Modelling the influence of the hippocampal memory system on the oculomotor system

Abstract: Visual exploration is influenced by what we remember. Amnesic cases, who have damage to the hippocampus (HC) and/or extended medial temporal lobe (MTL), show alterations in their gaze patterns relative to neurologically intact adults on tasks of memory. Recent work has revealed an extensive set of polysynaptic connections between the hippocampus and oculomotor system. However, little is known about how activation within the HC may impact the oculomotor system. In the present work, we conducted simulations of t… Show more

“…[138][139][140] Additional models mimicked lesions to the network and subsequently examined the propagation of activity. 134 Lesions to hippocampal subfields did not generally influence activity propagation from the MTL cortices, which showed quite rapid signal resolution within oculomotor regions (<100 ms). Lesions in each of the PRC, ERC, and PHC resulted in slower signal from the hippocampus throughout the network and, ultimately, to oculomotor regions.…”

“…Additional models mimicked lesions to the network and subsequently examined the propagation of activity . Lesions to hippocampal subfields did not generally influence activity propagation from the MTL cortices, which showed quite rapid signal resolution within oculomotor regions (<100 ms).…”

“…Dysfunction in the hippocampus and the broader MTL leads to changes in the manner by which visual exploration unfolds . When such findings are considered alongside computational modeling research that details how neural activity may traverse the myriad of structural connections between the memory and oculomotor systems within the time of a gaze fixation, it becomes apparent that eye movements reveal the use of stored information on a moment‐to‐moment basis. The research we have reviewed here collectively aligns with theoretical accounts that suggest hippocampally mediated representations are used in service of multiple cognitive functions beyond memory, including allocating overt attention, biasing ongoing perceptual processing, and directing further actions .…”

“…133 Although hypotheses could be generated from the knowledge of structural connectivity regarding whether activity would be relatively faster or slower via one route over another, the temporal detail (e.g., within the time of a gaze fixation) of such information required direct or modeled examination of neural responses. Using a connectome-based model to simulate network dynamics, Ryan et al 134 examined the dissipation of activity from the memory system to oculomotor areas. Subregions of the hippocampus and regions of the MTL were each stimulated separately, and the resultant neural activity was observed as it traversed through the rest of the modeled brain.…”

The intersection between the oculomotor and hippocampal memory systems: empirical developments and clinical implications

“…[138][139][140] Additional models mimicked lesions to the network and subsequently examined the propagation of activity. 134 Lesions to hippocampal subfields did not generally influence activity propagation from the MTL cortices, which showed quite rapid signal resolution within oculomotor regions (<100 ms). Lesions in each of the PRC, ERC, and PHC resulted in slower signal from the hippocampus throughout the network and, ultimately, to oculomotor regions.…”

“…Additional models mimicked lesions to the network and subsequently examined the propagation of activity . Lesions to hippocampal subfields did not generally influence activity propagation from the MTL cortices, which showed quite rapid signal resolution within oculomotor regions (<100 ms).…”

“…Dysfunction in the hippocampus and the broader MTL leads to changes in the manner by which visual exploration unfolds . When such findings are considered alongside computational modeling research that details how neural activity may traverse the myriad of structural connections between the memory and oculomotor systems within the time of a gaze fixation, it becomes apparent that eye movements reveal the use of stored information on a moment‐to‐moment basis. The research we have reviewed here collectively aligns with theoretical accounts that suggest hippocampally mediated representations are used in service of multiple cognitive functions beyond memory, including allocating overt attention, biasing ongoing perceptual processing, and directing further actions .…”

“…133 Although hypotheses could be generated from the knowledge of structural connectivity regarding whether activity would be relatively faster or slower via one route over another, the temporal detail (e.g., within the time of a gaze fixation) of such information required direct or modeled examination of neural responses. Using a connectome-based model to simulate network dynamics, Ryan et al 134 examined the dissipation of activity from the memory system to oculomotor areas. Subregions of the hippocampus and regions of the MTL were each stimulated separately, and the resultant neural activity was observed as it traversed through the rest of the modeled brain.…”

The intersection between the oculomotor and hippocampal memory systems: empirical developments and clinical implications

“…For example, a recent study from Bone et al (2018) found that participants reinstated encoding-related EMs during stimulusfree visualization, and this reinstatement was positively correlated with whole-brain neural reactivation (i.e., similarity between image-specific patterns of brain activity evoked during perception and imagery), which in turn was correlated with objective (change detection performance) and subjective (vividness ratings) measures of memory. Gaze reinstatement that differentiates hits from misses for configurally similar scene images has also been correlated with activity in the hippocampus (Ryals, Wang, Polnaszek, & Voss, 2015), supporting the existence of a functional link between EMs and hippocampally-mediated relational memory processes (also see, Bicanski & Burgess, 2019;Kragel et al, 2019;Liu, Shen, Olsen, & Ryan, 2017;Nau, Julian, & Doeller, 2018;Ryan et al, 2018;Shen, Bezgin, Selvam, McIntosh, & Ryan, 2016;Voss, Bridge, Cohen, & Walker, 2017; for review, see Hannula, Ryan, & Warren, 2017). Thus, given that EMs and memory retrieval, and the neural networks underlying them, are intimately related, the present study used EM monitoring to assess the online reactivation of previously encoded stimuli during mnemonic discrimination of lure images via gaze reinstatement.…”

Eye movements support behavioral pattern completion

Erratum