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6. Learning to Ignore: A Modeling Study of a Decremental Cholinergic Pathway and Its Influence on Attention and Learning

Author

Oros, Nicolas, Chiba, Andrea A., and Nitz, Douglas A.

Abstract

Learning to ignore irrelevant stimuli is essential to achieving efficient and fluid attention, and serves as the complement to increasing attention to relevant stimuli. The different cholinergic (ACh) subsystems within the basal forebrain regulate attention in distinct but complementary ways. ACh projections from the substantia innominata/nucleus basalis region (SI/nBM) to the neocortex are necessary to increase attention to relevant stimuli and have been well studied. Lesser known are ACh projections from the medial septum/vertical limb of the diagonal band (MS/VDB) to the hippocampus and the cingulate that are necessary to reduce attention to irrelevant stimuli. We developed a neural simulation to provide insight into how ACh can decrement attention using this distinct pathway from the MS/VDB. We tested the model in behavioral paradigms that require decremental attention. The model exhibits behavioral effects such as associative learning, latent inhibition, and persisting behavior. Lesioning the MS/VDB disrupts latent inhibition, and drastically increases perseverative behavior. Taken together, the model demonstrates that the ACh decremental pathway is necessary for appropriate learning and attention under dynamic circumstances and suggests a canonical neural architecture for decrementing attention.

Published
2014
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7. Linking global top-down views to first-person views in the brain.

Author

Jinwei Xing, Chrastil, Elizabeth R., Nitz, Douglas A., and Krichmar, Jeffrey L.

Subjects
TEMPORAL lobe, LATENT variables, COGNITIVE maps (Psychology)
Abstract

Humans and other animals have a remarkable capacity to translate their position from one spatial frame of reference to another. The ability to seamlessly move between topdown and first-person views is important for navigation, memory formation, and other cognitive tasks. Evidence suggests that the medial temporal lobe and other cortical regions contribute to this function. To understand how a neural system might carry out these computations, we used variational autoencoders (VAEs) to reconstruct the first-person view from the top-down view of a robot simulation, and vice versa. Many latent variables in the VAEs had similar responses to those seen in neuron recordings, including location-specific activity, head direction tuning, and encoding of distance to local objects. Place-specific responses were prominent when reconstructing a first-person view from a top-down view, but head direction–specific responses were prominent when reconstructing a top-down view from a first-person view. In both cases, the model could recover from perturbations without retraining, but rather through remapping. These results could advance our understanding of how brain regions support viewpoint linkages and transformations. [ABSTRACT FROM AUTHOR]

Published
2022
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14. Noncanonical projections to the hippocampal CA3 regulate spatial learning and memory by modulating the feedforward hippocampal trisynaptic pathway.

Author

Lin, Xiaoxiao, Amalraj, Michelle, Blanton, Crisylle, Avila, Brenda, Holmes, Todd C., Nitz, Douglas A., and Xu, Xiangmin

Subjects
SPATIAL memory, HIPPOCAMPUS (Brain), THETA rhythm, BACK propagation, REAR-screen projection
Abstract

The hippocampal formation (HF) is well documented as having a feedforward, unidirectional circuit organization termed the trisynaptic pathway. This circuit organization exists along the septotemporal axis of the HF, but the circuit connectivity across septal to temporal regions is less well described. The emergence of viral genetic mapping techniques enhances our ability to determine the detailed complexity of HF circuitry. In earlier work, we mapped a subiculum (SUB) back projection to CA1 prompted by the discovery of theta wave back propagation from the SUB to CA1 and CA3. We reason that this circuitry may represent multiple extended noncanonical pathways involving the subicular complex and hippocampal subregions CA1 and CA3. In the present study, multiple retrograde viral tracing approaches produced robust mapping results, which supports this prediction. We find significant noncanonical synaptic inputs to dorsal hippocampal CA3 from ventral CA1 (vCA1), perirhinal cortex (Prh), and the subicular complex. Thus, CA1 inputs to CA3 run opposite the trisynaptic pathway and in a temporal to septal direction. Our retrograde viral tracing results are confirmed by anterograde-directed viral mapping of projections from input mapped regions to hippocampal dorsal CA3 (dCA3). We find that genetic inactivation of the projection of vCA1 to dCA3 impairs object-related spatial learning and memory but does not modulate anxiety-related behaviors. Our data provide a circuit foundation to explore novel functional roles contributed by these noncanonical hippocampal circuit connections to hippocampal circuit dynamics and learning and memory behaviors. This study reveals extensive non-canonical synaptic inputs to dorsal hippocampal CA3 from ventral CA1, perirhinal cortex and subicular complex, and shows that genetic inactivation of projection from ventral CA1 to dorsal CA3 impairs object-related spatial learning and memory. [ABSTRACT FROM AUTHOR]

Published
2021
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16. Locomotor action sequences impact the scale of representation in hippocampus and posterior parietal cortex.

Author

Shelley, Laura E. and Nitz, Douglas A.

