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Interneuron

Interneurons are a class of neurons primarily located in the central nervous system (CNS) that connect afferent sensory neurons, efferent motor neurons, and other interneurons, facilitating the local integration, processing, and modulation of neural signals within circuits.^[1]^[2] Unlike long-range projection neurons, interneurons typically feature short axons confined to specific brain regions or spinal cord segments, enabling precise local communication without direct interaction with the external environment.^[2] They form a fundamental component of all neural circuits, alongside sensory afferents and motor efferents, and are essential for coordinating responses such as reflex actions where inhibitory interneurons suppress opposing muscle groups to ensure smooth movement.^[2] Interneurons predominantly function as inhibitory elements, releasing neurotransmitters like gamma-aminobutyric acid (GABA) to dampen the excitability of target neurons and maintain a balance between excitation and inhibition in the CNS.^[3] This inhibition is critical for regulating overall network activity, preventing overstimulation, and supporting synchronized firing patterns that underlie brain rhythms, such as gamma oscillations involved in attention and cognition.^[3] Beyond inhibition, interneurons contribute to excitatory modulation in certain contexts, such as through acetylcholine release in select spinal or autonomic circuits, though these are less common in the mammalian cortex.^[4] The diversity of interneurons is one of their most striking features, encompassing variations in morphology, physiological properties, connectivity patterns, and molecular expression that allow for specialized roles in neural computation.^[3] In the cerebral cortex, for instance, interneurons are broadly classified into developmentally distinct groups, including those expressing parvalbumin (PV) for fast-spiking perisomatic inhibition, somatostatin (SST) for dendritic targeting and gain control, and vasoactive intestinal peptide (VIP) for disinhibition of principal cells to gate sensory inputs.^[3] This heterogeneity enables interneurons to execute complex tasks, from timing neural spikes for sensory processing to orchestrating network dynamics essential for learning, memory, and adaptive behavior.^[5]

Definition and Classification

Definition

Interneurons are a class of neurons found primarily within the central nervous system (CNS), functioning as local circuit neurons that transmit signals between sensory neurons, motor neurons, or other interneurons, without direct afferent or efferent projections to the periphery.^[6] They serve as intermediaries in neural processing, integrating and relaying information to coordinate complex behaviors and responses.^[7] Key characteristics of interneurons include typically short axons that confine their projections to specific brain regions or the spinal cord, distinguishing them from long-range projecting neurons. They can be either inhibitory, primarily using gamma-aminobutyric acid (GABA) to suppress neuronal activity, or excitatory, though inhibitory types predominate in many CNS areas. This local connectivity enables interneurons to fine-tune neural circuits by modulating the activity of connected neurons.^[5] Interneurons are prevalent across the vertebrate CNS, with their evolutionary development marked by increased diversity and density in more complex brains, such as those of mammals, where changes in migration patterns of inhibitory interneuron precursors contributed to the expansion of neocortical networks. Recent studies indicate that in humans, approximately 30-50% of cortical interneurons derive from local cortical progenitors, contributing further to neocortical complexity.^[8]^[9] In the human cerebral cortex, interneurons constitute approximately 20-30% of the total neuronal population, underscoring their essential role in cortical function.^[5]

Types

Interneurons are primarily classified based on their primary neurotransmitter, with GABAergic interneurons being the most common type, releasing gamma-aminobutyric acid (GABA) to provide inhibitory signaling within local circuits. These cells, such as basket cells and chandelier cells, form synapses that hyperpolarize target neurons, thereby modulating network excitability and preventing overactivation.^[10] In contrast, glutamatergic interneurons release glutamate as an excitatory neurotransmitter and are rarer overall, particularly in the cerebral cortex where they constitute a small fraction of local circuit neurons; however, they are more prominent in the hippocampus, exemplified by hilar mossy cells in the dentate gyrus that excite granule cells and interneurons to facilitate pattern separation and memory encoding.^[11] This dichotomy highlights the dual inhibitory and excitatory roles interneurons play in balancing neural activity. Morphological classification further diversifies interneuron types according to their dendritic and axonal arborization patterns. Axo-axonic interneurons, like chandelier cells, specifically target the axon initial segment of principal neurons to precisely control action potential initiation. Dendro-dendritic interneurons, which form synapses directly between dendrites, are less common and facilitate localized signaling without involving the soma. Multipolar interneurons, the most prevalent morphological class, possess multiple dendrites and a branched axon, enabling broad connectivity; examples include basket cells that envelop the soma of target cells and neurogliaform cells with diffuse axonal clouds for volume transmission.^[10] Neurochemical subtypes, often overlapping with morphological and physiological properties, provide additional granularity, particularly among GABAergic interneurons. Parvalbumin (PV)-expressing interneurons are fast-spiking cells that express calcium-binding proteins for rapid, precise inhibition, comprising about 40% of cortical GABAergic interneurons and supporting high-frequency oscillations. Somatostatin (SST)-expressing interneurons exhibit low-threshold spiking behavior, allowing activation by weak inputs, and often target distal dendrites to regulate burst firing and plasticity. Vasoactive intestinal peptide (VIP)-expressing interneurons, typically arising from different developmental origins, promote disinhibition by suppressing other inhibitory cells, thus enhancing excitatory drive in networks.^[10]^[12] Functionally, interneurons are grouped by their circuit roles and targeting specificity, influencing how inhibition shapes information flow. Feedback inhibition involves interneurons activated by the output of principal neurons to dampen recurrent excitation and maintain stability, often mediated by PV-positive cells. Feedforward inhibition, conversely, occurs when interneurons are excited by incoming afferents to preemptively constrain principal neuron responses, commonly via PV or SST subtypes. Targeting distinctions include perisomatic inhibition, where axons contact the soma and proximal dendrites for strong, soma-wide control (e.g., by basket cells), versus dendritic targeting, which modulates compartmentalized inputs on distal dendrites (e.g., by SST-positive Martinotti cells) to fine-tune synaptic integration.^[10]

