Your search keyword '"Blake A. Richards"' showing total 25 results

1. Parallel and Recurrent Cascade Models as a Unifying Force for Understanding Subcellular Computation

Author

Emerson F. Harkin, Peter R. Shen, Anish Goel, Blake A. Richards, and Richard Naud

Subjects

Neurons, 0303 health sciences, Theoretical computer science, Quantitative Biology::Neurons and Cognition, Artificial neural network, Computer science, General Neuroscience, Computation, Models, Neurological, Biophysics, Dendrites, 03 medical and health sciences, 0302 clinical medicine, Models of neural computation, Flow (mathematics), Artificial Intelligence, Cascade, Neural Networks, Computer, Mathematical structure, 030217 neurology & neurosurgery, Physiological Phenomenon, 030304 developmental biology

Abstract

Neurons are very complicated computational devices, incorporating numerous non-linear processes, particularly in their dendrites. Biophysical models capture these processes directly by explicitly modelling physiological variables, such as ion channels, current flow, membrane capacitance, etc. However, another option for capturing the complexities of real neural computation is to use cascade models, which treat individual neurons as a cascade of linear and non-linear operations, akin to a multi-layer artificial neural network. Recent research has shown that cascade models can capture single-cell computation well, but there are still a number of sub-cellular, regenerative dendritic phenomena that they cannot capture, such as the interaction between sodium, calcium, and NMDA spikes in different compartments. Here, we propose that it is possible to capture these additional phenomena usingparallel, recurrentcascade models, wherein an individual neuron is modelled as a cascade of parallel linear and non-linear operations that can be connected recurrently, akin to a multi-layer, recurrent, artificial neural network. Given their tractable mathematical structure, we show that neuron models expressed in terms of parallel recurrent cascades can themselves be integrated into multi-layered artificial neural networks and trained to perform complex tasks. We go on to discuss potential implications and uses of these models for artificial intelligence. Overall, we argue that parallel, recurrent cascade models provide an important, unifying tool for capturing single-cell computation and exploring the algorithmic implications of physiological phenomena.

Published

2022

2. Learning function from structure in neuromorphic networks

Author

Laura E. Suárez, Blake A. Richards, Guillaume Lajoie, and Bratislav Misic

Subjects

0303 health sciences, Network architecture, Artificial neural network, Computer Networks and Communications, Computer science, business.industry, Reservoir computing, Complex network, Network topology, Human-Computer Interaction, 03 medical and health sciences, 0302 clinical medicine, Neuromorphic engineering, Artificial Intelligence, Encoding (memory), Biological neural network, Computer Vision and Pattern Recognition, Artificial intelligence, business, 030217 neurology & neurosurgery, Software, 030304 developmental biology

Abstract

The connection patterns of neural circuits in the brain form a complex network. Collective signalling within the network manifests as patterned neural activity and is thought to support human cognition and adaptive behaviour. Recent technological advances permit macroscale reconstructions of biological brain networks. These maps, termed connectomes, display multiple non-random architectural features, including heavy-tailed degree distributions, segregated communities and a densely interconnected core. Yet, how computation and functional specialization emerge from network architecture remains unknown. Here we reconstruct human brain connectomes using in vivo diffusion-weighted imaging and use reservoir computing to implement connectomes as artificial neural networks. We then train these neuromorphic networks to learn a memory-encoding task. We show that biologically realistic neural architectures perform best when they display critical dynamics. We find that performance is driven by network topology and that the modular organization of intrinsic networks is computationally relevant. We observe a prominent interaction between network structure and dynamics throughout, such that the same underlying architecture can support a wide range of memory capacity values as well as different functions (encoding or decoding), depending on the dynamical regime the network is in. This work opens new opportunities to discover how the network organization of the brain optimizes cognitive capacity. The relationship between brain organization, connectivity and computation is not well understood. The authors construct neuromorphic artificial neural networks endowed with biological connection patterns derived from diffusion-weighted imaging. The neuromorphic networks are trained to perform a memory task, revealing an interaction between network structure and dynamics.

Published

2021

3. PNS-GAN: Conditional Generation of Peripheral Nerve Signals in the Wavelet Domain via Adversarial Networks

Author

Blake A. Richards, Olivier Tessier-Lariviere, Luke Y. Prince, Emil Hewage, Lorenz Wernisch, Guillaume Lajoie, Oliver Armitage, and Pascal Fortier-Poisson

Subjects

0301 basic medicine, business.industry, Noise (signal processing), Computer science, Pattern recognition, Neural engineering, Signal, Convolution, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Wavelet, Recurrent neural network, Modulation, Artificial intelligence, business, 030217 neurology & neurosurgery, Decoding methods

Abstract

Simulated datasets of neural recordings are a crucial tool in neural engineering for testing the ability of decoding algorithms to recover known ground-truth. In this work, we introduce PNS-GAN, a generative adversarial network capable of producing realistic nerve recordings conditioned on physiological biomarkers. PNS-GAN operates in the wavelet domain to preserve both the timing and frequency of neural events with high resolution. PNS-GAN generates sequences of scaleograms from noise using a recurrent neural network and 2D transposed convolution layers. PNS-GAN discriminates over stacks of scaleograms with a network of 3D convolution layers. We find that our generated signal reproduces a number of characteristics of the real signal, including similarity in a canonical time-series feature-space, and contains physiologically related neural events including respiration modulation and similar distributions of afferent and efferent signalling.