Subjects
*HIPPOCAMPUS (Brain), *EPISODIC memory, *PARIETAL lobe, *NEURONS
Abstract

The hippocampus and posterior parietal cortex are implicated in both episodic memory and encoding of position in an environment. In the present study, we examine the impact of locomotor behaviors associated with movement in both the horizontal and vertical dimensions on population activity patterns in these two brain structures. We utilized a five‐looped, squared spiral track containing stair segments, ramp segments, and flat segments. In addition to encoding locations along the full route, posterior parietal cortex population activity demonstrates strong pattern recurrence for similar action types at different locations in the environment. Additionally, posterior parietal and hippocampal neurons exhibit parallel modulation in the scale of representation that follows behavioral dynamics required for track traversal. These findings build on prior work examining spatial mapping in the vertical dimension and provide a better understanding of how a series of actions and visited locations can be coordinated in the generation of episodic memory. [ABSTRACT FROM AUTHOR]

Published
2021
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19. Retrosplenial cortex maps the conjunction of internal and external spaces.

Author

Alexander, Andrew S and Nitz, Douglas A

Subjects
*ANIMAL intelligence, *VISUAL cortex development, *SENSORY neurons, *BEHAVIORAL neuroscience, *NEUROLOGICAL disorders -- Immunological aspects
Abstract

Intelligent behavior demands not only multiple forms of spatial representation, but also coordination among the brain regions mediating those representations. Retrosplenial cortex is densely interconnected with the majority of cortical and subcortical brain structures that register an animal's position in multiple internal and external spatial frames of reference. This unique anatomy suggests that it functions to integrate distinct forms of spatial information and provides an interface for transformations between them. Evidence for this was found in rats traversing two different routes placed at different environmental locations. Retrosplenial ensembles robustly encoded conjunctions of progress through the current route, position in the larger environment and the left versus right turning behavior of the animal. Thus, the retrosplenial cortex has the requisite dynamics to serve as an intermediary between brain regions generating different forms of spatial mapping, a result that is consistent with navigational and episodic memory impairments following damage to this region in humans. [ABSTRACT FROM AUTHOR]

Published
2015
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20. Cell Assemblies of the Basal Forebrain.

Author

Tingley, David, Alexander, Andrew S., Quinn, Laleh K., Chiba, Andrea A., and Nitz, Douglas A.

Subjects
PROSENCEPHALON physiology, PREFRONTAL cortex, NEURAL circuitry, SENSORY neurons, MOTOR neurons, NEURAL stimulation, PHYSIOLOGY
Abstract

The basal forebrain comprises several heterogeneous neuronal subgroupings having modular projection patterns to discrete sets of cortical subregions. Each cortical region forms recurrent projections, via prefrontal cortex, that reach the specific basal forebrain subgroups from which they receive afferents. This architecture enables the basal forebrain to selectively modulate cortical responsiveness according to current processing demands. Theoretically, optimal functioning of this distributed network would be enhanced by temporal coordination among coactive basal forebrain neurons, or the emergence of "cell assemblies." The present work demonstrates assembly formation in rat basal forebrain neuronal populations during a selective attention task. Neuron pairs exhibited coactivation patterns organized within beta-frequency time windows (55 ms), regardless of their membership within distinct bursting versus nonbursting basal forebrain subpopulations. Thus, the results reveal a specific temporal framework for integration of information within basal forebrain networks and for the modulation of cortical responsiveness. [ABSTRACT FROM AUTHOR]

Published
2015
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21. Task-phase-specific dynamics of basal forebrain neuronal ensembles.

Author

Tingley, David, Alexander, Andrew S., Kolbu, Sean, de Sa Virginia, R., Chiba, Andrea A., and Nitz, Douglas A.

Subjects
PROSENCEPHALON, ATTENTION, CEREBRAL cortex, NEURODEGENERATION, COGNITION disorders, COGNITIVE ability, COGNITIVE neuroscience
Abstract

Cortically projecting basal forebrain neurons play a critical role in learning and attention, and their degeneration accompanies age-related impairments in cognition. Despite the impressive anatomical and cell-type complexity of this system, currently available data suggest that basal forebrain neurons lack complexity in their response fields, with activity primarily reflecting only macro-level brain states such as sleep and wake, onset of relevant stimuli and/or reward obtainment. The current study examined the spiking activity of basal forebrain neuron populations across multiple phases of a selective attention task, addressing, in particular, the issue of complexity in ensemble firing patterns across time. Clustering techniques applied to the full population revealed a large number of distinct categories of task-phase-specific activity patterns. Unique population firing-rate vectors defined each task phase and most categories of task-phase-specific firing had counterparts with opposing firing patterns. An analogous set of task-phase-specific firing patterns was also observed in a population of posterior parietal cortex neurons. Thus, consistent with the known anatomical complexity, basal forebrain population dynamics are capable of differentially modulating their cortical targets according to the unique sets of environmental stimuli, motor requirements, and cognitive processes associated with different task phases. [ABSTRACT FROM AUTHOR]

Published
2014
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22. Repeating Firing Fields of CAI Neurons Shift Forward in Response to Increasing Angular Velocity.

Author

Cowen, Stephen L. and Nitz, Douglas A.