Anatomy and Distribution

General Morphology

Interneurons in the central nervous system (CNS) are characterized by small to medium-sized cell bodies, typically measuring 10–20 μm in diameter, which support their role in local circuit processing.^[13] These somata often lack spines and exhibit aspiny or minimally spiny surfaces, distinguishing them from many projection neurons.^[14] Dendritic arborization is variable but generally extensive within local domains, allowing interneurons to integrate inputs from nearby principal neurons and fellow interneurons through multipolar or bipolar branching patterns that span tens to hundreds of micrometers.^[3] Axonal projections of interneurons are predominantly short and locally ramifying, forming dense, varicose arbors that remain confined to specific CNS layers or modules rather than extending over long distances.^[15] This morphology facilitates en passant synaptogenesis, where boutons along the axon shaft contact target structures without forming discrete terminal fields, enabling widespread but targeted inhibition within neural circuits.^[16] Common targets include the somata and proximal dendrites of principal neurons, promoting rapid modulation of output firing.^[17] Synaptic specializations in interneurons emphasize precision and efficiency, with axo-somatic and axo-dendritic contacts predominating to exert domain-specific control over postsynaptic excitability.^[17] These synapses often feature high densities of postsynaptic receptors, such as GABA_A for inhibitory transmission or AMPA/NMDA for excitatory inputs, supporting fast integration and feedback.^[18] For instance, parvalbumin-positive interneurons typically form perisomatic baskets around principal cell bodies.^[3] At the ultrastructural level, certain interneuron populations incorporate gap junctions, primarily composed of connexin-36, which enable direct electrical coupling and bidirectional current flow between coupled cells.^[19] This feature, observed in subsets like fast-spiking interneurons, enhances oscillatory synchrony without relying solely on chemical transmission.^[20]

Spinal Cord

Spinal cord interneurons form intricate networks essential for coordinating locomotor patterns and reflex arcs, distinct from higher brain regions by their direct involvement in segmental motor control. These neurons, primarily inhibitory, integrate sensory inputs and modulate motor neuron activity to ensure smooth, rhythmic movements such as walking or swimming. In mammals, they are classified into dorsal (dI) and ventral (V) groups based on embryonic origins, with key subtypes including Renshaw cells and Ia inhibitory interneurons that underpin recurrent and reciprocal inhibition mechanisms.^[21]^[22] Renshaw cells, a subtype of V1 interneurons, mediate recurrent inhibition by receiving excitatory input from motor neuron collaterals and releasing glycine to suppress the same or nearby motor neurons, preventing overexcitation during locomotion. Located predominantly in lamina VII of the ventral horn, these cells express transcription factors like MafB and calbindin, enabling their identification and role in feedback loops that fine-tune motor output. Ia inhibitory interneurons, also V1-derived, facilitate reciprocal inhibition by receiving input from Ia afferent fibers of muscle spindles and inhibiting antagonist motor neurons, thus alternating flexor and extensor activity essential for stepping. These subtypes emerge from p1 progenitors at distinct developmental times, with Renshaw cells differentiating earlier to support rapid reflex modulation.^[21]^[23]^[24] Interneurons are distributed across laminae I-VII, with dorsal populations in I-IV processing sensory signals and ventral ones in V-VII driving motor coordination; propriospinal interneurons, spanning multiple segments, bridge cervical, thoracic, and lumbar regions to integrate interlimb movements. In lamina VII, V1 and V2a interneurons cluster to form locomotor modules, while propriospinal neurons extend across at least one segment, often ipsilaterally or commissurally, to propagate signals over short or long distances within the cord. This laminar organization allows for hierarchical processing, where superficial laminae filter nociceptive and proprioceptive inputs before relaying to deeper motor circuits.^[22]^[25]^[26] Morphological adaptations in spinal interneurons support efficient segmental coordination, featuring longitudinal axons that run rostrocaudally for intersegmental communication and dense local collaterals that arborize within laminae to form compact inhibitory networks. Propriospinal interneurons exemplify this with extended axons connecting forelimb to hindlimb circuits, often accompanied by dendritic arbors in white matter for broad sensory integration. These features enable precise timing in reflex pathways, such as the stretch reflex, where short axonal projections ensure low-latency inhibition.^[25]^[26] Connectivity within central pattern generators (CPGs) relies on inhibitory loops formed by V0 and V1 interneurons, where commissural V0 neurons cross the midline to alternate left-right motor activity via glycinergic inhibition, and V1 subtypes like Renshaw and Ia cells enforce ipsilateral rhythmicity. These loops, embedded in lamina VII-VIII, generate oscillatory patterns independent of supraspinal input, with Renshaw-mediated feedback stabilizing bursts and Ia-driven reciprocal inhibition phasing flexor-extensor transitions during locomotion. Disruption of these connections, as seen in genetic ablations, impairs gait symmetry, underscoring their role in vertebrate motor control.^[27]^[22]^[28]

