Your search keyword '"Emily L. Mackevicius"' showing total 15 results

1. An avian cortical circuit for chunking tutor song syllables into simple vocal-motor units

Author

Emily L. Mackevicius, Michael T. L. Happ, and Michale S. Fee

Subjects

Science

Abstract

Young songbirds learn to imitate their parents’ songs. Here, the authors find that, in baby birds, neurons in a brain region at the interface of auditory and motor circuits signal the onsets of song syllables during both tutoring and babbling, suggesting a specific neural mechanism for vocal imitation.

Published

2020

2. Self-organization of songbird neural sequences during social isolation

Author

Emily L Mackevicius, Shijie Gu, Natalia I Denisenko, and Michale S Fee

Subjects

zebra finch, neural sequences, calcium imaging, vocal learning, Medicine, Science, Biology (General), QH301-705.5

Abstract

Behaviors emerge via a combination of experience and innate predispositions. As the brain matures, it undergoes major changes in cellular, network, and functional properties that can be due to sensory experience as well as developmental processes. In normal birdsong learning, neural sequences emerge to control song syllables learned from a tutor. Here, we disambiguate the role of tutor experience and development in neural sequence formation by delaying exposure to a tutor. Using functional calcium imaging, we observe neural sequences in the absence of tutoring, demonstrating that tutor experience is not necessary for the formation of sequences. However, after exposure to a tutor, pre-existing sequences can become tightly associated with new song syllables. Since we delayed tutoring, only half our birds learned new syllables following tutor exposure. The birds that failed to learn were the birds in which pre-tutoring neural sequences were most ‘crystallized,’ that is, already tightly associated with their (untutored) song.

Published

2023

3. Neural learning rules for generating flexible predictions and computing the successor representation

Author

Ching Fang, Dmitriy Aronov, LF Abbott, and Emily L Mackevicius

Subjects

tufted titmouse, hippocampus, state-space model, recurrent neural network, plasticity, predictive coding, Medicine, Science, Biology (General), QH301-705.5

Abstract

The predictive nature of the hippocampus is thought to be useful for memory-guided cognitive behaviors. Inspired by the reinforcement learning literature, this notion has been formalized as a predictive map called the successor representation (SR). The SR captures a number of observations about hippocampal activity. However, the algorithm does not provide a neural mechanism for how such representations arise. Here, we show the dynamics of a recurrent neural network naturally calculate the SR when the synaptic weights match the transition probability matrix. Interestingly, the predictive horizon can be flexibly modulated simply by changing the network gain. We derive simple, biologically plausible learning rules to learn the SR in a recurrent network. We test our model with realistic inputs and match hippocampal data recorded during random foraging. Taken together, our results suggest that the SR is more accessible in neural circuits than previously thought and can support a broad range of cognitive functions.

Published

2023

4. Unsupervised discovery of temporal sequences in high-dimensional datasets, with applications to neuroscience

Author

Emily L Mackevicius, Andrew H Bahle, Alex H Williams, Shijie Gu, Natalia I Denisenko, Mark S Goldman, and Michale S Fee

Subjects

Zebra finch, sequence, matrix factorization, unsupervised, Medicine, Science, Biology (General), QH301-705.5

Abstract

Identifying low-dimensional features that describe large-scale neural recordings is a major challenge in neuroscience. Repeated temporal patterns (sequences) are thought to be a salient feature of neural dynamics, but are not succinctly captured by traditional dimensionality reduction techniques. Here, we describe a software toolbox—called seqNMF—with new methods for extracting informative, non-redundant, sequences from high-dimensional neural data, testing the significance of these extracted patterns, and assessing the prevalence of sequential structure in data. We test these methods on simulated data under multiple noise conditions, and on several real neural and behavioral data sets. In hippocampal data, seqNMF identifies neural sequences that match those calculated manually by reference to behavioral events. In songbird data, seqNMF discovers neural sequences in untutored birds that lack stereotyped songs. Thus, by identifying temporal structure directly from neural data, seqNMF enables dissection of complex neural circuits without relying on temporal references from stimuli or behavioral outputs.

