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Paleocortex

The paleocortex, also referred to as the olfactory cortex or paleopallium, is a phylogenetically ancient subdivision of the characterized by a simpler cytoarchitecture consisting of three to five layers of neuronal cell bodies, in contrast to the six-layered . It represents an evolutionarily older form of cortical , emerging early in vertebrate as part of the , and is primarily dedicated to processing olfactory sensory information received directly from the . Anatomically, the paleocortex is located on the medial and inferior surfaces of the , encompassing key regions such as the (including the anterior and posterior portions), the , the periamygdaloid cortex, and the . These areas form a continuous sheet of tissue that lacks the granular input and output layers typical of , instead featuring a prominent superficial molecular layer, a middle layer, and a deep polymorphic layer. Phylogenetically, it predates the and is distinct from the even older (such as the hippocampal formation), bridging primitive sensory processing with more advanced limbic functions. Functionally, the paleocortex serves as the primary site for initial olfactory perception and , integrating sensory inputs to generate representations before relaying them to higher cortical areas like the for conscious evaluation. Through dense interconnections with limbic structures—including the for emotional valence assignment and the via the for contextual memory encoding—it contributes to associative learning, emotional responses to smells, and formation. Disruptions in paleocortical regions are implicated in neurological conditions such as , where they can act as seizure foci due to their hyperexcitable circuitry.

Definition and Classification

Etymology and Terminology

The term paleocortex originates from the Greek palaios (παλαιός), meaning "old," combined with the Latin cortex, denoting "bark" or "rind," highlighting its status as an ancient cortical structure in evolutionary terms. This nomenclature was first introduced by the Dutch comparative anatomist Cornelis Ubbo Ariëns Kappers in 1909, in his paper on the phylogenetic development of cortical regions, to designate the intermediate layer of olfactory-associated cortex that bridges more primitive and advanced forms. Kappers coined the term to extend the earlier binary classification of cerebral cortex into archicortex (from Greek archi-, meaning "chief" or "primitive," referring to the oldest hippocampal-related cortex) and neocortex (from Greek neo-, meaning "new," for the six-layered mammalian expansion), a distinction initially proposed by British anatomist Grafton Elliot Smith in 1898–1901 based on comparative studies of vertebrate brains. The terminology evolved further through early 20th-century cytoarchitectonic work, notably by in his 1909 monograph Vergleichende Lokalisationslehre der Großhirnrinde, where he incorporated Kappers' tripartite scheme (, , ) to classify cortical areas by laminar organization, emphasizing the paleocortex's three-layered structure as a key phylogenetic marker. Within this framework, the paleocortex is grouped under the broader category of (from Greek allo-, meaning "other," + cortex), a term formalized by German anatomist in 1926 to encompass all non-six-layered cortices, distinguishing them from the uniform isocortex (or neocortex).

Phylogenetic Position

The paleocortex represents a phylogenetically intermediate cortical structure within the telencephalon, positioned between the more primitive —such as the , which traces back to the medial in early vertebrates—and the more advanced , which arose through expansion of the in mammals. This intermediate status reflects its evolutionary emergence in early amniotes, where it evolved as a specialized olfactory processing region with a simpler laminar organization featuring three to five layers, contrasting with the six-layered . In mammals, the paleocortex fully developed to support enhanced olfactory integration, marking a key adaptation for survival in diverse environments. Across vertebrates, reveals the paleocortex's homologs as rudimentary olfactory areas in non-mammalian species. In reptiles, the lateral cortex serves as the primary homolog, receiving direct projections from the main and exhibiting a basic three-layered structure akin to the mammalian , the core component of paleocortex. Birds possess a reduced olfactory , with projections from the terminating primarily in the , a homolog of the mammalian paleocortex that is less elaborated compared to mammals due to the evolutionary emphasis on visual and auditory processing. These structures highlight the paleocortex's conservation as an ancient olfactory hub, present but less elaborated prior to mammalian diversification. However, the precise homologies between avian and mammalian pallial regions, including the olfactory areas, remain a topic of active , with molecular and connectomic studies providing new insights into conserved cell types. In the broader evolution of the telencephalon, the paleocortex constitutes the paleopallium, a subdivision dedicated to olfaction that contrasts with the (yielding the for and spatial functions) and the neopallium (evolving into the expansive for higher ). This tripartite organization of the underscores the paleocortex's role in bridging primitive sensory processing with more complex cortical integrations seen in later lineages.