Published

2021

4. Systems consolidation impairs behavioral flexibility

Author

Blake A. Richards, Sofia Skromne Carrasco, Lydia Saad, and Sankirthana Sathiyakumar

Subjects

Male, Time Factors, Computer science, Cognitive Neuroscience, Hippocampus, Prefrontal Cortex, 03 medical and health sciences, Cellular and Molecular Neuroscience, Mice, 0302 clinical medicine, Animals, Animal behavior, Reinforcement, Prefrontal cortex, Maze Learning, Memory Consolidation, Flexibility (engineering), Behavior, Animal, Research, Mice, Inbred C57BL, Neuropsychology and Physiological Psychology, Initial training, Task analysis, Memory consolidation, sense organs, Neuroscience, 030217 neurology & neurosurgery

Abstract

Behavioral flexibility is important in a changing environment. Previous research suggests that systems consolidation, a long-term poststorage process that alters memory traces, may reduce behavioral flexibility. However, exactly how systems consolidation affects flexibility is unknown. Here, we tested how systems consolidation affects: (1) flexibility in response to value changes and (2) flexibility in response to changes in the optimal sequence of actions. Mice were trained to obtain food rewards in a Y-maze by switching nose pokes between three arms. During initial training, all arms were rewarded and mice simply had to switch arms in order to maximize rewards. Then, after either a 1 or 28 d delay, we either devalued one arm, or we reinforced a specific sequence of pokes. We found that after a 1 d delay mice adapted relatively easily to the changes. In contrast, mice given a 28 d delay struggled to adapt, especially for changes to the optimal sequence of actions. Immediate early gene imaging suggested that the 28 d mice were less reliant on their hippocampus and more reliant on their medial prefrontal cortex. These data suggest that systems consolidation reduces behavioral flexibility, particularly for changes to the optimal sequence of actions.

Published

2020

5. Distinct roles of parvalbumin and somatostatin interneurons in gating the synchronization of spike times in the neocortex

Author

Hyowon Chung, Michael M. Kohl, Blake A. Richards, Hyun Jae Jang, James M. Rowland, and Jeehyun Kwag

Subjects

Interneuron, genetic structures, Neurophysiology, Sensory system, Gating, Optogenetics, Inhibitory postsynaptic potential, 03 medical and health sciences, 0302 clinical medicine, medicine, Research Articles, 030304 developmental biology, 0303 health sciences, Multidisciplinary, Neocortex, biology, musculoskeletal, neural, and ocular physiology, fungi, SciAdv r-articles, Barrel cortex, medicine.anatomical_structure, nervous system, biology.protein, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin, Research Article

Abstract

Sensory information–driven spikes are synchronized across cortical layers by distinct subtypes of interneurons., Synchronization of precise spike times across multiple neurons carries information about sensory stimuli. Inhibitory interneurons are suggested to promote this synchronization, but it is unclear whether distinct interneuron subtypes provide different contributions. To test this, we examined single-unit recordings from barrel cortex in vivo and used optogenetics to determine the contribution of parvalbumin (PV)– and somatostatin (SST)–positive interneurons to the synchronization of spike times across cortical layers. We found that PV interneurons preferentially promote the synchronization of spike times when instantaneous firing rates are low (12 Hz). Furthermore, using a computational model, we demonstrate that these effects can be explained by PV and SST interneurons having preferential contributions to feedforward and feedback inhibition, respectively. Our findings demonstrate that distinct subtypes of inhibitory interneurons have frequency-selective roles in the spatiotemporal synchronization of precise spike times.

Published

2020

6. Optogenetic activation of parvalbumin and somatostatin interneurons selectively restores theta-nested gamma oscillations and oscillation-induced spike timing-dependent long-term potentiation impaired by amyloid β oligomers

Author

Jaedong Lee, Jeehyun Kwag, Blake A. Richards, Kyerl Park, Michael M. Kohl, and Hyun Jae Jang

Subjects

Amyloid beta oligomers, Physiology, Long-Term Potentiation, Action Potentials, Plant Science, Parvalbumin interneuron, Hippocampal formation, Hippocampus, Mice, 0302 clinical medicine, Structural Biology, LTP induction, lcsh:QH301-705.5, Theta-nested gamma oscillations, 0303 health sciences, musculoskeletal, neural, and ocular physiology, Long-term potentiation, Synapse-specific dysfunction, Parvalbumins, medicine.anatomical_structure, Somatostatin, General Agricultural and Biological Sciences, Alzheimer’s disease, hormones, hormone substitutes, and hormone antagonists, Research Article, Biotechnology, endocrine system, Interneuron, Biology, Optogenetics, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Interneurons, medicine, Biological neural network, Animals, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Amyloid beta-Peptides, fungi, Spike timing-dependent long-term potentiation, Cell Biology, Peptide Fragments, lcsh:Biology (General), nervous system, Synaptic plasticity, biology.protein, Somatostatin interneuron, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin, Developmental Biology

Abstract

Background Abnormal accumulation of amyloid β1–42 oligomers (AβO1–42), a hallmark of Alzheimer’s disease, impairs hippocampal theta-nested gamma oscillations and long-term potentiation (LTP) that are believed to underlie learning and memory. Parvalbumin-positive (PV) and somatostatin-positive (SST) interneurons are critically involved in theta-nested gamma oscillogenesis and LTP induction. However, how AβO1–42 affects PV and SST interneuron circuits is unclear. Through optogenetic manipulation of PV and SST interneurons and computational modeling of the hippocampal neural circuits, we dissected the contributions of PV and SST interneuron circuit dysfunctions on AβO1–42-induced impairments of hippocampal theta-nested gamma oscillations and oscillation-induced LTP. Results Targeted whole-cell patch-clamp recordings and optogenetic manipulations of PV and SST interneurons during in vivo-like, optogenetically induced theta-nested gamma oscillations in vitro revealed that AβO1–42 causes synapse-specific dysfunction in PV and SST interneurons. AβO1–42 selectively disrupted CA1 pyramidal cells (PC)-to-PV interneuron and PV-to-PC synapses to impair theta-nested gamma oscillogenesis. In contrast, while having no effect on PC-to-SST or SST-to-PC synapses, AβO1–42 selectively disrupted SST interneuron-mediated disinhibition to CA1 PC to impair theta-nested gamma oscillation-induced spike timing-dependent LTP (tLTP). Such AβO1–42-induced impairments of gamma oscillogenesis and oscillation-induced tLTP were fully restored by optogenetic activation of PV and SST interneurons, respectively, further supporting synapse-specific dysfunctions in PV and SST interneurons. Finally, computational modeling of hippocampal neural circuits including CA1 PC, PV, and SST interneurons confirmed the experimental observations and further revealed distinct functional roles of PV and SST interneurons in theta-nested gamma oscillations and tLTP induction. Conclusions Our results reveal that AβO1–42 causes synapse-specific dysfunctions in PV and SST interneurons and that optogenetic modulations of these interneurons present potential therapeutic targets for restoring hippocampal network oscillations and synaptic plasticity impairments in Alzheimer’s disease.

