Characterizing functional hippocampal pathways in a brain-based device as it solves a spatial memory task

Krichmar, Jeffrey L.; Nitz, Douglas A.; Gally, Joseph A.; Edelman, Gerald M.

doi:10.1073/pnas.0409792102

Cited by 79 publications

(46 citation statements)

References 40 publications

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“…Much attention has also been devoted to emulating navigation and orientation behavior. Examples abound and include visual homing inspired by how bees or wasps find their way back to their nests (12), cricket phonotaxis [how female crickets move toward the mating sounds of males in highly rugged and noisy environments (32)], and spatial memory formation by modeling place fields and head-direction cells which account for the sophisticated navigational skills of rodents (33). One of the important design principles implicitly exploited in the examples above is sensory-motor coordination (34); that is, the mutual coupling of sensing and acting.…”

Section: Embedded Neural Modelsmentioning

confidence: 99%

Self-Organization, Embodiment, and Biologically Inspired Robotics

Pfeifer

Lungarella

Iida

2007

Science

974

428

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Section: Embedded Neural Modelsmentioning

confidence: 99%

Self-Organization, Embodiment, and Biologically Inspired Robotics

Pfeifer

Lungarella

Iida

2007

Science

974

428

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“…We previously developed a method, called a backtrace procedure (7), that identifies functional pathways by choosing a particular reference neuronal unit at a specific time and recursively examining the previous activities of all neuronal units that caused the observed activity in that reference unit.…”

Section: Neuronal Responses and Synaptic Plasticity Duringmentioning

confidence: 99%

“…To provide a stringent test of this rule, we embodied a cerebellar model incorporating the rule in a brain-based device (BBD) (5)(6)(7)(8), which had to smoothly traverse a curved course outlined by a series of traffic cones. As in other neurorobotic systems (9)(10)(11)(12)(13), the behavior of such a BBD is guided by a simulated nervous system, incorporating features of vertebrate neuroanatomy and neurophysiology, which determine the device's interaction with the environment.…”

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confidence: 99%

A cerebellar model for predictive motor control tested in a brain-based device

McKinstry

Edelman

Krichmar

2006

Proc. Natl. Acad. Sci. U.S.A.

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The cerebellum is known to be critical for accurate adaptive control and motor learning. We propose here a mechanism by which the cerebellum may replace reflex control with predictive control. This mechanism is embedded in a learning rule (the delayed eligibility trace rule) in which synapses onto a Purkinje cell or onto a cell in the deep cerebellar nuclei become eligible for plasticity only after a fixed delay from the onset of suprathreshold presynaptic activity. To investigate the proposal that the cerebellum is a generalpurpose predictive controller guided by a delayed eligibility trace rule, a computer model based on the anatomy and dynamics of the cerebellum was constructed. It contained components simulating cerebellar cortex and deep cerebellar nuclei, and it received input from a middle temporal visual area and the inferior olive. The model was incorporated in a real-world brain-based device (BBD) built on a Segway robotic platform that learned to traverse curved paths. The BBD learned which visual motion cues predicted impending collisions and used this experience to avoid path boundaries. During learning, the BBD adapted its velocity and turning rate to successfully traverse various curved paths. By examining neuronal activity and synaptic changes during this behavior, we found that the cerebellar circuit selectively responded to motion cues in specific receptive fields of simulated middle temporal visual areas. The system described here prompts several hypotheses about the relationship between perception and motor control and may be useful in the development of general-purpose motor learning systems for machines. cerebellum ͉ computational model ͉ eligibility trace ͉ middle temporal visual area A recent theory of the cerebellum (1), consistent with much of the neurophysiological, behavioral, and imaging data regarding motor control, proposes that the cerebellum learns to replace reflexes with a predictive controller. This predictive controller produces a correct motor control signal earlier than less adaptive reflex responses. Numerous adaptive cerebellar functions are subject to this type of control, including eye-blink conditioning, the vestibular-ocular reflex, smooth pursuit eye movement, spinal nociceptive withdrawal reflex, grip force adjustments, arm movements, and saccadic eye movements. At present, however, the mechanisms responsible for this predictive capability are still debated. Proposals for such mechanisms include delay lines, spectral timing, oscillators, or dynamic recurrent activity in granule cells (for a review, see ref.2).It has been suggested that reflexive motor commands are used as error signals for the predictive controller and that they are delivered to the cerebellum by way of climbing fibers from the inferior olive (IO) (1, 3). Synaptic eligibility traces in the cerebellum have recently been proposed as a specific mechanism for such motor learning (4). Based on motor timing studies, Medina et al. (4) proposed an eligibility trace that is triggered by motion onset and tha...