Cerebral Cortex

Interneurons in the cerebral cortex exhibit a highly organized laminar distribution that reflects their roles in local circuit processing, comprising approximately 20–30% of all cortical neurons.^[29] This proportion varies across regions, with lower densities in areas such as the hippocampus, where interneurons constitute approximately 10-15% of neurons.^[30] In the neocortex, these GABAergic cells are diverse, with distinct subtypes preferentially occupying specific layers to modulate excitatory pyramidal neuron activity through targeted inhibition. Layer-specific distribution is a hallmark of cortical interneuron organization. In layers II and III (supragranular layers), somatostatin (SST)-expressing interneurons, particularly Martinotti cells, are abundant, alongside vasoactive intestinal peptide (VIP)-expressing interneurons that often display bipolar morphologies. Layer IV, the primary thalamorecipient layer, is enriched with parvalbumin (PV)-positive basket cells, which provide perisomatic inhibition to spiny stellate and pyramidal neurons. In layers V and VI (infragranular layers), Martinotti cells predominate among SST+ interneurons, contributing to feedback inhibition within deeper cortical circuits.^[31] Morphological diversity among cortical interneurons enables precise targeting of postsynaptic structures. Chandelier cells, a subtype of PV+ interneurons, are characterized by their distinctive axonal arbors that form candelabra-like clusters specifically synapsing onto the axon initial segments of pyramidal neurons, thereby exerting powerful control over action potential initiation. Double bouquet cells, typically expressing calbindin, feature vertically oriented dendritic bundles and tightly packed axonal fascicles that extend across multiple layers, facilitating columnar inhibition. These morphologies underscore the structural adaptations for selective inhibitory connectivity in the cortex.^[32]^[33] Axonal patterns of cortical interneurons further delineate their laminar contributions. In supragranular layers, many interneurons, such as VIP+ bipolar cells and basket cells, exhibit horizontally spreading arbors that promote lateral inhibition within the same or adjacent cortical columns. In contrast, infragranular interneurons, including Martinotti and certain PV+ types, display more columnar axonal projections, often ascending to layer I or spanning vertically to integrate signals across layers and provide feedback modulation. This organization supports the hierarchical processing in sensory and motor cortical areas.^[31]

Cerebellum

In the cerebellar cortex, interneurons play a crucial role in refining motor coordination through precise inhibitory circuits that modulate the activity of principal neurons. The primary types are Golgi cells, located in the granular layer, and basket and stellate cells, which populate the molecular layer. Golgi cells provide inhibitory feedback to granule cells, while basket and stellate cells target Purkinje cells to shape their output timing and spatial precision, enabling error correction in motor learning. These interneurons integrate excitatory inputs from mossy and climbing fiber pathways, ensuring high-fidelity signal processing essential for smooth and accurate movements.^[34] Golgi cells reside in the granular layer and are characterized by large, round or polygonal somata measuring approximately 20-30 μm in diameter, with 4-10 short basal dendrites confined to the granular layer and longer apical dendrites extending into the overlying molecular layer in a fan-like arrangement. Their axons ramify extensively within the granular layer, forming synapses onto the dendrites of granule cells. In contrast, basket cells occupy the deeper portion of the molecular layer, featuring pyramidal or oval somata around 20 μm, with 4-10 straight dendrites ascending toward the pial surface; their axons descend parallel to the Purkinje cell layer, creating characteristic "pinceau" formations—brush-like inhibitory terminals encircling the soma and axon initial segment of Purkinje cells. Stellate cells, situated in the superficial two-thirds of the molecular layer, have smaller fusiform somata (7-10 μm) and exhibit long, contorted dendrites radiating in the plane parallel to the folia; their axons branch locally to form synapses on Purkinje cell dendrites, often aligning parallel to climbing fibers for targeted inhibition. These morphological adaptations, first detailed in ultrastructural studies, underscore the specialization of cerebellar interneurons for layered, planar wiring.^[34]^[35] Connectivity among these interneurons forms feedforward and feedback loops that enhance motor precision. Golgi cells receive excitatory inputs from mossy fibers and granule cell parallel fibers, in turn inhibiting granule cell dendrites via GABAergic synapses to regulate mossy fiber-granule cell excitation in a feedback manner, preventing overactivation and supporting adaptive gain control in motor circuits. Basket and stellate cells are excited by parallel fibers from granule cells, providing rapid feedforward inhibition to Purkinje cells—basket cells targeting somata for somatic shunting and stellate cells modulating dendritic integration—with latencies under 1 ms to refine spike timing. Additionally, these molecular layer interneurons form lateral inhibitory networks through chemical (GABA_A) and electrical (connexin-36 gap junctions) synapses, confining interactions to sagittal planes up to 350 μm, which sharpens spatial resolution for error signal correction in cerebellar learning. This circuitry, with a 10:1 interneuron-to-Purkinje cell ratio, ensures precise modulation of cerebellar output to deep nuclei, vital for coordinated locomotion and timing tasks.^[34]^[35]^[36]

Basal Ganglia

Interneurons in the basal ganglia, particularly within the striatum (comprising the caudate nucleus and putamen), play crucial modulatory roles in coordinating movement initiation and reward processing through their interactions with the dominant medium spiny neurons (MSNs) that form the direct and indirect pathways. These GABAergic interneurons constitute approximately 5-10% of striatal neurons and exert precise control over striatal output by providing inhibitory inputs that shape the balance between excitatory corticostriatal and dopaminergic signals from the substantia nigra. By regulating MSN excitability, striatal interneurons facilitate habit formation, action selection, and reinforcement learning, with disruptions linked to disorders like Parkinson's disease and addiction.^[37] The primary subtypes of striatal interneurons include fast-spiking parvalbumin-expressing (PV+) interneurons and low-threshold spiking (LTS) interneurons, the latter often co-expressing somatostatin (SST) and neuropeptide Y (NPY). PV+ fast-spiking interneurons are characterized by high-frequency firing and rapid synaptic kinetics, enabling them to suppress MSN activity during bursts of cortical input. LTS interneurons, in contrast, exhibit slower, adapting firing patterns with a prominent afterhyperpolarization and low-threshold spikes, allowing sustained modulation over longer timescales. These subtypes align with broader classifications of PV-expressing and SST-positive interneurons, respectively.^[38]^[39]^[13] Striatal interneurons are distributed across both the matrix (the larger, more uniform compartment) and patch (striosomal) compartments, with PV+ interneurons showing a relatively even presence in both, though with regional variations such as higher density in the dorsolateral striatum compared to dorsomedial regions. LTS interneurons are more dispersed, often spanning millimeters across compartments, contributing to widespread network effects. Overall, interneuron density is elevated in the caudate and putamen relative to ventral striatal areas, supporting their integration into motor and reward circuits.^[13]^[39]^[37] Morphologically, striatal interneurons feature aspiny dendrites that lack the spines typical of MSNs, allowing efficient reception of inputs without extensive compartmentalization, and extensive varicose axons that facilitate volume transmission of GABA and neuropeptides such as NPY and SST from LTS interneurons. These varicose structures enable diffuse signaling beyond traditional synaptic clefts, influencing neuronal ensembles over broader areas. In terms of connectivity, PV+ interneurons provide strong perisomatic feedforward inhibition to nearby MSNs, enforcing lateral inhibition that sharpens action selection, while LTS interneurons target distal dendrites of spatially separated MSNs, promoting coordinated suppression across the striatal network. Both subtypes receive dopaminergic inputs from the substantia nigra, which modulate their excitability—dopamine enhances PV+ interneuron firing to balance direct pathway activation during reward anticipation, whereas it suppresses LTS activity to disinhibit indirect pathway MSNs for movement facilitation.^[37]^[39]