Anatomy

Gross Locations

The paleocortex occupies specific macroscopic sites within the medial of the , encompassing the where the is located, the that includes the , and the at the base of the . The specifically resides at the junction of the temporal and frontal lobes, medial to the temporal stem and lining the banks of the entorhinal sulcus. The is embedded in the anterior portion of the medial , anterior to the parahippocampal cortex and posterior to the . Spatially, the paleocortex forms a transitional zone, bordering the six-layered laterally and the three-layered medially, reflecting its intermediate phylogenetic position. It receives primary input from the via the lateral , which runs along its medial boundary and links to adjacent structures like the and . Compared to other mammals, the paleocortex is more compact and regressed, consistent with reduced reliance on olfaction, and constitutes approximately 1-2% of the total cortical surface area. In contrast, rodents exhibit a more extensive paleocortex relative to their smaller .

Microscopic Structure

The paleocortex, exemplified by regions such as the , displays a simplified cytoarchitecture characterized by three primary layers, distinguishing it from the more elaborate six-layered . Layer I, the superficial molecular layer, consists mainly of with dendrites and afferent fibers, subdivided into sublayers Ia (receiving direct olfactory inputs) and Ib (containing cortico-cortical connections and ). Layer II comprises a dense band of pyramidal neurons, often fused with elements of layer III in a compact arrangement, while layer III forms a polymorphic deep layer with sparse, irregularly arranged cells and reduced differentiation compared to neocortical equivalents. This structure lacks a prominent internal granular layer IV, a hallmark of allocortical that reflects its evolutionary primitiveness. Neuronal composition in the paleocortex is dominated by pyramidal neurons, which serve as the principal excitatory projection cells, particularly concentrated in layer II where they form a high-density band of small to large somata with extensive dendritic arborizations. These pyramidal cells are accompanied by sparse cells functioning as inhibitory , primarily in layer I and scattered through deeper regions, contributing to local circuit modulation. Additionally, the paleocortex features a high density of centrifugal fibers originating from subcortical structures, such as the and , which innervate layer I to provide modulatory inputs that influence olfactory processing. This neuronal arrangement supports efficient feedforward and associative connectivity with fewer cell types than in . Histological staining methods reveal the paleocortex's simpler cytoarchitecture effectively. Nissl staining, which targets RNA-rich cell bodies, highlights the dense packing of pyramidal neurons in layer II as a prominent band of darkly stained somata, while underscoring the relative sparsity in layers I and III, with minimal differentiation of a granular layer IV. Golgi staining, by impregnating entire neurons with , delineates the full morphology of pyramidal cells, showcasing their apical dendrites extending into layer I and basal dendrites ramifying locally, thus emphasizing the reduced laminar complexity compared to the neocortex's six distinct layers. These techniques, applied to regions like the , confirm the transitional nature of paleocortical organization.

Major Subdivisions

The paleocortex is primarily composed of several key regions that form the core of the , each exhibiting distinct anatomical positions and structural characteristics within the . These subdivisions share a general three-to-five-layer but differ in their , patterns, and spatial arrangements, reflecting their specialized roles in olfactory pathways. The represents the largest subdivision of the paleocortex, occupying a prominent position in the and extending into the lateral olfactory gyrus on the inferior surface of the . It features a characteristic trilaminar structure with a superficial molecular layer, a dense layer, and a deeper polymorphic layer, and it receives direct projections from the lateral , establishing it as the primary cortical target for mitral and tufted cell axons from the . This region's extensive surface area and layered distinguish it from other paleocortical areas, with its anterior portion (prepiriform cortex) showing denser cellular packing compared to the posterior (postpiriform) segment. The constitutes another major paleocortical region, situated in the anteromedial aspect of the within the , encompassing Brodmann areas 28 and 34. It displays a more complex laminar pattern than the , with up to five layers including a prominent superficial layer II rich in stellate and pyramidal neurons, and it serves as a transitional zone between the olfactory cortex and the hippocampal formation through dense reciprocal connections with the and . Subregional variations include the medial entorhinal cortex with its modular columnar organization and the lateral entorhinal cortex featuring broader layer III projections, highlighting its role as an anatomical interface in cortico-hippocampal circuits. The is a significant subdivision located within the at the base of the , forming part of the ventral . It exhibits a three-layered structure similar to other paleocortical regions, receives direct olfactory inputs via the lateral , and integrates olfactory information with reward-related processing through connections to the and . Smaller but integral subdivisions include the periamygdaloid cortex and the anterior olfactory nucleus, both contributing to the olfactory integration network with unique connectivity profiles and thinner laminar arrangements. The periamygdaloid cortex is positioned adjacent to the on the medial aspect of the , forming a cortical extension of the amygdaloid complex with a reduced three-layer structure and direct inputs from the lateral , differing from adjacent regions in its denser superficial plexiform layer and selective projections to amygdaloid nuclei. In contrast, the anterior olfactory nucleus lies on the orbital surface of the , medial to the olfactory sulcus in the retrobulbar region, characterized by a less pronounced laminar differentiation and bilateral commissural connections that link the two hemispheres, setting it apart through its role in interhemispheric olfactory signal distribution.