Subjects
*NEURONS, *HIPPOCAMPUS (Brain), *ANGULAR velocity, *INFORMATION theory, *LABORATORY rats, *ANGULAR acceleration, *MEMORY
Abstract

Self-motion information influences spatially-specific firing patterns exhibited by hippocampal neurons. Moreover, these firing patterns can repeat across similar subsegments of an environment, provided that there is similarity of path shape and head orientations across subsegments. The influence of self-motion variables on repeating fields remains to be determined. To investigate the role of path shape and angular rotation on hippocampal activity, we recorded the activity of CAI neurons from rats trained to run on spiral-shaped tracks. During inbound traversais of circular-spiral tracks, angular velocity increases continuously. Under this condition, most neurons (74%) exhibited repeating fields across at least three adjacent loops. Of these neurons, 86% exhibited forward shifts in the angles of field centers relative to centers on preceding loops. Shifts were absent on squared-spiral tracks, minimal and less reliable on concentric-circle tracks, and absent on outward-bound runs on circular-spiral tracks. However, outward-bound runs on the circular-spiral track in the dark were associated with backward shifts. Together, the most parsimonious interpretation of the results is that continuous increases or decreases in angular velocity are particularly effective at shifting the center of mass of repeating fields, although it is also possible that a nonlinear integration of step counts contributes to the shift. Furthermore, the unexpected absence of field shifts during outward journeys in light (but not darkness) suggests visual cues around the goal location anchored the map of space to an allocentric reference frame. [ABSTRACT FROM AUTHOR]

Published
2014
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23. Adaptive integration of self-motion and goals in posterior parietal cortex.

Author

Alexander, Andrew S., Tung, Janet C., Chapman, G. William, Conner, Allison M., Shelley, Laura E., Hasselmo, Michael E., and Nitz, Douglas A.

Abstract

Rats readily switch between foraging and more complex navigational behaviors such as pursuit of other rats or prey. These tasks require vastly different tracking of multiple behaviorally significant variables including self-motion state. To explore whether navigational context modulates self-motion tracking, we examined self-motion tuning in posterior parietal cortex neurons during foraging versus visual target pursuit. Animals performing the pursuit task demonstrate predictive processing of target trajectories by anticipating and intercepting them. Relative to foraging, pursuit yields multiplicative gain modulation of self-motion tuning and enhances self-motion state decoding. Self-motion sensitivity in parietal cortex neurons is, on average, history dependent regardless of behavioral context, but the temporal window of self-motion integration extends during target pursuit. Finally, many self-motion-sensitive neurons conjunctively track the visual target position relative to the animal. Thus, posterior parietal cortex functions to integrate the location of navigationally relevant target stimuli into an ongoing representation of past, present, and future locomotor trajectories. [Display omitted] • Rats pursue moving visual targets and make predictions about their paths • Pursuit behavior enhances self-motion coding in parietal cortex via gain modulation • Pursuit increases timescale of instantaneous trajectory mappings in parietal cortex • Parietal cortex neurons conjunctively code self-motion and egocentric target position Alexander et al. examine rats pursuing visual targets and characterize emergent predictive behaviors. Relative to free exploration, pursuit elicits enhanced coding of self-motion in the parietal cortex over extended temporal durations. A subset of parietal cortex neurons code for self-motion state and egocentric position of the pursuit target simultaneously. [ABSTRACT FROM AUTHOR]

Published
2022
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24. Adult mouse basal forebrain harbors two distinct cholinergic populations defined by their electrophysiology.

Author

Unal, Cagri T., Golowasch, Jorge P., Zaborszky, Laszlo, Disney, Anita, Nitz, Douglas, and Eggermann, Emmanuel

Subjects
PROSENCEPHALON physiology, NERVOUS system, CHOLINERGIC receptors, CHOLINERGIC mechanisms, GREEN fluorescent protein genetics, FLUORESCENT polymers, ELECTROPHYSIOLOGY
Abstract

We performed whole-cell recordings from basal forebrain (BF) cholinergic neurons in transgenic mice expressing enhanced green fluorescent protein (eGFP) under the control of the choline acetyltransferase promoter. BF cholinergic neurons can be differentiated into two electrophysiologically identifiable subtypes: early and late firing neurons. Early firing neurons (~70%) are more excitable, show prominent spike frequency adaptation and are more susceptible to depolarization blockade, a phenomenon characterized by complete silencing of the neuron following initial action potentials. Late firing neurons (~30%), albeit being less excitable, could maintain a tonic discharge at low frequencies. In voltage clamp analysis, we have shown that early firing neurons have a higher density of low voltage activated (LVA) calcium currents. These two cholinergic cell populations might be involved in distinct functions: the early firing group being more suitable for phasic changes in cortical acetylcholine release associated with attention while the late firing neurons could support general arousal by maintaining tonic acetylcholine levels. [ABSTRACT FROM AUTHOR]

Published
2012
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25. A unified description of cerebellar inter-spike interval distributions and variabilities using summation of Gaussians.

Author

Chen, Yanqing and Nitz, Douglas A.

Subjects
*CEREBELLAR ataxia, *INVERSE Gaussian distribution, *PURKINJE cells, *INTERVAL analysis, *POISSON distribution, *ACTION potentials
Abstract

Neuronal inter-spike intervals (ISIs) have previously been described as Poisson, Gamma, inverse Gaussian or other unimodal distributions. We analyzed ISIs of rhythmic and arrhythmic neuronal spike trains in cerebellum recorded from freely behaving rats, and found that their distributions can be described as the summation or integration of multiple Gaussian distributions. The ISIs of rhythmic cerebellar Purkinje cells have a main Gaussian peak at a basic firing interval and exponentially reduced peaks at multiples of this firing period. ISIs of arrhythmic Purkinje cells can be modeled as the integration of multiple Gaussian distributions centered at continuous intervals with exponentially reduced peak amplitudes. The sources of variability are directly related to the relative timing of action potentials between neighboring cells since we show that irregularities of discharge in one cell are associated with the previous history of its discharge in time relative to another cell. Through relative phase analyses, we demonstrate that the shape and the mathematical form of the ISI distributions in cerebellum are direct result of dynamic interactions in the nearby neuronal network, in addition to intrinsic firing properties. The analysis in this paper provides a unified description of cerebellar inter-spike interval distributions which deviate from the usual Poisson assumptions. Our results suggest the existence of an intrinsic rhythmicity in cells exhibiting arrhythmic spike trains in cerebellum, and may identify an important source of variability in neuronal firing patterns that is relevant to the mechanism of neural computation in cerebellum. [ABSTRACT FROM AUTHOR]

Published
2011
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27. Adaptation of Prefrontal Cortical Firing Patterns and Their Fidelity to Changes in Action--Reward Contingencies.