Published

2020

7. The Persistence and Transience of Memory

Author

Blake A. Richards and Paul W. Frankland

Subjects

Neurons, 0301 basic medicine, Cognitive science, Persistence (psychology), Forgetting, General Neuroscience, Decision Making, Models, Neurological, Brain, Flexibility (personality), Mnemonic, Models, Psychological, Overfitting, Machine Learning, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Memory, Generalization (learning), Synapses, Humans, Psychology, Social psychology, Parallels, 030217 neurology & neurosurgery

Abstract

The predominant focus in the neurobiological study of memory has been on remembering (persistence). However, recent studies have considered the neurobiology of forgetting (transience). Here we draw parallels between neurobiological and computational mechanisms underlying transience. We propose that it is the interaction between persistence and transience that allows for intelligent decision-making in dynamic, noisy environments. Specifically, we argue that transience (1) enhances flexibility, by reducing the influence of outdated information on memory-guided decision-making, and (2) prevents overfitting to specific past events, thereby promoting generalization. According to this view, the goal of memory is not the transmission of information through time, per se. Rather, the goal of memory is to optimize decision-making. As such, transience is as important as persistence in mnemonic systems.

Published

2017

8. Bidirectional Control of Anxiety-Related Behaviors in Mice: Role of Inputs Arising from the Ventral Hippocampus to the Lateral Septum and Medial Prefrontal Cortex

Author

D Kanghoon Seo, Matthew M Tran, Blake A. Richards, Robin Nguyen, Jee Yoon Bang, Afif J. Aqrabawi, Gustavo M. Parfitt, and Jun Chul Kim

Subjects

Male, 0301 basic medicine, Prefrontal Cortex, Cre recombinase, Hippocampus, Anxiety, Mice, 03 medical and health sciences, 0302 clinical medicine, Neural Pathways, medicine, Animals, Prefrontal cortex, Clozapine, Pharmacology, Behavior, Animal, business.industry, Septal nuclei, Retrograde tracing, Neuroanatomical Tract-Tracing Techniques, Psychiatry and Mental health, 030104 developmental biology, medicine.anatomical_structure, Forebrain, Septal Nuclei, Original Article, Neuron, medicine.symptom, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Anxiety is an adaptive response to potentially threatening situations. Exaggerated and uncontrolled anxiety responses become maladaptive and lead to anxiety disorders. Anxiety is shaped by a network of forebrain structures, including the hippocampus, septum, and prefrontal cortex. In particular, neural inputs arising from the ventral hippocampus (vHPC) to the lateral septum (LS) and medial prefrontal cortex (mPFC) are thought to serve as principal components of the anxiety circuit. However, the role of vHPC-to-LS and vHPC-to-mPFC signals in anxiety is unclear, as no study has directly compared their behavioral contribution at circuit level. We targeted LS-projecting vHPC cells and mPFC-projecting vHPC cells by injecting the retrogradely propagating canine adenovirus encoding Cre recombinase into the LS or mPFC, and injecting a Cre-responsive AAV (AAV8-hSyn-FLEX-hM3D or hM4D) into the vHPC. Consequences of manipulating these neurons were examined in well-established tests of anxiety. Chemogenetic manipulation of LS-projecting vHPC cells led to bidirectional changes in anxiety: activation of LS-projecting vHPC cells decreased anxiety whereas inhibition of these cells produced opposite anxiety-promoting effects. The observed anxiety-reducing function of LS-projecting cells was in contrast with the function of mPFC-projecting cells, which promoted anxiety. In addition, double retrograde tracing demonstrated that LS- and mPFC-projecting cells represent two largely anatomically distinct cell groups. Altogether, our findings suggest that the vHPC houses discrete populations of cells that either promote or suppress anxiety through differences in their projection targets. Disruption of the intricate balance in the activity of these two neuron populations may drive inappropriate behavioral responses seen in anxiety disorders.

Published

2017

9. A deep learning framework for neuroscience

Author

Panayiota Poirazi, Greg Wayne, Christopher C. Pack, Surya Ganguli, Joel Zylberberg, Pieter R. Roelfsema, Grace W. Lindsay, Blake A. Richards, Walter Senn, Colleen J Gillon, Denis Therien, Philippe Beaudoin, Anna C. Schapiro, Kenneth D. Miller, Archy O. de Berker, Yoshua Bengio, Claudia Clopath, Peter E. Latham, Amelia J. Christensen, João Sacramento, Nikolaus Kriegeskorte, Timothy P. Lillicrap, Rui Ponte Costa, Danijar Hafner, Daniel L. K. Yamins, Benjamin Scellier, Rafal Bogacz, Adam Kepecs, Richard Naud, Friedemann Zenke, Konrad P. Kording, Andrew M. Saxe, Netherlands Institute for Neuroscience (NIN), University of Zurich, Richards, Blake A, Wellcome Trust, Biotechnology and Biological Sciences Research Council (BBSRC), Biotechnology and Biological Sciences Research Cou, Simons Foundation, and National Institutes of Health