Functions

Primary Olfactory Roles

The paleocortex serves as the primary cortical recipient of olfactory input, integrating signals directly from the mitral and tufted cells of the via the lateral olfactory tract (LOT), a myelinated bundle that bypasses thalamic relay stations unique among sensory pathways. This direct connectivity enables the paleocortex to initiate , where incoming odorant patterns from the are decoded into rudimentary representations through sparse neural ensembles in layer Ia of the . Initial odor discrimination occurs here via feedforward inhibition and recurrent excitation, allowing differentiation of similar odorants based on glomerular activation patterns relayed by LOT afferents. Unimodal processing in the paleocortex focuses exclusively on olfactory signals, with the —its largest subdivision—specialized for crude identification and . Pyramidal neurons in the piriform cortex's layer II integrate these inputs to form distributed objects, supporting generalization across mixtures and discrimination through normalized firing rates that emphasize identity over intensity. The subdivision contributes to early memory association, linking current odors to prior experiences via superficial pyramidal cells that encode temporal and contextual elements of olfactory stimuli. Reciprocal neural circuits between the paleocortex and () facilitate basic hedonic valuation of s, where piriform outputs converge with neurons to assign affective tags such as pleasantness or aversion. These bidirectional projections, including from anterior piriform to agranular insular , allow rapid modulation of odor perception based on reward signals, enabling adaptive responses like approach or avoidance without higher cognitive involvement.

Integration with Limbic System

The paleocortex, particularly through its entorhinal component, functions as a key relay hub for transmitting olfactory information to core limbic structures, including the and . The receives direct projections from the and other paleocortical regions, and both direct projections from the and indirect paths via the forward processed olfactory signals to the basolateral amygdala for emotional valuation and to the hippocampal formation for integration into traces. This pathway enables the tagging of odors with affective significance, such as associating scents with rewarding or aversive experiences, thereby linking sensory input to long-term emotional . Recent studies have identified that projections from the lateral to the basolateral amygdala play a key role in encoding incidental odor-taste associations during low-salience learning. Beyond basic sensory relay, these connections facilitate within the limbic framework, where paleocortical inputs modulate -mediated responses and hippocampal-dependent spatial navigation. For instance, olfactory signals routed via the to the can amplify threat detection, enhancing rapid emotional arousal and behavioral adaptation in potentially dangerous environments. Similarly, projections to the support the contextual embedding of odors in spatial maps, contributing to navigation tasks that incorporate olfactory landmarks for memory-guided orientation. Reciprocal feedback loops further underscore this integration, with centrifugal projections from limbic areas like the and influencing paleocortical activity to prioritize olfactory salience and . These inputs, originating from higher-order limbic , adjust the of olfactory representations in the entorhinal and piriform cortices, thereby enhancing the perceptual prominence of emotionally relevant odors during states of heightened or retrieval. Such bidirectional dynamics allow the to dynamically shape olfactory based on contextual demands.

Evolutionary and Developmental Aspects

Evolutionary Origins

The paleocortex, encompassing the such as the piriform region, originated as rudimentary structures in early tetrapods, particularly amphibians, where the lateral functioned as a basic hub for chemosensation. In amphibians, this lateral pallial region receives direct projections from the and processes chemical signals vital for detecting prey, predators, and mates in predominantly aquatic habitats. As tetrapods adapted to terrestrial environments around 360 million years ago, the structure expanded in reptiles, developing into a more elaborate olfactory cortex within the lateral to support enhanced detection of volatile airborne odors essential for survival on land. A marked elaboration of the paleocortex occurred during the early mammal evolution approximately 160 million years ago in the period, with further diversification during the radiation. This expansion coincided with early mammals' shift to nocturnal and lifestyles, where reliance on olfaction for , predator avoidance, and social communication became paramount amid competition from diurnally active reptiles. The resulting enlargement of the and associated paleocortical areas provided a selective advantage, enabling precise chemosensory discrimination in dark environments. In the primate lineage, diverging around 65 million years ago, the paleocortex experienced a substantial reduction in relative volume, accounting for less than 1% of total cortical volume in humans, driven by the evolutionary prioritization of visual processing for arboreal and diurnal adaptations. Nevertheless, this structure persists in for specialized roles, including the processing of pheromones that influence reproductive and social behaviors.