Physiological Functions

Synaptic Integration

Interneurons integrate synaptic inputs through temporal and spatial summation of excitatory postsynaptic potentials (EPSPs) and inhibitory postsynaptic potentials (IPSPs), enabling them to process converging signals from principal neurons and other interneurons. Temporal summation occurs when successive EPSPs or IPSPs arrive in close proximity, incrementally depolarizing or hyperpolarizing the membrane potential to influence action potential firing thresholds. For instance, in hippocampal CA3 interneurons, clustered synaptic inputs facilitate summation that can trigger dendritic spikes for coincidence detection, where near-synchronous arrivals amplify responses beyond linear addition.^[40] This mechanism allows interneurons to detect temporal correlations in presynaptic activity, enhancing signal precision in feedforward and feedback circuits.^[41] Biophysical properties of interneurons underpin their integration capabilities, varying by subtype. Parvalbumin (PV)-expressing interneurons exhibit fast-spiking kinetics, characterized by narrow action potentials with widths typically less than 1 ms, enabling high-frequency firing up to several hundred Hz without significant fatigue.^[42] In contrast, somatostatin (SST)-expressing interneurons display spike-frequency adaptation during sustained depolarization, where initial high firing rates decline due to intrinsic potassium conductances, allowing them to modulate prolonged inputs rather than rapid transients.^[43] These properties ensure that PV interneurons provide precise, temporally locked inhibition, while SST interneurons exert more sustained control over dendritic compartments. Synaptic dynamics further shape integration in interneurons. Short-term plasticity at GABAergic synapses onto interneurons often manifests as depression in fast-spiking PV cells during high-frequency stimulation, reducing efficacy to prevent over-inhibition, whereas SST interneuron synapses show weaker depression or facilitation.^[44] Additionally, GABA spillover from synaptic clefts activates extrasynaptic receptors, generating tonic inhibition that broadly tunes interneuron excitability without phasic bursts, as observed in cortical networks where ambient GABA levels modulate baseline membrane conductance.^[45] Computationally, interneurons function as coincidence detectors or gain controllers in neural models. Dendritic spikes in interneurons enable nonlinear coincidence detection, where synchronized inputs trigger suprathreshold responses that principal neurons cannot achieve alone.^[46] As gain controllers, perisomatic PV inhibition often imposes subtractive effects, linearly shifting excitation-response curves, while distal SST inhibition yields divisive normalization, multiplicatively scaling output to contextualize sensory inputs—mechanisms validated in cortical models of visual processing.^[47] These roles highlight interneurons' capacity for single-cell computation, distinct from broader network synchronization.

Network Modulation

Interneurons play a pivotal role in shaping neural network dynamics through inhibitory motifs that refine population activity. In sensory cortices, such as the visual cortex, surround inhibition mediated by fast-spiking interneurons enhances the specificity of neuronal responses by suppressing activity in the non-classical receptive field, thereby sharpening the tuning of principal neurons' receptive fields.^[48] This mechanism increases inhibitory postsynaptic potentials by approximately 40% during simultaneous stimulation of classical and non-classical receptive fields, promoting sparse coding and improving signal-to-noise ratios.^[48] Additionally, disinhibitory circuits involving vasoactive intestinal peptide (VIP)-expressing interneurons preferentially target somatostatin (SST)-expressing interneurons, reducing their broad inhibition of pyramidal cells and thereby modulating network gain to favor responses to specific stimuli.^[49] This VIP-SST interaction forms a core motif across cortical layers, enabling context-dependent amplification of excitatory activity without direct excitation.^[49] Interneurons also drive oscillatory patterns that synchronize ensemble activity. Parvalbumin (PV)-expressing interneurons generate gamma oscillations (30-80 Hz) via their fast-spiking properties and reciprocal connections, which promote precise temporal coordination among principal neurons and enhance computational efficiency in cortical circuits. Optogenetic activation of PV interneurons induces gamma rhythms in vivo, while their suppression disrupts these oscillations, underscoring their necessity for rhythm generation. This synchrony arises from the low input resistance and rapid kinetics of PV cells, allowing them to impose rhythmic inhibition that entrains excitatory populations. Network modulation by interneurons extends to plasticity mechanisms that stabilize circuit function. Homeostatic scaling of inhibitory synapses, particularly in PV interneurons, adjusts the strength of GABAergic transmission to counteract perturbations in excitatory drive, thereby maintaining the excitation-inhibition (E/I) balance critical for network stability.^[50] This form of plasticity operates through divisive gain control, where PV-mediated inhibition dynamically tunes pyramidal cell excitability to preserve an approximate 20:80 E/I ratio across prefrontal and sensory networks.^[50] Specific examples illustrate these roles in distinct brain regions. In the hippocampus, interneurons, including PV-positive cells, underpin theta oscillations (4-12 Hz) by providing fast perisomatic inhibition that couples theta to gamma rhythms, facilitating temporal coding during spatial navigation.^[51] Ablation of GABA_A receptors in PV interneurons reduces theta power by several-fold and destabilizes rhythm frequency, highlighting their essential contribution.^[51] In the basal ganglia, cholinergic interneurons generate beta oscillations (13-30 Hz) through muscarinic receptor activation of striatal medium spiny neurons, supporting motor control by gating movement initiation and suppressing unwanted actions.^[52] These beta rhythms emerge from pause-burst firing patterns in cholinergic cells, synchronizing downstream circuits for coordinated motor output.^[52]