Author

Kargo, William J., Szatmary, Botond, and Nitz, Douglas A.

Subjects
ANIMAL behavior, ACTION theory (Psychology), PREFRONTAL cortex, NEURONS, MICE
Abstract

Animals adapt action-selection policies when the relationship between possible actions and associated outcomes changes. Prefrontal cortical neurons vary their discharge patterns depending on action choice and rewards received and undoubtedly play a pivotal role in maintaining and adapting action policies. Here, we recorded neurons from the medial precentral subregion of mouse prefrontal cortex to examine neural substrates of goal-directed behavior. Discharge patterns were recorded after animals developed stable action-selection policies, wherein four possible action sequences were invariably related to different reward magnitudes and during adaptation to changes in the action-reward contingencies. During the adaptation period, when the same action sequence resulted in different reward magnitudes, many neurons (38%) exhibited significantly different discharge patterns for identical action sequences, well before reaching the reward site. In addition, trial-to-trial reliability of ensemble pattern production leading up to reward was found to vary both positively and negatively with increases and decreases in reward magnitude, respectively. Pairwise analyses of simultaneously recorded neurons revealed that decreased reliability in part reflected fluctuations between different ensemble activity patterns as opposed to within-pattern variability. Increases in reliability were related to an increased probability of both selecting highly rewarding actions and completing such actions without pause or reversal, whereas decreases in reliability were associated with the opposite pattern. Thus, we suggest that both the spatiotemporal pattern and fidelity of prefrontal cortical discharge are impacted by action- outcome relationships and that each of these features serve to adapt action choices and maintain behaviors leading to reward. [ABSTRACT FROM AUTHOR]

Published
2007
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28. Tracking Route Progression in the Posterior Parietal Cortex

Author

Nitz, Douglas A.

Subjects
*NERVOUS system, *NEUROSCIENCES, *PHYSIOLOGICAL control systems, *CENTRAL nervous system, *NAVIGATION, *HIPPOCAMPUS (Brain)
Abstract

Summary: Quick and efficient traversal of learned routes is critical to the survival of many animals. Routes can be defined by both the ordering of navigational epochs, such as continued forward motion or execution of a turn, and the distances separating them. The neural substrates conferring the ability to fluidly traverse complex routes are not well understood, but likely entail interactions between frontal, parietal, and rhinal cortices and the hippocampus. This paper demonstrates that posterior parietal cortical neurons map both individual and multiple navigational epochs with respect to their order in a route. In direct contrast to spatial firing patterns of hippocampal neurons, parietal neurons discharged in a place- and direction-independent fashion. Parietal route maps were scalable and versatile in that they were independent of the size and spatial configuration of navigational epochs. The results provide a framework in which to consider parietal function in spatial cognition. [Copyright &y& Elsevier]

Published
2006
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29. Lateralized functional components of spatial cognition in the avian hippocampal formation: Evidence from single-unit recordings in freely moving homing pigeons.

Author

Siegel, Jennifer J., Nitz, Douglas, and Bingman, Verner P.

Abstract

Previous research has revealed that the functional components of spatial cognition are lateralized in the forebrain of birds, including the hippocampal formation (HF). To investigate how HF cells in the left and right avian brain may differentially participate in representations of space, we recorded single-units from the HF of homing pigeons as they ran a plus maze for food. The rate maps of left HF cells often displayed elongated regions of increased activity in the center of the maze and along the maze corridors, whereas right HF cells tended to display patches at the ends of maze arms at/near goal locations. Left HF cells displayed a higher degree of spatial-specificity compared with right HF cells, including higher patch-specificity, higher reliability, and a higher incidence of location-correlated activity. Analysis of speed-correlated and trajectory-dependent activity also revealed significant HF-lateralized differences. Right HF cells tended to display significant negative correlations between spike rate and speed, although speed-dependent rate maps indicate that this relationship did not explain their space-specific activity. Left HF cells displayed a significantly higher incidence of trajectory-dependent space-specific activity than was observed in the right HF, suggesting that left HF cells may participate in navigating among goal locations. Differences in the correlates of left and right pigeon HF cells are consistent with unilateral HF-lesion data suggesting that the functional components of spatial cognition are lateralized in the avian brain, and furthermore, provide a basis for hypotheses regarding how the left and right HF support different aspects of spatial cognition. © 2005 Wiley-Liss, Inc. [ABSTRACT FROM AUTHOR]

Published
2006
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30. Spatial-specificity of single-units in the hippocampal formation of freely moving homing pigeons.

Author

Siegel, Jennifer J., Nitz, Douglas, and Bingman, Verner P.