Published

2019

5. Barcoding of episodic memories in the hippocampus of a food-caching bird

Author

Selmaan N Chettih, Emily L Mackevicius, Stephanie Hale, and Dmitriy Aronov

Abstract

Episodic memory, or memory of experienced events, is a critical function of the hippocampus. It is therefore important to understand how hippocampal activity represents specific events in an animal's life. We addressed this question in chickadees — specialist food-caching birds that hide food at scattered locations and use memory to find their caches later in time. We performed high-density neural recordings in the hippocampus of chickadees as they cached and retrieved seeds in a laboratory arena. We found that each caching event was represented by a burst of firing in a unique set of hippocampal neurons. These 'barcode-like' patterns of activity were sparse (

Published

2023

6. Spatial Tracking Across Time (STAT): Tracking Neurons Across In-Vivo Imaging Sessions through Optimizing Local Neighborhood Motion Consistency

Author

Shijie Gu, Emily L. Mackevicius, Michale S. Fee, and Pengcheng Zhou

Abstract

Chronic calcium imaging has become a powerful and indispensable tool for analyzing the long-term stability and plasticity of neuronal activity. One crucial step of the data processing pipeline is to register individual neurons across imaging sessions, which usually extend over a few days or even months, and show various levels of spatial deformation of the imaged field of view (FOV). Previous solutions align FOVs of all sessions first and then register the same neurons according to their shapes and locations [1, 2]. However, the FOV registration is computational intensive, especially in the case of nonrigid case.Here we propose a cell tracking method that does not require FOV image registration. Specifically, the algorithmSTAT(short forStayTogether,AlignTogether, and forSpatialTrackingAcrossTime) represents neurons from two sessions as two sets of neuronal centroids, uses point set registration (PSR) to find a spatially smooth transformation to align them while assigning correspondences. The optimization method iteratively updates between the general motion and individual neuron identity tracking, an idea seen in the computer vision literatures [3, 4]. Our method can be thought of as a specialization and simplification of these more general methods to calcium imaging neuron tracking.We validate STAT on datasets with simulated nonrigid motion that is hard to motion correct without extensive manual intervention. Next, we test STAT on experimental data from singing birds collected on three different days, and observe stable song-locked activity across days. An example use case of this package is reference [5].

Published

2023

7. An entorhinal-like region in food-caching birds

Author

Marissa C. Applegate, Konstantin S. Gutnichenko, Emily L. Mackevicius, and Dmitriy Aronov

Abstract

SUMMARYThe mammalian entorhinal cortex routes inputs from diverse sources into the hippocampus. This information is mixed and expressed in the activity of many specialized entorhinal cell types, which are considered indispensable for hippocampal function. However, functionally similar hippocampi exist even in non-mammals that lack an obvious entorhinal cortex, or generally any layered cortex. To address this dilemma, we mapped extrinsic hippocampal connections in chickadees, whose hippocampi are used for remembering numerous food caches. We found a well-delineated structure in these birds that is topologically similar to the entorhinal cortex and interfaces between the hippocampus and other pallial regions. Recordings of this structure revealed entorhinal-like activity, including border and multi-field grid-like cells. These cells were localized to the subregion predicted by anatomical mapping to match the dorsomedial entorhinal cortex. Our findings uncover an anatomical and physiological equivalence of vastly different brains, suggesting a fundamental nature of entorhinal-like computations for hippocampal function.

Published

2023

8. Author response: Neural learning rules for generating flexible predictions and computing the successor representation

Author

Ching Fang, Dmitriy Aronov, LF Abbott, and Emily L Mackevicius

Published

2022

9. Self-organization of songbird neural sequences during social isolation

Author

Emily L. Mackevicius, Shijie Gu, Natalia I. Denisenko, and Michale S. Fee

Subjects

education, behavior and behavior mechanisms, psychological phenomena and processes

Abstract

Behaviors emerge via a combination of experience and innate predis-positions. As the brain matures, it undergoes major changes in cellular, network and functional properties that can be due to sensory experience as well as developmental processes. In normal birdsong learning, neural sequences emerge to control song syllables learned from a tutor. Here, we disambiguate the role of experience and development in neural sequence formation by delaying exposure to a tutor. Using functional calcium imaging, we observe neural sequences in the absence of tutoring, demonstrating that experience is not necessary for the formation of sequences. However, after exposure to a tutor, pre-existing sequences can become tightly associated with new song syllables. Since we delayed tutoring, only half our birds learned new syllables following tutor exposure. The birds that failed to learn were the birds in which pre-tutoring neural sequences were most ‘crystallized’, that is, already tightly associated with their (untutored) song.