Development and Plasticity

Embryonic Origins

Interneurons, which constitute a diverse class of inhibitory neurons in the central nervous system, originate from specific progenitor domains during embryonic development. In the forebrain, cortical interneurons primarily derive from the subpallial ganglionic eminences. The medial ganglionic eminence (MGE) serves as the main source for parvalbumin (PV)-expressing and somatostatin (SST)-expressing subtypes, such as basket cells, chandelier cells, and Martinotti cells, while the caudal ganglionic eminence (CGE) generates vasoactive intestinal peptide (VIP)-expressing interneurons, including bipolar and multipolar varieties.^[53]^[31] A smaller proportion arises from the preoptic area, contributing to neurogliaform and neuropeptide Y (NPY)-positive interneurons. In contrast, spinal interneurons emerge from progenitor cells in the ventral ventricular zone of the neural tube, organized into distinct domains (p0 through p3) that give rise to specific subtypes like V0 commissural and V1 interneurons under the influence of homeodomain proteins such as Dbx1.^[54] The specification of interneuron fate is tightly regulated by transcription factors that direct progenitor differentiation toward a GABAergic lineage. In the ganglionic eminences, Dlx1 and Dlx2 homeobox genes play a pivotal role by promoting GABAergic neuron production through activation of enzymes like GAD1 and GAD2, which synthesize gamma-aminobutyric acid (GABA), while repressing alternative glial fates such as oligodendrocyte precursors via inhibition of Olig2 expression.^[55] Additional factors, including Nkx2.1 and Lhx6, further refine subtype identity in MGE-derived cells, ensuring PV+ and SST+ interneurons acquire their characteristic molecular profiles early in neurogenesis. These genetic programs operate within multipotent progenitors, balancing neuronal versus non-neuronal outcomes to generate the requisite diversity of interneurons.^[31] Following specification, interneuron progenitors undergo extensive tangential migration from their subpallial origins to integrate into pallial targets like the cortex and spinal cord. This long-distance journey, spanning hundreds of micrometers in rodents and even greater distances in humans, occurs primarily along three streams: the marginal zone, subventricular zone, and intermediate zone. Migration is orchestrated by chemokine signaling, notably CXCL12 (also known as SDF-1), which attracts interneurons via its receptors CXCR4 and CXCR7 on migrating cells, confining them to appropriate pathways and preventing premature invasion of the cortical plate.^[56] Disruptions in this guidance, as seen in receptor mutants, lead to reduced interneuron numbers in target areas and altered motility, underscoring the precision of these molecular cues.^[31] In humans, cortical interneuron birthdating occurs predominantly during embryonic weeks 6 to 20, with peak generation in mid-gestation around 10 to 15 weeks, as evidenced by progenitor proliferation markers like Nkx2.1 and Dlx2 in the ganglionic eminences.^[57] This timeline aligns with the expansion of the subventricular zone, where radial glia-like progenitors sustain neurogenesis into the second trimester. Spinal interneuron generation follows a similar ventral patterning but peaks earlier, during the initial neural tube closure and ventralization phases around embryonic days equivalent to human weeks 4 to 8. Although most production ceases by late gestation, some CGE-derived interneurons continue generating into the third trimester, contributing to the protracted human cortical development.^[58]