Subjects

0301 basic medicine, Computer science, 1702 Cognitive Sciences, media_common.quotation_subject, Article, 03 medical and health sciences, Deep Learning, 0302 clinical medicine, Artificial Intelligence, Perception, Biological neural network, Animals, Humans, 610 Medicine & health, 10194 Institute of Neuroinformatics, media_common, Systems neuroscience, Neurology & Neurosurgery, Artificial neural network, Quantitative Biology::Neurons and Cognition, business.industry, General Neuroscience, Deep learning, Perspective (graphical), Brain, 2800 General Neuroscience, Cognition, Variety (cybernetics), 030104 developmental biology, 1701 Psychology, 570 Life sciences, biology, Neural Networks, Computer, Artificial intelligence, 1109 Neurosciences, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Systems neuroscience seeks explanations for how the brain implements a wide variety of perceptual, cognitive and motor tasks. Conversely, artificial intelligence attempts to design computational systems based on the tasks they will have to solve. In the case of artificial neural networks, the three components specified by design are the objective functions, the learning rules, and architectures. With the growing success of deep learning, which utilizes brain-inspired architectures, these three designed components have increasingly become central to how we model, engineer and optimize complex artificial learning systems. Here we argue that a greater focus on these components would also benefit systems neuroscience. We give examples of how this optimization-based framework can drive theoretical and experimental progress in neuroscience. We contend that this principled perspective on systems neuroscience will help to generate more rapid progress.

Published

2019

10. Deep learning for brains?: Different linear and nonlinear scaling in UK Biobank brain images vs. machine-learning datasets

Author

Blake A. Richards, Yeo Bt, Jakob Nikolas Kather, Joshua T. Vogelstein, Marc-Andre Schulz, Danilo Bzdok, Janaina Mourao-Miranada, Konrad P. Kording, Rheinisch-Westfälische Technische Hochschule Aachen (RWTH), National University of Singapore (NUS), Johns Hopkins University (JHU), University College of London [London] (UCL), German Cancer Consortium [Heidelberg] (DKTK), German Cancer Research Center - Deutsches Krebsforschungszentrum [Heidelberg] (DKFZ), University of Pennsylvania [Philadelphia], Montreal Institute for Learning Algorithms [Montréal] (MILA), Centre de Recherches Mathématiques [Montréal] (CRM), Université de Montréal (UdeM)-Université de Montréal (UdeM), Department of Neurology and Neurosurgery [Montreal], Montreal Neurological Institute and Hospital, McGill University = Université McGill [Montréal, Canada]-McGill University = Université McGill [Montréal, Canada], Modelling brain structure, function and variability based on high-field MRI data (PARIETAL), Inria Saclay - Ile de France, Institut National de Recherche en Informatique et en Automatique (Inria)-Institut National de Recherche en Informatique et en Automatique (Inria)-Service NEUROSPIN (NEUROSPIN), Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris-Saclay, Service NEUROSPIN (NEUROSPIN), Rheinisch-Westfälische Technische Hochschule Aachen University (RWTH), University of Pennsylvania, Université Paris-Saclay-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Inria Saclay - Ile de France, Institut National de Recherche en Informatique et en Automatique (Inria)-Institut National de Recherche en Informatique et en Automatique (Inria), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), and Bzdok, Danilo

Subjects

[INFO.INFO-AI] Computer Science [cs]/Artificial Intelligence [cs.AI], 0303 health sciences, Computer science, business.industry, Deep learning, Linear model, Contrast (statistics), Sample (statistics), Machine learning, computer.software_genre, Speech processing, [INFO.INFO-AI]Computer Science [cs]/Artificial Intelligence [cs.AI], 03 medical and health sciences, Kernel (linear algebra), 0302 clinical medicine, Sample size determination, Artificial intelligence, business, computer, 030217 neurology & neurosurgery, MNIST database, 030304 developmental biology

Abstract

In recent years, deep learning has unlocked unprecedented success in various domains, especially in image, text, and speech processing. These breakthroughs may hold promise for neuroscience and especially for brain-imaging investigators who start to analyze thousands of participants. However, deep learning is only beneficial if the data have nonlinear relationships and if they are exploitable at currently available sample sizes.We systematically profiled the performance of deep models, kernel models, and linear models as a function of sample size on UK Biobank brain images against established machine learning references. On MNIST and Zalando Fashion, prediction accuracy consistently improved when escalating from linear models to shallow-nonlinear models, and further improved when switching to deep-nonlinear models. The more observations were available for model training, the greater the performance gain we saw. In contrast, using structural or functional brain scans, simple linear models performed on par with more complex, highly parameterized models in age/sex prediction across increasing samplesizes. In fact, linear models kept improving as the sample size approached ~10,000 participants. Our results indicate that the increase in performance of linear models with additional data does not saturate at the limit of current feasibility. Yet, nonlinearities of common brain scans remain largely inaccessible to both kernel and deep learning methods at any axemined scale

Published

2019

11. Dissociating memory accessibility and precision in forgetting

Author

Sam C. Berens, Blake A. Richards, and Aidan J. Horner

Subjects

Adult, Male, Social Psychology, Adolescent, Computer science, Experimental and Cognitive Psychology, Information loss, Models, Psychological, 03 medical and health sciences, Behavioral Neuroscience, Young Adult, 0302 clinical medicine, Memory, Generalization (learning), General pattern, Humans, Set (psychology), Pattern learning, Protocol (object-oriented programming), 030304 developmental biology, 0303 health sciences, Memory Disorders, Forgetting, Retention, Psychology, Mental Recall, Female, 030217 neurology & neurosurgery, Cognitive psychology

Abstract

Forgetting involves the loss of information over time; however, we know little about what form this information loss takes. Do memories become less precise over time, or do they instead become less accessible? Here we assessed memory for word-location associations across four days, testing whether forgetting involves losses in precision versus accessibility and whether such losses are modulated by learning a generalizable pattern. We show that forgetting involves losses in memory accessibility with no changes in memory precision. When participants learned a set of related word-location associations that conformed to a general pattern, we saw a strong trade-off; accessibility was enhanced, whereas precision was reduced. However, this trade-off did not appear to be modulated by time or confer a long-term increase in the total amount of information maintained in memory. Our results place theoretical constraints on how models of forgetting and generalization account for time-dependent memory processes. PROTOCOL REGISTRATION: The stage 1 protocol for this Registered Report was accepted in principle on 4 June 2019. The protocol, as accepted by the journal, can be found at https://doi.org/10.6084/m9.figshare.c.4368464.v1 .

