Adaptability to changes in temporal structure is fornix-dependent

Kwok, Sze Chai; Mitchell, Anna S.; Buckley, Mark J.

doi:10.1101/lm.038851.115

Cited by 10 publications

(6 citation statements)

References 46 publications

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“…By registering each event as it occurs, the hippocampal network continuously tracks the progression of events within an experience. This interpretation of the ongoing neural activity complements research showing that hippocampal lesions impair the ability to monitor recent choices [15,16,50] and to track events across time [11,13,14,20]. …”

Section: Resultssupporting

confidence: 63%

“…However, it is critical to note that these studies mark the few examples of hippocampal-dependent spatial cognition. Importantly, processing positional information alone does not seem to rely on the hippocampus [14,18–20] particularly when it can be egocentrically defined from the perspective of the stationary monkey [21]. Instead, the hippocampus seems to be required when spatial relationships between objects in allocentric space must be formed, and when spatially-distinct objects must be linked across time.…”

Section: Hippocampal Dependence In Spatial Tasksmentioning

confidence: 99%

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Spatial responses, immediate experience, and memory in the monkey hippocampus

Buffalo

2017

Current Opinion in Behavioral Sciences

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Debate about the function of the hippocampus often pits theories advocating for spatial mapping against those that argue for a central role in memory. This review addresses whether research in the monkey supports the view that processing spatial information is fundamental to the function of the hippocampus. In support of spatial processing theories, neurons in the monkey hippocampal formation have striking spatial tuning, and an intact hippocampus is necessary to effectively utilize allocentric spatial relationships. However, the hippocampus also supports non-spatial processes, as its neurons acutely respond to distinct task events and hippocampal damage disrupts both expedient task acquisition and the monitoring of ongoing events in non-spatial paradigms. The features that are shared between spatial and non-spatial hippocampal-dependent tasks point toward a common mechanism underlying hippocampal function that is independent of processing spatial information. We suggest that spatial information is only one facet of immediate experience represented by the hippocampus. The current data support the idea that the hippocampus tracks many aspects of ongoing experience and the primary role of the hippocampus may be in linking experienced events into unitary episodes.

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Section: Resultssupporting

confidence: 63%

Section: Hippocampal Dependence In Spatial Tasksmentioning

confidence: 99%

Spatial responses, immediate experience, and memory in the monkey hippocampus

Buffalo

2017

Current Opinion in Behavioral Sciences

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“…Hirsch & Segal, 1972;O'Keefe et al, 1975;Walker & Olton, 1979;Markowska et al, 1989;Murray et al, 1989;Aggleton et al, 1992;Gaffan, 1994;Ennaceur et al, 1996;Ennaceur & Aggleton, 1997;Parker & Gaffan, 1997;Whishaw & Tomie, 1997;Bussey et al, 2000;De Bruin et al, 2001;Easton et al, 2002;Buckley et al, 2004 andKwok, 2006;Kwok & Buckley, 2010;Kwok et al, 2015;Hodgetts et al, 2017Hodgetts et al, , 2018 Traditional Episodic Memory Tasks, e.g. WMS, CVLT, etc.…”

Section: Trace and Contextual Fear Conditioningmentioning

confidence: 99%

Dissecting the Fornix in Basic Memory Processes and Neuropsychiatric Disease: A Review

2020

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The fornix is the primary axonal tract of the hippocampus, connecting it to modulatory subcortical structures. This review reveals that fornix damage causes cognitive deficits that closely mirror those resulting from hippocampal lesions. In rodents and non-human primates, this is demonstrated by deficits in conditioning, reversal learning, and navigation. In humans, this manifests as anterograde amnesia. The fornix is essential for memory formation because it serves as the conduit for theta rhythms and acetylcholine, as well as providing mnemonic representations to deep brain structures that guide motivated behavior, such as when and where to eat. Diffusion imaging research is revealing that the fornix plays a key role in mild cognitive impairment and Alzheimer's Disease, and can potentially predict conversion from the former to the latter. Emerging imaging findings link perturbations in this structure to schizophrenia, mood disorders, and eating disorders, although more research is needed. Cutting-edge research is currently investigating how deep brain stimulation of the fornix can potentially halt memory loss, control epileptic seizures, and even improve mood.

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“…Additionally, the fornix is associated with recollection and recall in MRI studies (Rudebeck et al, 2009;Metzler-Baddeley et al, 2011) and has shown changes in patients with hippocampal lesions (Henson et al, 2016). Interestingly, causal evidence from humans and nonhuman primates further shows that transecting the UF or the fornix impairs cognitive performance in learning and memory tasks (D'Esposito et al, 1995;Aggleton et al, 2000;Gaffan, 2002;Browning and Gaffan, 2008;Tsivilis et al, 2008;Kwok et al, 2015). However, it remains unclear how learning new visuospatial information alters (sub)cortical connectivity, and how, following the loss of subcortical inputs to the cortex, this connectivity is rearranged.…”

Section: Introductionmentioning

confidence: 99%

Corticocortical and Thalamocortical Changes in Functional Connectivity and White Matter Structural Integrity after Reward-Guided Learning of Visuospatial Discriminations in Rhesus Monkeys

et al. 2020

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The frontal cortex and temporal lobes together regulate complex learning and memory capabilities. Here, we collected resting-state functional and diffusion-weighted MRI data before and after male rhesus macaque monkeys received extensive training to learn novel visuospatial discriminations (reward-guided learning). We found functional connectivity changes in orbitofrontal, ventromedial prefrontal, inferotemporal, entorhinal, retrosplenial, and anterior cingulate cortices, the subicular complex, and the dorsal, medial thalamus. These corticocortical and thalamocortical changes in functional connectivity were accompanied by related white matter structural alterations in the uncinate fasciculus, fornix, and ventral prefrontal tract: tracts that connect (sub)cortical networks and are implicated in learning and memory processes in monkeys and humans. After the well-trained monkeys received fornix transection, they were impaired in learning new visuospatial discriminations. In addition, the functional connectivity profile that was observed after the training was altered. These changes were accompanied by white matter changes in the ventral prefrontal tract, although the integrity of the uncinate fasciculus remained unchanged. Our experiments highlight the importance of different communication relayed among corticocortical and thalamocortical circuitry for the ability to learn new visuospatial associations (learning-to-learn) and to make reward-guided decisions.

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Adaptability to changes in temporal structure is fornix-dependent

Cited by 10 publications

References 46 publications

Spatial responses, immediate experience, and memory in the monkey hippocampus

Spatial responses, immediate experience, and memory in the monkey hippocampus

Dissecting the Fornix in Basic Memory Processes and Neuropsychiatric Disease: A Review

Corticocortical and Thalamocortical Changes in Functional Connectivity and White Matter Structural Integrity after Reward-Guided Learning of Visuospatial Discriminations in Rhesus Monkeys

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