Maturation and Adaptability

Interneurons undergo significant postnatal maturation, particularly during critical periods in the first 2-3 weeks of life in rodents, when dendritic pruning refines their connectivity and perineuronal nets (PNNs) form to stabilize neural circuits. In rodents, this timeline aligns with heightened plasticity, where parvalbumin-positive (PV+) interneurons mature rapidly between postnatal days (P)10 and P20, involving activity-dependent refinement of dendritic arbors and synaptic inputs. Dendritic pruning peaks around P10-P15, driven by neuronal activity that eliminates excess branches to optimize inhibitory control over principal neurons. Concurrently, PNNs, composed of extracellular matrix components like chondroitin sulfate proteoglycans and hyaluronan, begin assembling around P10 and mature by P21, coinciding with the closure of critical periods such as ocular dominance plasticity in the visual cortex. This PNN formation limits further structural changes, transitioning interneurons from a plastic to a more stable state.^[59] Plasticity in interneurons manifests through Hebbian-like mechanisms, including long-term potentiation (LTP) and depression (LTD) at synapses with principal neurons, which support activity-dependent refinement and subtype diversification. In hippocampal interneurons, NMDA receptor-dependent Hebbian LTP occurs at Schaffer collateral synapses onto CA1 interneurons, requiring coincident pre- and postsynaptic firing to trigger Ca²⁺ influx and CaMKII activation, thereby enhancing feedforward inhibition. Anti-Hebbian LTP, independent of NMDA receptors, arises at local pyramidal-interneuron synapses via Ca²⁺-permeable AMPA receptors and mGluR1 activation when the interneuron is depolarized, often expressed presynaptically to modulate release probability. Corresponding LTD forms, such as NMDA-dependent LTD with intense depolarization, allow bidirectional adjustments that refine network dynamics. These processes contribute to activity-dependent diversification of PV+ interneuron subtypes, where a postnatal molecular switch involving PGC-1α (upregulated from P5, peaking at P12) cooperates with ERRγ and Mef2c to drive layer-specific maturation and gene expression by P21, enabling subtypes like those in cortical layer 4 versus layers 5/6 to adapt their electrophysiological and synaptic properties.^[60]^[61] Interneuron adaptability is evident in their responses to environmental enrichment or deprivation, which modulate plasticity during critical periods for sensory processing. Environmental enrichment accelerates interneuron maturation by increasing dendritic branching and spine density in sensory cortices, elevating BDNF levels to enhance synaptic plasticity and counteract deprivation effects, as seen in visual cortex development where it advances acuity and interneuron integration. Sensory deprivation, such as dark-rearing during P19-P35 in rats, delays GABAergic interneuron arborization and reduces astrocyte support, impairing circuit refinement but inducing cross-modal plasticity where non-deprived senses reorganize affected areas. PV+ interneurons play a pivotal role here, regulating critical period timing through GABAergic inhibition; their maturation initiates plasticity windows, while PNN dissolution can reinstate adult adaptability, as in auditory cortex responses to maternal cues that temporarily reduce PV+ activity to boost sensory tuning.^[62]^[63] With aging, interneurons exhibit a gradual decline in function, particularly PV+ subtypes, contributing to cognitive slowdown through structural simplification and reduced plasticity. In aged rodents and humans, PV+ interneurons show dendritic retraction and loss of spine density, markers of diminished adaptability that correlate with impaired gamma oscillations and working memory. This vulnerability arises from increased PNN density enclosing more neurons, restricting synaptic modifications and exacerbating excitatory-inhibitory imbalances that underlie age-related cognitive decline.^[64]^[65]

Pathophysiology and Research

Role in Disorders

Interneuron dysfunction contributes significantly to the pathophysiology of various neurological and psychiatric disorders, particularly through disruptions in inhibitory control that lead to network hyperexcitability or imbalanced excitation-inhibition (E/I) ratios.^[66] In epilepsy, particularly temporal lobe epilepsy (TLE), reduced inhibition from parvalbumin (PV)-expressing interneurons is a key factor promoting hyperexcitability and seizure propagation. Studies in human TLE patients and animal models reveal a selective loss or dysfunction of PV-positive interneurons in the hippocampus and entorhinal cortex, resulting in fewer synaptic boutons and diminished GABAergic inhibition onto principal neurons. This interneuron impairment lowers the seizure threshold, as optogenetic silencing of hippocampal PV interneurons exacerbates electrographic seizures, while their activation restores dentate inhibition and suppresses seizure activity.^[66]^[67]^[68] Schizophrenia is associated with deficits in somatostatin (SST)-expressing interneurons, which impair gamma oscillations critical for cognitive processes like working memory. Postmortem analyses of prefrontal cortex tissue from schizophrenia patients show reduced SST interneuron density and mRNA expression, correlating with weakened gamma-band synchrony and deficits in prefrontal-hippocampal communication. These SST interneuron alterations disrupt distal dendritic inhibition, leading to excessive pyramidal neuron excitability and impaired oscillatory coherence, as modeled in NMDA receptor hypofunction paradigms that mimic schizophrenia symptoms.^[69]^[70]^[71] In autism spectrum disorders (ASD), errors in the migration of caudal ganglionic eminence (CGE)-derived interneurons contribute to an imbalanced E/I ratio favoring excitation, underlying social and sensory processing deficits. Disruptions in tangential migration pathways, often linked to genetic mutations in ASD-risk genes like SHANK3 or MECP2, result in reduced numbers of CGE-derived interneurons (such as those expressing vasoactive intestinal peptide or reelin) populating superficial cortical layers. This leads to weakened perisomatic and dendritic inhibition, promoting network hyperexcitability and altered gamma oscillations observed in ASD brains, as evidenced by mouse models exhibiting autism-like behaviors due to interneuron migration defects.^[72]^[73]^[74] Neurodegenerative disorders like Parkinson's disease (PD) involve interneuron loss in the striatum, specifically fast-spiking interneurons (FSIs), which exacerbates motor circuit imbalances. In PD mouse models, early synaptic dysfunction and reduced PV-positive FSI activity disrupt the balance between direct and indirect pathway medium spiny neurons, contributing to beta oscillations and akinesia. These FSIs normally synchronize to maintain striatal E/I homeostasis, but dopamine depletion leads to their hypoactivity and desynchronization. Emerging therapeutic strategies, such as optogenetic activation of striatal interneurons, have shown promise in restoring circuit function and alleviating parkinsonian symptoms in preclinical models, highlighting interneurons as potential targets for neuromodulation.^[75]^[76]^[77]