Abstract

The importance of space-specific single-unit activity for hippocampal formation (HF)-mediated learning and memory in rodents has been extensively studied, yet little is known about how the unit findings in rodents generalize to other vertebrate species. We report a first assessment of the space-specific single-unit activity recorded from the HF of homing pigeons as they moved through a plus maze for food reward. Rate maps of pigeon HF single-unit activity typically revealed multiple regions (2-5 per cell) of increased activity (on average, 2.5 times higher than other regions of the maze) that in 27% of slow-firing cells was reliably space-specific over time. The qualitative appearance of rate maps and the degree of spatial-specificity observed for most all pigeon HF cells suggests more modest space-specific activity than typically reported for rat hippocampal cells. The nature of space-specific activity in the pigeon HF includes (1) often transiently reliable regions of increased activity for many cells, (2) multiple patches of activity that were sometimes observed in analogous maze areas, and (3) cells displaying substantial decreases in firing rate between baseline and maze-run conditions that could not be explained by a simple relationship between firing rate and a pigeon's speed. These observations suggest that pigeon HF cells may be coding for an unspecified behavioral/motivational/environmental factors in addition to a pigeon's momentary location. The data further suggest that the spatial ecology and evolutionary history of different species may be a critical feature shaping how HF neurons capture properties of space. © 2004 Wiley-Liss, Inc. [ABSTRACT FROM AUTHOR]

Published
2005
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31. Improvements in the Signal-to-Noise Ratio of Motor Cortex Cells Distinguish Early versus Late Phases of Motor Skill Learning.

Author

Kargo, William J. and Nitz, Douglas A.

Subjects
*MOTOR cortex, *MOTOR learning, *LABORATORY rodents, *NEURAL circuitry, *MUSCLE cells
Abstract

There are numerous experience-driven changes in cortical circuitry that correlate with improved performance. Improved motor performance on a reach-to-grasp task in rodents is associated with changes in long-term potentiation (LTP), synaptogenesis, and movement representations in primary motor cortex (M1) by training days 3, 7, and 10, respectively. We recorded single-cell activity patterns in M1 during reach-to-grasp training to test how neural-spiking properties change with respect to LTP, synaptogenesis, and motor map changes. We also tested how neural-spiking changes relate directly to improved performance by monitoring muscle activity patterns. We found that signal-to-noise ratios (SNRs) of M1 spiking were significantly improved with practice but only after 7- 12 d. Three sources of noise were assessed: signal-dependent noise exemplified by the slope of the relationship between mean spike count and count variance per burst, signal-independent noise exemplified by the offset of this relationship, and background firing rates before and after bursts. Signal-independent noise and pre-burst firing rates were reduced with practice. Early performance gains (days 1-6) were dissociated from SNR improvements, whereas later performance gains (day 7-12) were related directly to the magnitude of improvement in both muscle recruitment reliability and success rates. With training, an increased number of cells exhibited firing rates that were correlated with muscle recruitment patterns, with lags suggesting a primary direction of influence from M1 to muscles. These results suggest a functional linkage from local synaptogenesis in M1 to improved spiking reliability of M1 cells to more reliable recruitment of muscles and finally to improved behavioral performance. [ABSTRACT FROM AUTHOR]

Published
2004
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32. Differential modulation of CA1 and dentate gyrus interneurons during exploration of novel environments.

Author

Nitz Douglas and McNaughton Bruce

Subjects
*DENTATE gyrus, *INTERNEURONS, *CELLS, *HIPPOCAMPUS (Brain)
Abstract

Parallel recordings of hippocampal principal cells and interneurons were obtained as rats foraged in familiar and adjacent, novel environments. Firing rates of each cell type were assessed as a function of spatial location. Many CA1 interneurons exhibited large decreases in activity in the novel compared with the familiar environment. Dentate gyrus interneurons, however, were much more likely to exhibit large increases in firing in the novel environment. Neither effect was correlated with basic interneuron discharge properties such as degree of theta modulation, baseline firing rate or degree of spatially modulated discharge. Both CA1 and dentate gyrus interneuron rate changes extended into regions of the familiar environment bordering the novel environment. Principal cells in CA1 and dentate gyrus exhibited similar patterns of place specific activity each being indicative of incorporation of novel spatial information into the spatial representation of the familiar environment. The data indicate that inhibitory networks in the CA1 and dentate gyrus areas are modulated in a divergent fashion during the acquisition of novel spatial information and that interneuron activities can be used to detect those regions of an environment subject to redistribution of principal cell spatial activity patterns. [ABSTRACT FROM AUTHOR]

Published
2004
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33. Early Skill Learning Is Expressed through Selection and Tuning of Cortically Represented Muscle Synergies.

Author

Kargo, William J. and Nitz, Douglas A.