Published

2018

12. Dendritic solutions to the credit assignment problem

Author

Timothy P. Lillicrap and Blake A. Richards

Subjects

0301 basic medicine, Multiple stages, Neuronal Plasticity, Credit assignment, Computer science, General Neuroscience, education, Action Potentials, Brain, Dendrites, humanities, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Synaptic plasticity, Neural Pathways, medicine, Animals, Humans, Learning, Neuron, Neuroscience, health care economics and organizations, 030217 neurology & neurosurgery

Abstract

Guaranteeing that synaptic plasticity leads to effective learning requires a means for assigning credit to each neuron for its contribution to behavior. The 'credit assignment problem' refers to the fact that credit assignment is non-trivial in hierarchical networks with multiple stages of processing. One difficulty is that if credit signals are integrated with other inputs, then it is hard for synaptic plasticity rules to distinguish credit-related activity from non-credit-related activity. A potential solution is to use the spatial layout and non-linear properties of dendrites to distinguish credit signals from other inputs. In cortical pyramidal neurons, evidence hints that top-down feedback signals are integrated in the distal apical dendrites and have a distinct impact on spike-firing and synaptic plasticity. This suggests that the distal apical dendrites of pyramidal neurons help the brain to solve the credit assignment problem.

Published

2018

13. Moving beyond reward prediction errors

Author

Blake A. Richards

Subjects

Computer Science::Machine Learning, 0301 basic medicine, Cognitive science, Quantitative Biology::Neurons and Cognition, Computer Networks and Communications, Computer science, Computer Science::Neural and Evolutionary Computation, Neuromodulation (medicine), Human-Computer Interaction, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Artificial Intelligence, Reinforcement learning, Computer Vision and Pattern Recognition, 030217 neurology & neurosurgery, Software

Abstract

Classic theories of reinforcement learning and neuromodulation rely on reward prediction errors. A new machine learning technique relies on neuromodulatory signals that are optimized for specific tasks, which may lead to better AI and better explanations of neuroscience data.

Published

2019

14. Parvalbumin-positive interneurons mediate neocortical-hippocampal interactions that are necessary for memory consolidation

Author

Matthew M Tran, Paul W. Frankland, Sheena A. Josselyn, Blake A. Richards, Frances Xia, and Kaori Takehara-Nishiuchi

Subjects

0301 basic medicine, Mouse, Interneuron, hippocampus, QH301-705.5, Science, Conditioning, Classical, Action Potentials, Hippocampus, Neocortex, Hippocampal formation, Biology, General Biochemistry, Genetics and Molecular Biology, memory, Mice, 03 medical and health sciences, 0302 clinical medicine, Interneurons, medicine, Animals, Biology (General), Prefrontal cortex, Anterior cingulate cortex, Memory Consolidation, General Immunology and Microbiology, ripple, General Neuroscience, Fear, spindle, General Medicine, anterior cingulate cortex, Parvalbumins, 030104 developmental biology, medicine.anatomical_structure, nervous system, biology.protein, Medicine, Memory consolidation, consolidation, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin, Research Article

Abstract

Following learning, increased coupling between spindle oscillations in the medial prefrontal cortex (mPFC) and ripple oscillations in the hippocampus is thought to underlie memory consolidation. However, whether learning-induced increases in ripple-spindle coupling are necessary for successful memory consolidation has not been tested directly. In order to decouple ripple-spindle oscillations, here we chemogenetically inhibited parvalbumin-positive (PV+) interneurons, since their activity is important for regulating the timing of spiking activity during oscillations. We found that contextual fear conditioning increased ripple-spindle coupling in mice. However, inhibition of PV+ cells in either CA1 or mPFC eliminated this learning-induced increase in ripple-spindle coupling without affecting ripple or spindle incidence. Consistent with the hypothesized importance of ripple-spindle coupling in memory consolidation, post-training inhibition of PV+ cells disrupted contextual fear memory consolidation. These results indicate that successful memory consolidation requires coherent hippocampal-neocortical communication mediated by PV+ cells., eLife digest Sleep contributes to the strengthening of memories. During non-dreaming sleep, neurons in regions of the brain that form and store memories – such as the hippocampus and prefrontal cortex – fire in rhythmic waves. The neurons in the hippocampus tend to fire during a wave that repeats up to 250 times per second, called sharp-wave ripples. Meanwhile, in the prefrontal cortex, the neurons tend to fire during a lower frequency wave that repeats 12 to 15 times per second, called spindles. During sleep and quiet wakefulness, hippocampal ripples often synchronize with prefrontal spindles; that is, both waves tend to occur at approximately the same time. Many neuroscientists think this allows the brain regions to better communicate with one another, which in turn should help the brain to strengthen memories. Consistent with this possibility, rodents that learn a new task show more synchrony between ripples and spindles afterwards. But no one had actually tested whether this increase in ripple-spindle synchrony does strengthen the rodent’s memory of the task. It was also unclear how the brain achieves such an increase. Xia et al. suspected that this process involved a group of inhibitory brain cells called parvalbumin-positive interneurons. These cells act like timekeepers, and help to synchronize the firing of groups of neurons. Xia et al. now show that training mice to associate an environment with a mild electric shock made it more likely that the animals would show ripple-spindle synchrony. Yet, inhibiting the activity of parvalbumin-positive interneurons in either the hippocampus or prefrontal cortex blocked this effect. It also prevented sleep from strengthening the animals’ memory of the link between the environment and the shock. Patients with Alzheimer’s disease have fewer parvalbumin-positive interneurons. By showing that these neurons help strengthen new memories, these findings may explain why losing them can impair memory. Restoring or replacing interneuron activity could be a promising therapeutic avenue to explore.