Published

2022

10. An avian cortical circuit for chunking tutor song syllables into simple vocal-motor units

Author

Emily L. Mackevicius, Michale S. Fee, and Michael T. L. Happ

Subjects

0301 basic medicine, Male, animal structures, Computer science, Science, Speech recognition, education, General Physics and Astronomy, Models, Biological, General Biochemistry, Genetics and Molecular Biology, Babbling, Article, Learning and memory, 03 medical and health sciences, Motor network, 0302 clinical medicine, Chunking (psychology), Motor system, Animals, Learning, Birdsong, lcsh:Science, TUTOR, computer.programming_language, Neurons, Multidisciplinary, Network models, Extramural, Age Factors, General Chemistry, Electrophysiology, Brain region, 030104 developmental biology, nervous system, behavior and behavior mechanisms, Auditory Perception, lcsh:Q, Female, Finches, Singing, Vocalization, Animal, computer, psychological phenomena and processes, 030217 neurology & neurosurgery

Abstract

How are brain circuits constructed to achieve complex goals? The brains of young songbirds develop motor circuits that achieve the goal of imitating a specific tutor song to which they are exposed. Here, we set out to examine how song-generating circuits may be influenced early in song learning by a cortical region (NIf) at the interface between auditory and motor systems. Single-unit recordings reveal that, during juvenile babbling, NIf neurons burst at syllable onsets, with some neurons exhibiting selectivity for particular emerging syllable types. When juvenile birds listen to their tutor, NIf neurons are also activated at tutor syllable onsets, and are often selective for particular syllable types. We examine a simple computational model in which tutor exposure imprints the correct number of syllable patterns as ensembles in an interconnected NIf network. These ensembles are then reactivated during singing to train a set of syllable sequences in the motor network., Young songbirds learn to imitate their parents’ songs. Here, the authors find that, in baby birds, neurons in a brain region at the interface of auditory and motor circuits signal the onsets of song syllables during both tutoring and babbling, suggesting a specific neural mechanism for vocal imitation.

Published

2019

11. Author response: Unsupervised discovery of temporal sequences in high-dimensional datasets, with applications to neuroscience

Author

Andrew H Bahle, Michale S. Fee, Emily L. Mackevicius, Alex H. Williams, Natalia Denisenko, Mark S. Goldman, and Shijie Gu

Subjects

Computer science, business.industry, Pattern recognition, High dimensional, Artificial intelligence, business

Published

2018

12. Growth and splitting of neural sequences in songbird vocal development

Author

Hannah L Payne, Michale S. Fee, Emily L. Mackevicius, Galen F. Lynch, Tatsuo S. Okubo, McGovern Institute for Brain Research at MIT, Okubo, Tatsuo, Mackevicius, Emily Lambert, Lynch, Galen Forest, and Fee, Michale Sean

Subjects

Male, Multidisciplinary, Extramural, Models, Neurological, Motor Cortex, Biology, biology.organism_classification, Article, 3. Good health, Songbird, medicine.anatomical_structure, Rhythm, nervous system, Neural Pathways, Feature (machine learning), medicine, Animals, Learning, Finches, Singing, Syllable, Vocalization, Animal, Neuroscience, Motor cortex, Sequence (medicine)

Abstract

Neural sequences are a fundamental feature of brain dynamics underlying diverse behaviours, but the mechanisms by which they develop during learning remain unknown. Songbirds learn vocalizations composed of syllables; in adult birds, each syllable is produced by a different sequence of action potential bursts in the premotor cortical area HVC. Here we carried out recordings of large populations of HVC neurons in singing juvenile birds throughout learning to examine the emergence of neural sequences. Early in vocal development, HVC neurons begin producing rhythmic bursts, temporally locked to a prototype syllable. Different neurons are active at different latencies relative to syllable onset to form a continuous sequence. Through development, as new syllables emerge from the prototype syllable, initially highly overlapping burst sequences become increasingly distinct. We propose a mechanistic model in which multiple neural sequences can emerge from the growth and splitting of a commo n precursor sequence., National Institutes of Health (U.S.) (Grant R01DC009183), National Science Foundation (U.S.) (Grant DGE-114747)

Published

2015

13. Building a state space for song learning

Author

Emily L. Mackevicius and Michale S. Fee

Subjects

0301 basic medicine, Neurons, Time Factors, biology, Computer science, General Neuroscience, Auditory area, Models, Neurological, Brain, biology.organism_classification, Songbird, Songbirds, 03 medical and health sciences, Bursting, 030104 developmental biology, 0302 clinical medicine, Neural Pathways, State space, Reinforcement learning, Animals, Learning, Vocalization, Animal, Neuroscience, Reinforcement, Psychology, 030217 neurology & neurosurgery