Subjects
*CENTRAL nervous system, *BEHAVIOR genetics, *ABILITY, *LEARNING, *MUSCLES, *MOTOR cortex, *CELLS
Abstract

Skill learning may be based on integrating and adapting movement building blocks organized in the CNS. We examined at what level integration and adaptation occur during early skill learning, the level of individual muscles, muscle synergies or combinations of synergies through time, and whether these operations are expressed through the primary motor cortex (M1). Forelimb muscle and M1 cell activity were recorded over the first day of training on a reach-to-grasp task in rodents. Independent components analysis was used to assess how well muscle activation patterns could be described as time-varying combinations of synergies. In 3 of 11 animals, prereach M1 activity predicted the activation of different combinations of independent components (ICs) to perform the task. With training, animals increasingly adopted postures and prereach patterns of M1 activity that supported activation of the more successful combination. With training, animals also adjusted the activation magnitude (6 of 11 animals) and weights (11 of 11) of specific ICs that constituted the selected combination. Weights represent how IC activation patterns were distributed to forelimb muscles; this distribution pattern was adapted with training. M1 cells (37 of 100) had task-related firing rates that were significantly correlated with IC activation patterns. Changes in M1 firing rates were associated with corresponding changes in either the activation magnitude or weights of the correlated IC. Our data suggest that early skill learning is expressed through selection and tuning of M1 firing rates, which specify time-varying patterns of synergistic muscle contractions in the limb. [ABSTRACT FROM AUTHOR]

Published
2003
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34. Electrophysiological Correlates of Rest and Activity in Drosophila melanogaster

Author

Nitz, Douglas A., van Swinderen, Bruno, Tononi, Giulio, and Greenspan, Ralph J.

Subjects
*DROSOPHILA melanogaster, *ELECTROPHYSIOLOGY, *GENE expression
Abstract

Extended periods of rest in Drosophila melanogaster resemble mammalian sleep states in that they are characterized by heightened arousal thresholds and specific alterations in gene expression . Defined as inactivity periods spanning 5 or more min, amounts of this sleep-like state are, as in mammals, sensitive to prior amounts of waking activity, time of day, and pharmacological intervention . Clearly recognizable changes in the pattern and amount of brain electrical activity accompany changes in motor activity and arousal thresholds originally used to identify mammalian sleeping behavior . Electroencephalograms (EEGs) and/or local field potentials (LFPs) are now widely used to quantify sleep state amounts and define types of sleep. Thus, slow-wave sleep (SWS) is characterized by EEG spindles and large-amplitude delta-frequency (0–3.5 Hz) waves. Rapid-eye movement (REM) sleep is characterized by irregular gamma-frequency cortical EEG patterns and rhythmic theta-frequency (5–9 Hz) hippocampal EEG activity . It is unknown whether rest and activity in Drosophila are associated with distinct electrophysiological correlates. To address this issue, we monitored motor activity levels and recorded LFPs in the medial brain between the mushroom bodies, structures implicated in the modulation of locomotor activity, of Drosophila . The results indicate that LFPs can be reliably recorded from the brains of awake, moving fruit flies, that targeted genetic manipulations can be used to localize sources of LFP activity, and that brain electrical activity of Drosophila is reliably correlated with activity state. [Copyright &y& Elsevier]

Published
2002
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37. GABA release in the dorsal raphe nucleus: Role in the control of REM sleep.

Author

Nitz, Douglas and Siegel, Jerome

Subjects
*SEROTONINERGIC mechanisms, *SLEEP physiology, *GABA, *BIOCHEMICAL mechanism of action
Abstract

Tests the hypothesis that the cessation of firing of serotonergic dorsal raphe neurons is due to GABA. Cessation of this activity as a key controlling event of rapid eye movement (REM) sleep; Indication that REM sleep is accompanied by a selective increase in GABA.

Published
1997
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38. GABA release in posterior hypothalamus across sleep-wake cycle.

Author

Nitz, Douglas and Siegel, Jerome M.

Subjects
*AMINOBUTYRIC acid, *GLUTAMIC acid, *GLYCINE, *SLEEP-wake cycle
Abstract

Studies whether glutamate, glycine, and gamma-aminobutyric acid (GABA) concentrations in the posterior hypothalamus fluctuate as a function of sleep-wake state. Potential sources of inhibition or disfacilitation underlying the reduction of the PH unit activity during slow-wave sleep in the cat; Effects of GABA-receptor agonist muscimol.

Published
1996
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40. Spaces within spaces: rat parietal cortex neurons register position across three reference frames.

Author

Nitz, Douglas A

Subjects
*NEURONS, *HIPPOCAMPUS (Brain), *NERVOUS system, *LABORATORY rats, *NEUROSCIENCES
Abstract

We recorded parietal cortex neurons as rats traversed squared spiral tracks. Spatial firing patterns distinguished the behaviorally identical track segments composing loops, yet recurred with increasing or decreasing amplitude across the five loops composing the full track. These results indicate that parietal cortex neurons simultaneously respond to spatial relationships in multiple external reference frames, a phenomenon that may reflect a neural mechanism for relating parts to a whole. [ABSTRACT FROM AUTHOR]

Published
2012
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41. Crossing borders: sleep reactivation as a window on cell assembly formation.

Author

Nitz, Douglas and Cowen, Stephen

Subjects
*DECISION making, *ANIMAL behavior, *HIPPOCAMPUS (Brain), *SLEEP, *NEURONS
Abstract

The article focuses on a study regarding the associative connections between neurons and decision-making behavior of animals. Physiological investigations on the hippocampus were conducted to examine the preservation of behavior-induced correlations during sleep episodes. The spike-timing relationships between neuron pairs that maximize reactivation is determined.

Published
2008
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42. A place for motion in mapping.

Author

Nitz, Douglas

Subjects
*HIPPOCAMPUS (Brain), *VIRTUAL reality, *NEUROSCIENCES, *NEURONS
Abstract

The article presents the author's views on the study by M. Aghajan and colleagues on the role of various types of cues in map formation. It discusses how the study was conducted wherein multiple neuron recordings in hippocampus were combined with a method to implement virtual reality. The results reportedly revealed that cognitive map formation for virtual reality requires certain movement trajectories to be associated with peripheral landmark constellation.