Historical and Current Studies

The study of interneurons began in the late 19th century with Santiago Ramón y Cajal's pioneering use of Camillo Golgi's silver staining technique, which allowed visualization of individual neurons and led to the identification of local circuit neurons in the cerebral cortex and cerebellum during the 1890s.^[78] These short-axon cells, distinct from long projection neurons, were recognized as key components of neural circuits, laying the groundwork for understanding inhibitory local processing.^[79] In the mid-20th century, John C. Eccles advanced interneuron research through intracellular electrophysiology in the spinal cord during the 1950s, demonstrating how interneurons mediate presynaptic and postsynaptic inhibition of motor neurons.^[80] His recordings revealed mechanisms of reciprocal and recurrent inhibition, establishing interneurons as central to reflex modulation and earning him the 1963 Nobel Prize in Physiology or Medicine.^[81] Rafael Yuste's work in the 2000s utilized two-photon microscopy to map cortical microcircuits, highlighting the dense connectivity of GABAergic interneurons and their role in balancing excitation. Recent transcriptomic efforts by the Allen Brain Institute in the 2020s have generated high-resolution atlases from single-cell RNA sequencing, identifying over 50 interneuron subtypes across the mouse brain based on gene expression patterns. Optogenetic tools, developed in the 2010s, enable precise, real-time manipulation of specific interneuron populations in vivo, such as parvalbumin-expressing cells, to dissect their contributions to network oscillations.^[82] Similarly, CRISPR-Cas9 editing has been applied in recent developmental studies to screen genes regulating interneuron specification and migration in human stem cell-derived models.^[83] Despite these advances, research gaps persist, including incomplete mapping of interneuron diversity in regions like the hippocampus, where local circuit roles of certain subtypes remain underexplored.^[84] As of 2025, therapeutic trials for interneuron transplantation in epilepsy, such as the NRTX-1001 stem cell therapy, show promising safety and seizure reduction in drug-resistant temporal lobe epilepsy patients.^[85] These phase 1 studies, including implants at sites like the University of Chicago and UAMS, aim to restore inhibitory balance through grafted GABAergic cells.^[86]