Published

2017

15. Author response: Parvalbumin-positive interneurons mediate neocortical-hippocampal interactions that are necessary for memory consolidation

Author

Frances Xia, Blake A. Richards, Kaori Takehara-Nishiuchi, Sheena A. Josselyn, Paul W. Frankland, and Matthew M Tran

Subjects

0301 basic medicine, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, biology, biology.protein, Memory consolidation, Hippocampal formation, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin

Published

2017

16. Irrelevance by inhibition: Learning, computation, and implications for schizophrenia

Author

Nathan Insel, Jordan Guerguiev, and Blake A. Richards

Subjects

0301 basic medicine, Computer science, Physiology, Action Potentials, Social Sciences, Nervous System, 0302 clinical medicine, Learning and Memory, Animal Cells, Medicine and Health Sciences, Psychology, lcsh:QH301-705.5, Neurons, Neuronal Plasticity, Ecology, Artificial neural network, Simulation and Modeling, Brain, Amygdala, Electrophysiology, medicine.anatomical_structure, Computational Theory and Mathematics, Modeling and Simulation, Excitatory postsynaptic potential, Cellular Types, Anatomy, Temporal difference learning, Research Article, Computer and Information Sciences, Neural Networks, Schizophrenia (object-oriented programming), Models, Neurological, Neurophysiology, Sensory system, Inhibitory postsynaptic potential, Research and Analysis Methods, Models, Biological, 03 medical and health sciences, Cellular and Molecular Neuroscience, Interneurons, Neuroplasticity, Mental Health and Psychiatry, Genetics, medicine, Learning, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Cognitive Psychology, Biology and Life Sciences, Neural Inhibition, Cell Biology, Models, Theoretical, 030104 developmental biology, lcsh:Biology (General), Cellular Neuroscience, Synapses, Schizophrenia, Cognitive Science, Neural Networks, Computer, Nerve Net, Neuroscience, 030217 neurology & neurosurgery

Abstract

Symptoms of schizophrenia may arise from a failure of cortical circuits to filter-out irrelevant inputs. Schizophrenia has also been linked to disruptions in cortical inhibitory interneurons, consistent with the possibility that in the normally functioning brain, these cells are in some part responsible for determining which sensory inputs are relevant versus irrelevant. Here, we develop a neural network model that demonstrates how the cortex may learn to ignore irrelevant inputs through plasticity processes affecting inhibition. The model is based on the proposal that the amount of excitatory output from a cortical circuit encodes the expected magnitude of reward or punishment (“relevance”), which can be trained using a temporal difference learning mechanism acting on feedforward inputs to inhibitory interneurons. In the model, irrelevant and blocked stimuli drive lower levels of excitatory activity compared with novel and relevant stimuli, and this difference in activity levels is lost following disruptions to inhibitory units. When excitatory units are connected to a competitive-learning output layer with a threshold, the relevance code can be shown to “gate” both learning and behavioral responses to irrelevant stimuli. Accordingly, the combined network is capable of recapitulating published experimental data linking inhibition in frontal cortex with fear learning and expression. Finally, the model demonstrates how relevance learning can take place in parallel with other types of learning, through plasticity rules involving inhibitory and excitatory components, respectively. Altogether, this work offers a theory of how the cortex learns to selectively inhibit inputs, providing insight into how relevance-assignment problems may emerge in schizophrenia., Author summary Individuals with schizophrenia have difficulty ignoring ideas and experiences that most people would treat as unimportant. There is evidence that this may be due to changes in neuronal inhibition, suggesting that inhibitory neurons may be involved in learning to ignore irrelevant inputs. By developing a computational model that learns relevance and irrelevance through changes in the strength of feedforward inhibition, we are able to simulate many specific effects of inhibitory neuron dysfunction on behavior. We also show two computational advantages to this mechanism: (1) if relevance is signaled by the level of excitatory activity, then downstream circuits can easily avoid learning from irrelevant stimuli, (2) relevance learning can occur simultaneously with other types of learning. The model therefore offers insight into the relationships between neural inhibition and behavior, including symptoms of schizophrenia.

Published

2017

17. Author response: Towards deep learning with segregated dendrites

Author

Blake A. Richards, Jordan Guerguiev, and Timothy P. Lillicrap

Subjects

0301 basic medicine, Cognitive science, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, business.industry, Computer science, Deep learning, Artificial intelligence, business, 030217 neurology & neurosurgery

Published

2017

18. Neuronal chloride and excitability - the big impact of small changes

Author

Melanie A. Woodin, Joseph V Raimondo, and Blake A. Richards

Subjects

0301 basic medicine, Regulator, 03 medical and health sciences, 0302 clinical medicine, Chlorides, medicine, Humans, Receptor, Visual Cortex, Neurons, Neuronal Plasticity, Chemistry, GABAA receptor, General Neuroscience, fungi, food and beverages, Receptors, GABA-A, Monocular deprivation, 030104 developmental biology, Visual cortex, medicine.anatomical_structure, Synaptic plasticity, Excitatory postsynaptic potential, GABAergic, Neuroscience, 030217 neurology & neurosurgery

Abstract

Synaptic inhibition is a critical regulator of neuronal excitability, and in the mature brain the majority of synaptic inhibition is mediated by Cl−-permeable GABAA receptors. Unlike other physiologically relevant ions, Cl− is dynamically regulated, and alterations in the Cl− gradient can have significant impact on neuronal excitability. Due to changes in the neuronal Cl− concentration, GABAergic transmission can bidirectionally regulate the induction of excitatory synaptic plasticity and gate the closing of the critical period for monocular deprivation in visual cortex. GABAergic circuitry can also provide a powerful restraining mechanism for the spread of excitation, however Cl− extrusion mechanisms can become overwhelmed and GABA can paradoxically contribute to pathological excitation such as the propagation of seizure activity.