Published
2015
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43. Spatially Periodic Activation Patterns of Retrosplenial Cortex Encode Route Sub-spaces and Distance Traveled.

Author

Alexander, Andrew S. and Nitz, Douglas A.

Subjects
*BRAIN physiology, *NEURONS, *NERVOUS system, *NEUROPHYSIOLOGY, *BRAIN function localization
Abstract

Summary Traversal of a complicated route is often facilitated by considering it as a set of related sub-spaces. Such compartmentalization processes could occur within retrosplenial cortex, a structure whose neurons simultaneously encode position within routes and other spatial coordinate systems. Here, retrosplenial cortex neurons were recorded as rats traversed a track having recurrent structure at multiple scales. Consistent with a major role in compartmentalization of complex routes, individual retrosplenial cortex (RSC) neurons exhibited periodic activation patterns that repeated across route segments having the same shape. Concurrently, a larger population of RSC neurons exhibited single-cycle periodicity over the full route, effectively defining a framework for encoding of sub-route positions relative to the whole. The same population simultaneously provides a novel metric for distance from each route position to all others. Together, the findings implicate retrosplenial cortex in the extraction of path sub-spaces, the encoding of their spatial relationships to each other, and path integration. [ABSTRACT FROM AUTHOR]

Published
2017
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44. Neuroscience: The inside story on place cells.

Author

Nitz, Douglas

Subjects
*PHYSIOLOGICAL aspects of cognition, *NEURONS, *ANIMAL locomotion, *ANIMAL mechanics, *HIPPOCAMPUS physiology, *NEUROSCIENCES, *CELLULAR mappings (Mathematics), *VIRTUAL reality
Abstract

The article presents a study led by David Tank, which provides evidence that examination of brain correlates of higher cognitive processes and identification of their causes at the cellular levels are possible. It emphasizes the study's demonstration of the membrane-potential dynamics of place cells, which are a subtype of pyramidal neuron that encode spatial information needed in guiding an animal's movement. It also explores the implications of the discovery of the place cells, involvement of the hippocampal region in the processes and phase precession to the field of neuroscience. Furthermore, it notes the integrated use of techniques in intracellular and extracellular recordings and in virtual reality simulations, as well as their implications to the study.

Published
2009
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45. Conjunctive coding in an evolved spiking model of retrosplenial cortex.

Author

Rounds, Emily L., Alexander, Andrew S., Nitz, Douglas A., and Krichmar, Jeffrey L.

Abstract

Retrosplenial cortex (RSC) is an association cortex supporting spatial navigation and memory. However, critical issues remain concerning the forms by which its ensemble spiking patterns register spatial relationships that are difficult for experimental techniques to fully address. We therefore applied an evolutionary algorithmic optimization technique to create spiking neural network models that matched electrophysiologically observed spiking dynamics in rat RSC neuronal ensembles. Virtual experiments conducted on the evolved networks revealed a mixed selectivity coding capability that was not built into the optimization method, but instead emerged as a consequence of replicating biological firing patterns. The experiments reveal several important outcomes of mixed selectivity that may subserve flexible navigation and spatial representation: (a) robustness to loss of specific inputs, (b) immediate and stable encoding of novel routes and route locations, (c) automatic resolution of input variable conflicts, and (d) dynamic coding that allows rapid adaptation to changing task demands without retraining. These findings suggest that biological retrosplenial cortex can generate unique, first-trial, conjunctive encodings of spatial positions and actions that can be used by downstream brain regions for navigation and path integration. Moreover, these results are consistent with the proposed role for the RSC in the transformation of representations between reference frames and navigation strategy deployment. Finally, the specific modeling framework used for evolving synthetic retrosplenial networks represents an important advance for computational modeling by which synthetic neural networks can encapsulate, describe, and predict the behavior of neural circuits at multiple levels of function. [ABSTRACT FROM AUTHOR]

Published
2018
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46. Rethinking retrosplenial cortex: Perspectives and predictions.

Author

Alexander, Andrew S., Place, Ryan, Starrett, Michael J., Chrastil, Elizabeth R., and Nitz, Douglas A.

Subjects
*CINGULATE cortex, *CHROMATIN-remodeling complexes, *PERSPECTIVE taking, *BRAIN anatomy, *FORECASTING
Abstract

The last decade has produced exciting new ideas about retrosplenial cortex (RSC) and its role in integrating diverse inputs. Here, we review the diversity in forms of spatial and directional tuning of RSC activity, temporal organization of RSC activity, and features of RSC interconnectivity with other brain structures. We find that RSC anatomy and dynamics are more consistent with roles in multiple sensorimotor and cognitive processes than with any isolated function. However, two more generalized categories of function may best characterize roles for RSC in complex cognitive processes: (1) shifting and relating perspectives for spatial cognition and (2) prediction and error correction for current sensory states with internal representations of the environment. Both functions likely take advantage of RSC's capacity to encode conjunctions among sensory, motor, and spatial mapping information streams. Together, these functions provide the scaffold for intelligent actions, such as navigation, perspective taking, interaction with others, and error detection. What is the retrosplenial cortex and what does it do? Alexander et al. discuss theories inspired by these questions and highlight their limitations. They propose that retrosplenial activity serves to relate spatial perspectives and to generate predictions about environmental interactions. [ABSTRACT FROM AUTHOR]

Published
2023
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47. Celebrating place cells.

