroscience #CompNeuro #NeuralDynamics

🧠 New preprint by Chericoni et al: #NeuralPopulation activity in the #hippocampus encodes spatial information for different agents (self, prey, gaze) in distinct but related low-dimensional subspaces. The study shows that these representations can be linearly transformed between each other, suggesting a shared geometric code supporting flexible spatial #cognition and multi-agent navigation.

📄 https://arxiv.org/abs/2603.04747

#Neuroscience #CompNeuro #NeuralDynamics

🧠 New preprint by Ruff, Markman, Kim & Cohen (2025): #NeuralPopulation formatting matters for function. In monkeys combining motion and reward, both middle temporal area (#MT) & dorsolateral prefrontal #cortex (#dlPFC) encode both signals. But MT formats them separately, dlPFC integrates them. A recurrent #RNN model predicted, and microstimulation confirmed, distinct #behavioral impacts.

🌍 https://www.biorxiv.org/content/10.1101/2025.01.03.631242v1

#Neuroscience #CompNeuro #DecisionMaking #NeuralCoding

🧠 New preprint by Ruff, Markman, Kim & Cohen (2025): #NeuralPopulation formatting matters for function. In monkeys combining motion and reward, both middle temporal area (#MT) & dorsolateral prefrontal #cortex (#dlPFC) encode both signals. But MT formats them separately, dlPFC integrates them. A recurrent #RNN model predicted, and microstimulation confirmed, distinct #behavioral impacts.

🌍 https://www.biorxiv.org/content/10.1101/2025.01.03.631242v1

#Neuroscience #CompNeuro #DecisionMaking #NeuralCoding

🧠 New preprint by Ruff, Markman, Kim & Cohen (2025): #NeuralPopulation formatting matters for function. In monkeys combining motion and reward, both middle temporal area (#MT) & dorsolateral prefrontal #cortex (#dlPFC) encode both signals. But MT formats them separately, dlPFC integrates them. A recurrent #RNN model predicted, and microstimulation confirmed, distinct #behavioral impacts.

🌍 https://www.biorxiv.org/content/10.1101/2025.01.03.631242v1

#Neuroscience #CompNeuro #DecisionMaking #NeuralCoding

@juangallego just published a review on how #NeuralManifolds go beyond being a convenient data representation – they reflect fundamental constraints on #NeuralPopulation activity. Originating in mammalian BCI work (2014), these low-dimensional trajectories shape what neural patterns are learnable and expressible.

🌍 https://www.nature.com/articles/s41583-025-00919-0.epdf

#CompNeuro #SystemsNeuroscience #PopulationDynamics #Neuroscience