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“…During maze navigation, journey-dependent responses emerged in Darwin XI's hippocampal neuronal units. Because the computational design of a BBD allows us to determine the detailed microcircuitry and synaptic activity of all neuronal units, we are able to trace structural and functional connections in complete detail by a procedure called backtrace analysis (16). In the present study, such an analysis of neural population activity revealed the differential contributions of the BBD's cortical sensory areas and hippocampus to the firing of journey-independent and -dependent neuronal units.…”

mentioning

confidence: 79%

Retrospective and prospective responses arising in a modeled hippocampus during maze navigation by a brain-based device

Fleischer

Gally

Edelman

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

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Recent recordings of place field activity in rodent hippocampus have revealed correlates of current, recent past, and imminent future events in spatial memory tasks. To analyze these properties, we used a brain-based device, Darwin XI, that incorporated a detailed model of medial temporal structures shaped by experience-dependent synaptic activity. Darwin XI was tested on a plus maze in which it approached a goal arm from different start arms. In the task, a journey corresponded to the route from a particular starting point to a particular goal. During maze navigation, the device developed place-dependent responses in its simulated hippocampus. Journey-dependent place fields, whose activity differed in different journeys through the same maze arm, were found in the recordings of simulated CA1 neuronal units. We also found an approximately equal number of journey-independent place fields. The journey-dependent responses were either retrospective, where activity was present in the goal arm, or prospective, where activity was present in the start arm. Detailed analysis of network dynamics of the neural simulation during behavior revealed that many different neural pathways could stimulate any single CA1 unit. That analysis also revealed that place activity was driven more by hippocampal and entorhinal cortical influences than by sensory cortical input. Moreover, journey-dependent activity was driven more strongly by hippocampal influence than journey-independent activity. episodic memory ͉ hippocampal anatomy ͉ place fields ͉ spatial learning ͉ backtrace P lace field activity reflecting past, present, and future events has been found in hippocampal responses of rodents performing spatial memory tasks (1-3). In studies using a plus maze, a journey consisted of a trajectory from one start arm to one goal arm, with a forced choice at the intersection. Place fields, for which activity varies in different journeys through the maze, are called journey-dependent, and place fields for which activity is present in multiple journeys through the same maze arm are called journey-independent. Journey-dependent responses are either retrospective, where neural activity is present in the goal arm after choice, or prospective, where neural activity is present in the start arm before choice.Place cell activity depends on the anatomy and detailed circuit connectivity of the hippocampal region and its surrounding areas. The input to the hippocampus consists of highly processed neocortical information from multiple sensory modalities, which converges onto the medial temporal lobe. After processing through the hippocampus and the entorhinal cortex, the output diverges in broad projections back to the neocortex (4, 5). Within the hippocampus itself, there are several levels of looping over different time scales (6-9). The looping of information within the hippocampus allows it to integrate sensory input over time, providing an essential basis for episodic memory (10).Although current recording techniques are of critical value in explorin...

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Characterizing functional hippocampal pathways in a brain-based device as it solves a spatial memory task

Cited by 79 publications

References 40 publications

Self-Organization, Embodiment, and Biologically Inspired Robotics

Self-Organization, Embodiment, and Biologically Inspired Robotics

A cerebellar model for predictive motor control tested in a brain-based device

Retrospective and prospective responses arising in a modeled hippocampus during maze navigation by a brain-based device

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