Author

Nitz, Douglas

Subjects
*NEUROSCIENCES, *NONFICTION
Abstract

The article reviews the book "Hippocampal Place Fields: Relevance to Learning and Memory," edited by Sheri J. Y. Mizumori.

Published
2008
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48. Neurophysiological signatures of temporal coordination between retrosplenial cortex and the hippocampal formation.

Author

Alexander, Andrew S., Rangel, Lara M., Tingley, David, and Nitz, Douglas A.

Abstract

Retrosplenial cortex (RSC) is heavily interconnected with a multitude of cortical regions and is directly connected with the hippocampal formation. As such, it is a likely coordinator of information transfer between the hippocampus (HPC) and cortex in the service of spatial cognition and episodic memory. The current work examined three potential temporal frameworks for retrosplenial-hippocampal communication, namely, theta frequency oscillations (6-12 Hz), sharp-wave/ripple events, and repeating, theta phase-locked shifts from low (30-65 Hz) to high (120-160 Hz) gamma frequency oscillations. From simultaneous recordings of single units and local field potentials (LFPs) in RSC and HPC, we report the presence of prominent theta, low-gamma, and high-gamma oscillations in the retrosplenial LFP. Retrosplenial and hippocampal theta rhythms were strongly coherent and subgroups of retrosplenial neurons exhibited either spiking at theta frequencies and/or spike-phase-locking to theta. Retrosplenial neurons were also phase-locked to local low- and high-gamma rhythms, and power in these frequency bands was coupled in a sequential fashion to specific phases of hippocampal and retrosplenial theta rhythms. Coordinated activity between the two regions also occurred during hippocampal sharp-wave/ripple events, where retrosplenial neuron populations were modulated in their spiking and retrosplenial LFPs exhibited sharp-wave-like events that co-occurred with those observed in HPC. These results identify several temporal windows of synchronization between RSC and HPC that may mediate cortico-hippocampal processes related to learning, memory, and spatial representation. [ABSTRACT FROM AUTHOR]

Published
2018
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49. Multiplexed oscillations and phase rate coding in the basal forebrain.

Author

Tingley, David, Alexander, Andrew S., Quinn, Laleh K., Chiba, Andrea A., and Nitz, Douglas

Subjects
*NEURONS, *PROSENCEPHALON, *BRAIN, *ORGANISMS, *NEUROPHYSIOLOGY
Abstract

The article focuses on a study which examines local field potentials and multiple single-neuron recordings in basal forebrain context of an orientation task taking place within circular arena. It mentions that complex behaviors demand temporal coordination among functionally distinct brain regions. It states that associative brain regions can integrate oscillatory inputs and transform them into sequence-specific outputs that are adaptive to pace with which organisms interact with environment.

Published
2018
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50. Degenerate mapping of environmental location presages deficits in object-location encoding and memory in the 5xFAD mouse model for Alzheimer's disease.

Author

Zhang, Hai, Chen, Lujia, Johnston, Kevin G., Crapser, Joshua, Green, Kim N., Ha, Nicole My-Linh, Tenner, Andrea J., Holmes, Todd C., Nitz, Douglas A., and Xu, Xiangmin

Subjects
*ALZHEIMER'S disease, *ENVIRONMENTAL mapping, *LABORATORY mice, *MEMORY disorders, *ANIMAL disease models
Abstract

A key challenge in developing diagnosis and treatments for Alzheimer's disease (AD) is to detect abnormal network activity at as early a stage as possible. To date, behavioral and neurophysiological investigations in AD model mice have yet to conduct a longitudinal assessment of cellular pathology, memory deficits, and neurophysiological correlates of neuronal activity. We therefore examined the temporal relationships between pathology, neuronal activities and spatial representation of environments, as well as object location memory deficits across multiple stages of development in the 5xFAD mice model and compared these results to those observed in wild-type mice. We performed longitudinal in vivo calcium imaging with miniscope on hippocampal CA1 neurons in behaving mice. We find that 5xFAD mice show amyloid plaque accumulation, depressed neuronal calcium activity during immobile states, and degenerate and unreliable hippocampal neuron spatial tuning to environmental location at early stages by 4 months of age while their object location memory (OLM) is comparable to WT mice. By 8 months of age, 5xFAD mice show deficits of OLM, which are accompanied by progressive degradation of spatial encoding and, eventually, impaired CA1 neural tuning to object-location pairings. Furthermore, depressed neuronal activity and unreliable spatial encoding at early stage are correlated with impaired performance in OLM at 8-month-old. Our results indicate the close connection between impaired hippocampal tuning to object-location and the presence of OLM deficits. The results also highlight that depressed baseline firing rates in hippocampal neurons during immobile states and unreliable spatial representation precede object memory deficits and predict memory deficits at older age, suggesting potential early opportunities for AD detecting. • In vivo longitudinal miniscope calcium imaging was applied in freely behaving 5xFAD mice. • Depressed CA1 neuronal activity and spatial encoding deficits develop at early stage. • Impaired circuit function precedes object location memory deficit in 5xFAD mice. • Impaired circuit function at early stage predicts future memory deficits. [ABSTRACT FROM AUTHOR]

Published
2023
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