Published

2016

19. GABAergic circuits control stimulus-instructed receptive field development in the optic tectum

Author

Blake A. Richards, Oliver P. Voss, and Colin J. Akerman

Subjects

Superior Colliculi, Patch-Clamp Techniques, Time Factors, Motion Perception, Action Potentials, Sensory system, Neurotransmission, Biology, Stimulus (physiology), Synaptic Transmission, gamma-Aminobutyric acid, Article, 03 medical and health sciences, Motion, Xenopus laevis, 0302 clinical medicine, Neural Pathways, medicine, Animals, Motion perception, GABA-A Receptor Antagonists, gamma-Aminobutyric Acid, 030304 developmental biology, Neurons, 0303 health sciences, General Neuroscience, Signal Processing, Computer-Assisted, Receptors, GABA-A, nervous system, Receptive field, Larva, GABAergic, sense organs, Tectum, Neuroscience, 030217 neurology & neurosurgery, Photic Stimulation, medicine.drug

Abstract

During the development of sensory systems, receptive fields are modified by stimuli in the environment. This is thought to rely on learning algorithms that are sensitive to correlations in spike timing between cells, but the manner in which developing circuits selectively exploit correlations that are related to sensory inputs is unknown. We recorded from neurons in the developing optic tectum of Xenopus laevis and found that repeated presentation of moving visual stimuli induced receptive field changes that reflected the properties of the stimuli and that this form of learning was disrupted when GABAergic transmission was blocked. Consistent with a role for spike timing-dependent mechanisms, GABA blockade altered spike-timing patterns in the tectum and increased correlations between cells that would affect plasticity at intratectal synapses. This is a previously unknown role for GABAergic signals in development and highlights the importance of regulating the statistics of spiking activity for learning.

Published

2016

20. Memory Transformation Enhances Reinforcement Learning in Dynamic Environments

Author

Paul W. Frankland, Adam Santoro, and Blake A. Richards

Subjects

Memory, Episodic, Interference theory, Models, Neurological, Choice Behavior, Hippocampus, 050105 experimental psychology, 03 medical and health sciences, 0302 clinical medicine, Reward, Animals, Humans, 0501 psychology and cognitive sciences, Computer Simulation, Episodic memory, Research Articles, Adaptive memory, Distributed shared memory, Communication, Forgetting, business.industry, General Neuroscience, 05 social sciences, Memory map, Adaptation, Physiological, Memory, Short-Term, Mental Recall, Memory consolidation, Artificial intelligence, Implicit memory, business, Psychology, 030217 neurology & neurosurgery

Abstract

Over the course of systems consolidation, there is a switch from a reliance on detailed episodic memories to generalized schematic memories. This switch is sometimes referred to as “memory transformation.” Here we demonstrate a previously unappreciated benefit of memory transformation, namely, its ability to enhance reinforcement learning in a dynamic environment. We developed a neural network that is trained to find rewards in a foraging task where reward locations are continuously changing. The network can use memories for specific locations (episodic memories) and statistical patterns of locations (schematic memories) to guide its search. We find that switching from an episodic to a schematic strategy over time leads to enhanced performance due to the tendency for the reward location to be highly correlated with itself in the short-term, but regress to a stable distribution in the long-term. We also show that the statistics of the environment determine the optimal utilization of both types of memory. Our work recasts the theoretical question of why memory transformation occurs, shifting the focus from the avoidance of memory interference toward the enhancement of reinforcement learning across multiple timescales.SIGNIFICANCE STATEMENTAs time passes, memories transform from a highly detailed state to a more gist-like state, in a process called “memory transformation.” Theories of memory transformation speak to its advantages in terms of reducing memory interference, increasing memory robustness, and building models of the environment. However, the role of memory transformation from the perspective of an agent that continuously acts and receives reward in its environment is not well explored. In this work, we demonstrate a view of memory transformation that defines it as a way of optimizing behavior across multiple timescales.

Published

2016

21. Towards deep learning with segregated dendrites

Author

Blake A. Richards, Jordan Guerguiev, and Timothy P. Lillicrap

Subjects

0301 basic medicine, target propagation, QH301-705.5, Brain activity and meditation, Computer science, Process (engineering), Science, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, feedback alignment, neocortex, medicine, Biology (General), Cognitive science, Neocortex, General Immunology and Microbiology, Credit assignment, business.industry, General Neuroscience, Deep learning, Artificial networks, deep learning, food and beverages, General Medicine, Human brain, credit assignment, dendritic morphology, Artificial limbs, 030104 developmental biology, medicine.anatomical_structure, Quantitative Biology - Neurons and Cognition, FOS: Biological sciences, Medicine, Neurons and Cognition (q-bio.NC), Artificial intelligence, business, 030217 neurology & neurosurgery

Abstract

Deep learning has led to significant advances in artificial intelligence, in part, by adopting strategies motivated by neurophysiology. However, it is unclear whether deep learning could occur in the real brain. Here, we show that a deep learning algorithm that utilizes multi-compartment neurons might help us to understand how the brain optimizes cost functions. Like neocortical pyramidal neurons, neurons in our model receive sensory information and higher-order feedback in electrotonically segregated compartments. Thanks to this segregation, the neurons in different layers of the network can coordinate synaptic weight updates. As a result, the network can learn to categorize images better than a single layer network. Furthermore, we show that our algorithm takes advantage of multilayer architectures to identify useful representations---the hallmark of deep learning. This work demonstrates that deep learning can be achieved using segregated dendritic compartments, which may help to explain the dendritic morphology of neocortical pyramidal neurons., Comment: 41 pages, 11 figures