Embryonic Development

The paleocortex emerges during early human embryonic development from the telencephalic vesicles, which form as outgrowths of the prosencephalon (forebrain) around gestational weeks 5 to 6, marking the initial regionalization of the cerebral hemispheres. This stage involves the proliferation of neural progenitor cells in the ventricular zone of the telencephalon, setting the foundation for allocortical structures like the paleocortex, which derives from the rostral telencephalic wall adjacent to the olfactory primordia. By gestational week 8, the olfactory placode, a thickened ectodermal region, induces the formation of paleocortical primordia through signaling interactions that promote and axonal outgrowth toward the emerging . Key morphogenetic events follow, including the radial and tangential migration of neural progenitors from the paleocortical ventricular zone to establish a three-layer laminar structure by weeks 9 to 12, with initial differentiation of the superficial plexiform, , and deep layers observed around week 10. In the prosomeric model of patterning, the paleocortex is positioned within the rostral prosomeres (primarily prosomeres 4 and 5), reflecting its evolutionary as a ventral telencephalic derivative influenced by genes like Dlx5 expressed in the . Cell density in the prepiriform region (a key paleocortical area) peaks between weeks 18 and 27, followed by a decline as maturation advances, with glial elements marked by GFAP appearing earlier than in neocortical regions. Postnatally, refinements continue with the myelination of olfactory tracts and bulb projections, initiating in the first few months and reaching approximately 90% completion by age 2 years, enhancing signal conduction efficiency. , mediated by microglial activity and complement-dependent mechanisms, further shapes adult paleocortical during the first few years, eliminating excess synapses to refine olfactory-limbic . By age 2 to 3, these processes largely stabilize the paleocortex's functional architecture, aligning with the three-layer organization observed in maturity.

Clinical and Research Significance

Associated Pathologies

Damage to the paleocortex, particularly in regions such as the piriform and entorhinal cortices, is associated with olfactory disorders including anosmia and parosmia. Anosmia often results from head trauma that shears olfactory axons at the cribriform plate or directly impairs central olfactory processing in the paleocortex. Tumors, such as meningiomas in the uncus or olfactory groove, can compress or infiltrate paleocortical structures, leading to ipsilateral anosmia by disrupting olfactory pathways. Parosmia, characterized by distorted odor perception, has been linked to post-viral infections like COVID-19, with functional connectivity alterations in the piriform cortex contributing to aberrant smell processing. In neurodegenerative diseases, the exhibits early atrophy and pathology accumulation, which are hallmarks of progression. This atrophy begins in the preclinical stage, with significant neuronal loss in layer II of the correlating with Braak stage I-II tangle formation. pathology in the disrupts its connections to the , contributing to decline even in the absence of amyloid-beta accumulation. Epilepsy associations involve hyperexcitable circuits in the and , which can initiate . The , particularly the endopiriform nucleus, acts as a zone, promoting hypersynchronization and propagation through limbic networks in . Layer III neuronal loss in the enhances excitability, facilitating onset and correlating with duration and .

Neuroimaging and Studies

Functional magnetic resonance imaging (fMRI) has been instrumental in mapping functional activation within the paleocortex, particularly during odor perception tasks, by revealing patterns of activity in the primary olfactory cortex and its connections. For instance, studies employing event-related fMRI designs have demonstrated robust BOLD responses in the piriform and entorhinal cortices to olfactory stimuli, enabling the parcellation of these regions based on whole-brain functional connectivity profiles. Diffusion tensor imaging (DTI) complements fMRI by facilitating tractography of olfactory pathways, quantifying white matter integrity through metrics like fractional anisotropy to trace connections from the olfactory bulb through the paleocortex. Research using DTI has shown reduced anisotropy in these tracts in contexts of olfactory deficits, highlighting disruptions in paleocortical connectivity. Positron emission tomography (PET) with 18F-fluorodeoxyglucose (FDG) detects metabolic changes in the paleocortex associated with degeneration, such as hypometabolism in the entorhinal cortex during early Alzheimer's disease progression. These scans reveal altered glucose utilization patterns that correlate with cognitive impairment, providing a biomarker for neurodegenerative involvement. Landmark studies from the have leveraged high-resolution structural MRI to identify thinning as a reliable for , with longitudinal analyses showing accelerated atrophy rates predicting cognitive decline. For example, measurements of entorhinal thickness in cohorts demonstrated its sensitivity to preclinical changes, outperforming global hippocampal volume assessments. In models, optogenetic techniques have elucidated paleocortical circuit dynamics, such as the role of entorhinal projections in modulating hippocampal representations during spatial learning tasks. By selectively activating or inhibiting entorhinal neurons, these experiments revealed how layer-specific inputs drive and behavioral adaptation. Despite these advances, of the paleocortex faces significant challenges, including limited human studies due to the region's small size and susceptibility to motion artifacts, which complicate high-resolution imaging. Emerging applications of 7T MRI address these limitations by achieving laminar resolution, allowing differentiation of superficial and deep layer activity in the during memory tasks. Such ultra-high-field approaches have detected distinct activation patterns across cortical layers, offering insights into functional organization not feasible with lower-field scanners.