The PROUST hypothesis: the embodiment of olfactory cognition

Jacobs, Lucia F.

doi:10.1007/s10071-022-01734-1

Cited by 6 publications

(4 citation statements)

References 145 publications

(212 reference statements)

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“…The FAM allows the ASIMOV agent to learn landmark features and rewarding items in its spatial environment, reproducing a potential early phase in the evolution of simpler episodic memory. In particular, the FAM shows how spatial cognitive mapping may have evolved from a simple olfactory learning system, much like how directional olfaction has been hypothesized as the basis for evolution of spatial cognitive mapping and hippocampal-like circuitry [9,10], and furthermore, it shows how autonoetic consciousness may have evolved from systems controlling decision-making in spatial foraging [11,12].…”

Section: Models Of Memorymentioning

confidence: 97%

Cognitive Mapping and Episodic Memory Emerge From Simple Associative Learning Rules

Gribkova,

Chowdhary,

Gillette

2024

Preprint

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Episodic memory enables animals to map contexts and environmental features in space and time but is underused in artificial intelligence (AI). Here we show how simple associative learning rules can be expanded to basic episodic memory in AI. We augment an agent-based foraging simulation, ASIMOV, modeled on the simple neuronal circuitry of an invertebrate forager, by adding a novel computational module for simple episodic memory, the Feature Association Matrix (FAM). The FAM is a set of computationally light, graph learning algorithms which functionally resemble the auto- and hetero-associative circuits of the hippocampus for episodic memory. In simulations, FAM enables highly efficient foraging and navigation and shows how higher-order conditioning mechanisms give rise to spatial cognitive mapping by chaining pair-wise associations and encoding them with additional contexts. Thus, FAM demonstrates a biologically inspired, bottom-up enhancement of AI for higher-order cognition.

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Section: Models Of Memorymentioning

confidence: 97%

Cognitive Mapping and Episodic Memory Emerge From Simple Associative Learning Rules

Gribkova,

Chowdhary,

Gillette

2024

Preprint

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“…Olfactory bulb, cortex, pallial amygdala, and other pallial structures are thought to have evolved as elaborations of the olfactory system, with the addition of more sensory inputs from complex exteroceptors such as mediate vision, audition, proprioception, and taste ( Reiner et al, 1998 ; Redgrave et al, 1999 ; Smeets et al, 2000 ; Aboitiz et al, 2003 ; Grillner et al, 2013 ; Aboitiz and Montiel, 2015 ; Jacobs, 2023 ). Functionally, these structures interact with each other and the subpallial striatum to integrate reward, motivation, affect, and memory to compute incentive for decision making and to place it in physical context with directional information.…”

Section: Vertebrate Nervous Systemsmentioning

confidence: 99%

“…Elaboration of olfactory systems and associated structures for odor learning is closely tied to the emergence of pallial structures. Directional olfaction may have formed the basis for the evolution of memory organization in the bilaterian brain, with hippocampal-like structures used for mapping and encoding the spatial distributions of novel odorants ( Jacobs, 2012 ; 2023 ). Further, the olfactory system is the only sensory system that bypasses the thalamus, a structure for multi-modal sensory relay; instead, the olfactory bulb projects directly to amygdala and piriform cortex, which are important for emotion and memory ( Kay and Sherman, 2007 ; Jacobs, 2023 ).…”

Section: Vertebrate Nervous Systemsmentioning

confidence: 99%

“…Directional olfaction may have formed the basis for the evolution of memory organization in the bilaterian brain, with hippocampal-like structures used for mapping and encoding the spatial distributions of novel odorants ( Jacobs, 2012 ; 2023 ). Further, the olfactory system is the only sensory system that bypasses the thalamus, a structure for multi-modal sensory relay; instead, the olfactory bulb projects directly to amygdala and piriform cortex, which are important for emotion and memory ( Kay and Sherman, 2007 ; Jacobs, 2023 ). Like the olfactory bulb, the SeN of Pleurobranchaea is notably dopaminergic and is richly innervated by the serotonergic neurons of the C-cluster.…”

Section: Vertebrate Nervous Systemsmentioning

confidence: 99%

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A common modular design of nervous systems originating in soft-bodied invertebrates

Gribkova,

Lee,

Brown

et al. 2023

Front. Physiol.

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Nervous systems of vertebrates and invertebrates show a common modular theme in the flow of information for cost-benefit decisions. Sensory inputs are incentivized by integrating stimulus qualities with motivation and memory to affect appetitive state, a system of homeostatic drives, and labelled for directionality. Appetitive state determines action responses from a repertory of possibles and transmits the decision to a premotor system that frames the selected action in motor arousal and appropriate postural and locomotion commands. These commands are then sent to the primary motor pattern generators controlling the motorneurons, with feedback at each stage. In the vertebrates, these stages are mediated by forebrain pallial derivatives for incentive and directionality (olfactory bulb, cerebral cortex, pallial amygdala, etc.) interacting with hypothalamus (homeostasis, motivation, and reward) for action selection in the forebrain basal ganglia, the mid/hindbrain reticular formation as a premotor translator for posture, locomotion, and arousal state, and the spinal cord and cranial nuclei as primary motor pattern generators. Gastropods, like the predatory sea slug Pleurobranchaea californica, show a similar organization but with differences that suggest how complex brains evolved from an ancestral soft-bodied bilaterian along with segmentation, jointed skeletons, and complex exteroceptors. Their premotor feeding network combines functions of hypothalamus and basal ganglia for homeostasis, motivation, presumed reward, and action selection for stimulus approach or avoidance. In Pleurobranchaea, the premotor analogy to the vertebrate reticular formation is the bilateral “A-cluster” of cerebral ganglion neurons that controls posture, locomotion, and serotonergic motor arousal. The A-cluster transmits motor commands to the pedal ganglia analogs of the spinal cord, for primary patterned motor output. Apparent pallial precursors are not immediately evident in Pleurobranchaea’s central nervous system, but a notable candidate is a subepithelial nerve net in the peripheral head region that integrates chemotactile stimuli for incentive and directionality. Evolutionary centralization of its computational functions may have led to the olfaction-derived pallial forebrain in the ancestor’s vertebrate descendants and their analogs in arthropods and annelids.

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Animal cognition, past present and future, a 25th anniversary special issue

Kelly

Lea

2022

Anim Cogn

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The PROUST hypothesis: the embodiment of olfactory cognition

Cited by 6 publications

References 145 publications

Cognitive Mapping and Episodic Memory Emerge From Simple Associative Learning Rules

Cognitive Mapping and Episodic Memory Emerge From Simple Associative Learning Rules

A common modular design of nervous systems originating in soft-bodied invertebrates

Animal cognition, past present and future, a 25th anniversary special issue

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