Published

2016

22. Visuospatial information in the retinotectal system of xenopus before correct image formation by the developing eye

Author

Colin J. Akerman, Blake A. Richards, and J J van Rheede

Subjects

Superior Colliculi, Patch-Clamp Techniques, genetic structures, Neurogenesis, Xenopus, Emmetropia, Eye, Xenopus laevis, 03 medical and health sciences, Cellular and Molecular Neuroscience, Glutamatergic, 0302 clinical medicine, Developmental Neuroscience, Neural Pathways, medicine, Animals, Focal length, Visual Pathways, 030304 developmental biology, Neurons, 0303 health sciences, biology, Anatomy, biology.organism_classification, eye diseases, medicine.anatomical_structure, Receptive field, Lens (anatomy), Visual Perception, Optic nerve, sense organs, Tectum, Neuroscience, 030217 neurology & neurosurgery

Abstract

The retinotectal pathway of Xenopus laevis is a well-established experimental model for studying activity-dependent processes during visual system development. Such processes can be guided by stimulus-evoked activity patterns, which depend on the refractive characteristics of the eye. Previous work has shown that many animals are hyperopic at early developmental stages due to immature refractive properties. Whether this is also the case for Xenopus laevis is unknown. Here, we measure the focal length of the lens and the size of the eye of embryos at different stages and find that Xenopus laevis exhibits a similar shift from hyperopia to emmetropia. At early stages, immediately after innervation of the tectum by the optic nerve, Xenopus embryos are hyperopic. Soon afterwards the focal length of the lens decreases and the eye converges to a state of emmetropia. Despite being hyperopic we find that some visuospatial information is available to the young circuit. Calculations based on the optical properties of the eye show that even when the animals are hyperopic the blurred retinal image provides a crude spatial resolution. Furthermore, using whole-cell recordings in the optic tectum combined with visual stimulation through the intact eye, we show that tectal neurons in hyperopic embryos have spatially restricted glutamatergic receptive fields. Our data demonstrate that Xenopus laevis eyes undergo a process of developmental emmetropization, and suggest that despite an initial stage of suboptimal image formation there is potentially enough information to guide activity-dependent refinements of the retinotectal pathway from the onset of vision. © 2011 Wiley Periodicals, Inc. Develop Neurobiol 72: 507–519, 2012

Published

2012

23. Can neocortical feedback alter the sign of plasticity?

Author

Blake A. Richards and Timothy P. Lillicrap

Subjects

0301 basic medicine, Neuronal Plasticity, Computer science, General Neuroscience, Neocortex, Plasticity, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Cortex (anatomy), medicine, Neuroscience, 030217 neurology & neurosurgery, Sign (mathematics)

Published

2018

24. Neurons are recruited to a memory trace based on relative neuronal excitability immediately before training

Author

Paul W. Frankland, Melanie A. Woodin, Blake A. Richards, Jessica C. Pressey, Adelaide P. Yiu, Chen Yan, Matthew M Tran, Hwa-Lin Liz Hsiang, Steven A. Kushner, Vivek Mahadevan, Sheena A. Josselyn, Asim J. Rashid, Valentina Mercaldo, and Psychiatry

Subjects

Male, Neuroscience(all), Engram, CREB, Amygdala, 03 medical and health sciences, 0302 clinical medicine, Memory, Conditioning, Psychological, medicine, Memory formation, Animals, Learning, Nervous System Physiological Phenomena, Cyclic AMP Response Element-Binding Protein, Transcription factor, Neuronal memory allocation, 030304 developmental biology, Neurons, 0303 health sciences, Neuronal Plasticity, biology, General Neuroscience, Fear, medicine.anatomical_structure, nervous system, biology.protein, Memory consolidation, Female, Neuron, Psychology, Neuroscience, 030217 neurology & neurosurgery

Abstract

SummaryMemories are thought to be sparsely encoded in neuronal networks, but little is known about why a given neuron is recruited or allocated to a particular memory trace. Previous research shows that in the lateral amygdala (LA), neurons with increased CREB are selectively recruited to a fear memory trace. CREB is a ubiquitous transcription factor implicated in many cellular processes. Which process mediates neuronal memory allocation? One hypothesis is that CREB increases neuronal excitability to bias neuronal recruitment, although this has not been shown experimentally. Here we use several methods to increase neuronal excitability and show this both biases recruitment into the memory trace and enhances memory formation. Moreover, artificial activation of these neurons alone is a sufficient retrieval cue for fear memory expression, showing that these neurons are critical components of the memory trace. These results indicate that neuronal memory allocation is based on relative neuronal excitability immediately before training.Video Abstract

Published

2014

25. In vivo spike-timing-dependent plasticity in the optic tectum of Xenopus laevis

Author

Blake A. Richards, Colin J. Akerman, and Carlos D. Aizenman

Subjects

animal structures, Xenopus, receptive field, synaptic development, Sensory system, Review Article, Biology, lcsh:RC321-571, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, In vivo, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, 030304 developmental biology, spike-timing-dependent plasticity, 0303 health sciences, Spike-timing-dependent plasticity, Cell Biology, Optic tectum, biology.organism_classification, Receptive field, Synaptic plasticity, visual system, optic tectum, sense organs, Tectum, Neuroscience, 030217 neurology & neurosurgery

Abstract

Spike-timing-dependent plasticity (STDP) is found in vivo in a variety of systems and species, but the first demonstrations of in vivo STDP were carried out in the optic tectum of Xenopus laevis embryos. Since then, the optic tectum has served as an excellent experimental model for studying STDP in sensory systems, allowing researchers to probe the developmental consequences of this form of synaptic plasticity during early development. In this review, we will describe what is known about the role of STDP in shaping feed-forward and recurrent circuits in the optic tectum with a focus on the functional implications for vision. We will discuss both the similarities and differences between the optic tectum and mammalian sensory systems that are relevant to STDP. Finally, we will highlight the unique properties of the embryonic tectum that make it an important system for researchers who are interested in how STDP contributes to activity-dependent development of sensory computations. © 2010 Richards, Aizenman and Akerman.

Published

2010