Abstract

The songbird system has shed light on how the brain produces precisely timed behavioral sequences, and how the brain implements reinforcement learning (RL). RL is a powerful strategy for learning what action to produce in each state, but requires a unique representation of the states involved in the task. Songbird RL circuitry is thought to operate using a representation of each moment within song syllables, consistent with the sparse sequential bursting of neurons in premotor cortical nucleus HVC. However, such sparse sequences are not present in very young birds, which sing highly variable syllables of random lengths. Here, we review and expand upon a model for how the songbird brain could construct latent sequences to support RL, in light of new data elucidating connections between HVC and auditory cortical areas. We hypothesize that learning occurs via four distinct plasticity processes: 1) formation of ‘tutor memory’ sequences in auditory areas; 2) formation of appropriately-timed latent HVC sequences, seeded by inputs from auditory areas spontaneously replaying the tutor song; 3) strengthening, during spontaneous replay, of connections from HVC to auditory neurons of corresponding timing in the ‘tutor memory’ sequence, aligning auditory and motor representations for subsequent song evaluation; and 4) strengthening of connections from premotor neurons to motor output neurons that produce the desired sounds, via well-described song RL circuitry.

Published

2017

14. Millisecond Precision Spike Timing Shapes Tactile Perception

Author

Matthew D. Best, Emily L. Mackevicius, Sliman J. Bensmaia, and Hannes P. Saal

Subjects

Male, Adolescent, media_common.quotation_subject, Somatosensory system, Vibration, Young Adult, Form perception, Perception, Physical Stimulation, Psychophysics, Animals, Humans, Neurons, Afferent, media_common, Skin, Communication, business.industry, General Neuroscience, Articles, Tactile perception, Neurophysiology, Macaca mulatta, Electrophysiological Phenomena, Form Perception, Touch Perception, Data Interpretation, Statistical, Female, Percept, Psychology, business, Neuroscience, Algorithms

Abstract

In primates, the sense of touch has traditionally been considered to be a spatial modality, drawing an analogy to the visual system. In this view, stimuli are encoded in spatial patterns of activity over the sheet of receptors embedded in the skin. We propose that the spatial processing mode is complemented by a temporal one. Indeed, the transduction and processing of complex, high-frequency skin vibrations have been shown to play an important role in tactile texture perception, and the frequency composition of vibrations shapes the evoked percept. Mechanoreceptive afferents innervating the glabrous skin exhibit temporal patterning in their responses, but the importance and behavioral relevance of spike timing, particularly for naturalistic stimuli, remains to be elucidated. Based on neurophysiological recordings from Rhesus macaques, we show that spike timing conveys information about the frequency composition of skin vibrations, both for individual afferents and for afferent populations, and that the temporal fidelity varies across afferent class. Furthermore, the perception of skin vibrations, measured in human subjects, is better predicted when spike timing is taken into account, and the resolution that predicts perception best matches the optimal resolution of the respective afferent classes. In light of these results, the peripheral representation of complex skin vibrations draws a powerful analogy with the auditory and vibrissal systems.

Published

2012

15. In Vivo Recording of Single-Unit Activity during Singing in Zebra Finches

Author

Michale S. Fee, Emily L. Mackevicius, Tatsuo S. Okubo, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, McGovern Institute for Brain Research at MIT, Okubo, Tatsuo S., Mackevicius, Emily Lambert, and Fee, Michale S.

Subjects

Male, Neurons, animal structures, Amplifiers, Electronic, Anatomy, Biology, Collision test, Implant surgery, Article, General Biochemistry, Genetics and Molecular Biology, Vocal production, Electrophysiological Phenomena, Antidromic, Electrophysiology, nervous system, Tape Recording, behavior and behavior mechanisms, Animals, Female, Finches, Vocalization, Animal, Singing, Neuroscience, Zebra finch

Abstract

The zebra finch is an important model for investigating the neural mechanisms that underlie vocal production and learning. Previous anatomical and gene expression studies have identified an interconnected set of brain areas in this organism that are important for singing. To advance our understanding of how these various brain areas act together to learn and produce a highly stereotyped song, it is necessary to record the activity of individual neurons during singing. Here, we present a protocol for recording single-unit activity in freely moving zebra finches during singing using a miniature, motorized microdrive. It includes procedures for both the microdrive implant surgery and the electrophysiological recordings. There are several advantages of this technique: (1) high-impedance electrodes can be used in the microdrive to obtain well-isolated single units; (2) a motorized microdrive is used to remotely control the electrode position, allowing neurons to be isolated without handling the bird, and (3) a lateral positioner is used to move electrodes into fresh tissue before each penetration, allowing recordings from well-isolated neurons over the course of several weeks. We also describe the application of the antidromic stimulation and the spike collision test to identify neurons based on the axonal projection patterns., National Institutes of Health (U.S.) (Grant R01DC009183), National Institutes of Health (U.S.) (Grant R01MH067105), Nakajima Foundation, Schoemaker Fellowship, United States. Dept. of Defense. National Defense Science & Engineering Graduate Fellowship Program

Published

2014