References

[1]
Brain Basics: The Life and Death of a Neuron
Feb 25, 2025 · Other neurons, called interneurons, make connections between sensory and motor neurons. ... Scientists think that neurons are the most diverse ...
[2]
Neural Circuits - Neuroscience - NCBI Bookshelf - NIH
Nerve cells that only participate in the local aspects of a circuit are called interneurons or local circuit neurons. These three classes—afferent neurons, ...
[3]
Interneuron Cell Types: Fit to form and formed to fit - PMC
Interneurons possess the largest diversity in morphology, connectivity, and physiological properties.
[4]
Neuroscience For Kids - cells of the nervous system
Interneurons: send information between sensory neurons and motor neurons. Most interneurons are located in the central nervous system. Check out the Gallery ...
[5]
GENERATION OF DIVERSE CORTICAL INHIBITORY ...
A key feature of these interneurons is the striking structural and functional diversity, which allows them to modulate neural activity in diverse ways and ...
[6]
Anatomy, Central Nervous System - StatPearls - NCBI Bookshelf - NIH
Oct 10, 2022 · The gray commissure surrounds the central canal. The dorsal horns are made of interneurons, while the ventral horns are somatic motor neurons.
[7]
Interneurons | Neuronetwork | University of Michigan Medical School
Interneurons are specialized nerve cells in the central nervous system that act as the regulators of neural activity. They play a crucial role in processing ...
[8]
Changes in cortical interneuron migration contribute to the evolution ...
Apr 25, 2011 · These results suggest that an evolutionary change in the migratory ability of inhibitory interneurons, which originate outside the neocortex, ...<|control11|><|separator|>
[9]
GABAergic interneurons in the neocortex: From cellular properties to ...
The IN types shown in Figure 1 are still heterogeneous and include subtypes differing in morphological, electrophysiological and molecular properties (Table I).
[10]
Hippocampal Mossy Cells Provide a Fate Switch for Adult Neural ...
Aug 8, 2018 · In contrast, mossy cells (MCs), glutamatergic dentate interneurons, are very active and have been proposed as sentinels of the DG network ( ...
[11]
The Current Status of Somatostatin-Interneurons in Inhibitory Control ...
The low-threshold spiking property of Martinotti cells indicates they can be activated by a small number of excitatory neurons [63] and since they are ...
[12]
Heterogeneity and Diversity of Striatal GABAergic Interneurons - PMC
... small to medium sized neurons (less than 20 μm in diameter) of varying morphology and a small number of large neurons (Mehler, 1981). Estimates of the ratio ...
[13]
Interneuron - an overview | ScienceDirect Topics
Most of these aspinous interneurons, termed “neurons with short axons” by Ramón y Cajal, have axons that ramify locally rather than projecting away from their ...<|control11|><|separator|>
[14]
Nerve Cells - Neuroscience - NCBI Bookshelf - NIH
These short axons are a defining feature of local circuit neurons or interneurons throughout the brain. Many axons, however, extend to more distant targets ...
[15]
Morphological Characterization of the Entire Interneuron Population ...
Nov 2, 2011 · The current study has characterized the morphology of the complete population of interneurons in the late embryonic Drosophila abdominal nerve cord.
[16]
The Diversity of Cortical Inhibitory Synapses - Frontiers
The domain specific selectivity of cortical inhibition is expressed as four different innervation styles: axo-somatic, axo-dendritic, axo-spinous or axo-axonic ...
[17]
New dimensions of interneuronal specialization unmasked by ...
Interneuron cell types are specialized to deliver GABA at particular times to select spatial domains along the somato-dendritic axis of principal cells (PC).
[18]
Electrical Coupling and Neuronal Synchronization in the ...
This article reviews the many subtleties of transmission mediated by gap junctions and the mechanisms whereby these junctions contribute to synchronous firing.
[19]
Interneuron Types as Attractors and Controllers - PMC
Cortical interneurons display striking differences in shape, physiology, and other attributes, challenging us to appropriately classify them.
[20]
Spinal inhibitory interneuron diversity delineates variant motor ...
Renshaw cells and Ia inhibitory interneurons are generated at different times from p1 progenitors and differentiate shortly after exiting the cell cycle. J ...
[21]
Spinal cords: Symphonies of interneurons across species - PMC
Renshaw cells and ia inhibitory interneurons are generated at different times from p1 progenitors and differentiate shortly after exiting the cell cycle. J ...
[22]
Primary Afferent Synapses on Developing and Adult Renshaw Cells
Renshaw cells, Ia inhibitory interneurons (IaINs), and possibly other types of mammalian spinal interneurons have common embryonic origins within the V1 group.
[23]
Target Selection of Proprioceptive and Motor Axon Synapses on ...
Some Ia inhibitory interneurons (IaINs) and all Renshaw cells (RCs) derive from embryonic V1 interneurons; however, in adult they display distinct functional ...
[24]
Propriospinal Neurons: Essential Elements of Locomotor Control in ...
Propriospinal interneurons (INs) communicate information over short and long distances within the spinal cord. They act to coordinate different parts of the ...
[25]
Spinal Interneurons as Gatekeepers to Neuroplasticity after Injury or ...
Abstract. Spinal interneurons are important facilitators and modulators of motor, sensory, and autonomic functions in the intact CNS.Introduction · Spinal Interneuron Diversity... · Figure 2Missing: paper | Show results with:paper
[26]
Circuits controlling vertebrate locomotion: moving in a new direction
Central pattern generator (CPG) networks in the spinal cord control locomotion, generating repetitive motor activity. These CPGs are modular and function ...
[27]
Decoding the organization of spinal circuits that control locomotion
Spinal locomotor networks are modular, with distinct codes, and reconfigure with speed changes. They are located in the spinal cord and receive brain inputs.
[28]
Transcriptional and imaging-genetic association of cortical ... - Nature
Jun 8, 2020 · Interneurons comprise 20–30% of cortical neurons and form stereotyped connections with excitatory projection neurons. The majority of ...
[29]
https://www.nature.com/articles/s41467-020-16710-x
[30]
Shedding Light on Chandelier Cell Development, Connectivity and ...
Chandelier cells (ChCs) are a unique type of GABAergic interneuron that selectively innervate the axon initial segment (AIS) of excitatory pyramidal neurons ...
[31]
Synapses of double bouquet cells in monkey cerebral cortex ...
These results indicate that double bouquet cells can be distinguished both by their GABAergic character and by their possession of calbindin immunoreactivity.
[32]
Diverse Neuron Properties and Complex Network Dynamics in the ...
This review elaborates current knowledge on cerebellar inhibitory interneurons [Golgi cells, Lugaro cells (LCs), basket cells (BCs) and stellate cells (SCs)]
[33]
Molecular Layer Interneurons: Key Elements of Cerebellar Network ...
May 10, 2021 · Multiple local chemical (1) and electrical (2) synaptic connections between basket cells (BC) and stellate cells (SC) organize MLIs into ...
[34]
https://www.frontiersin.org/journals/molecular-neuroscience/articles/10.3389/fnmol.2019.00267/full
[35]
The dual role of striatal interneurons: circuit modulation and trophic ...
This review aims to summarize recent findings regarding the role of striatal cholinergic and GABAergic interneurons in providing circuit modulation to the basal ...
[36]
Distinct Roles of GABAergic Interneurons in the Regulation of ...
Feb 10, 2010 · We find that the two major interneuron populations, persistent low-threshold spiking (PLTS) and fast spiking (FS) interneurons, differ substantially in their ...
[37]
https://pmc.ncbi.nlm.nih.gov/articles/PMC11467944/
[38]
Coincidence detection of convergent perforant path and mossy fibre ...
The selective enhancement of summation for near synchronous EPSPs suggests that one main dendritic operation in R and L-M interneurons is coincidence detection ...<|control11|><|separator|>
[39]
Dynamic Influences on Coincidence Detection in Neocortical ...
Coincidence detection (CD) is the operation performed by a neuron when it responds maximally to synchronized inputs. Various neuronal processes may be modulated ...
[40]
Parvalbumin-Expressing Basket Cells & Working Memory
Sep 21, 2016 · ... (action potential width <0.3 ms, firing rate >10 Hz) and 102 putative ... Functional fission of parvalbumin interneuron classes during fast network ...
[41]
The Roles of Somatostatin-Expressing (GIN) and Fast-Spiking ...
Their firing rate during suprathreshold current injection can be high, and they do not typically display spike rate adaptation. In contrast, GIN interneurons ...
[42]
Short-Term Plasticity of Unitary Inhibitory-to-Inhibitory Synapses ...
Specifically, STP was strongly depressing in synapses made by FS interneurons, and weakly depressing to weakly facilitating in output synapses of SOM ...
[43]
GABA-mediated tonic inhibition differentially modulates gain in ...
Jan 23, 2020 · Instead of providing a simple “blanket” of inhibition, the nonspecific diffusion of GABA may selectively tune interneuron excitability.
[44]
On the Initiation and Propagation of Dendritic Spikes in CA1 ... - NIH
We found that dendritic spike initiation requires highly coincident and loosely clustered synaptic input and that their generation often leads to short-latency ...Missing: IPSPs | Show results with:IPSPs
[45]
Mechanisms underlying gain modulation in the cortex - PMC
Jan 7, 2020 · In the auditory cortex, optogenetically activating PV+ interneurons or SST+ interneurons evokes a mixture of divisive and subtractive modulation ...
[46]
Surround suppression and sparse coding in visual and barrel cortices
For intracortical inhibition to be effective in generating surround suppression, inhibition must be temporarily uncoupled from excitation to cause a withdrawal ...
[47]
Inhibition of inhibition in visual cortex: the logic of connections between molecularly distinct interneurons - Nature Neuroscience
### Summary of VIP-SST Interactions and Disinhibition in Visual Cortex Interneurons
[48]
PV Interneurons: Critical Regulators of E/I Balance for Prefrontal ...
Diagram shows how parvalbumin (PV) interneurons help maintain the excitation and inhibition (E/I) balance within prefrontal local circuits for optimal ...
[49]
Hippocampal theta rhythm and its coupling with gamma oscillations ...
Mar 3, 2009 · Hippocampal theta (5–10 Hz) and gamma (35–85 Hz) oscillations depend on an inhibitory network of GABAergic interneurons.
[50]
Striatal cholinergic interneurons generate beta and gamma ... - PNAS
May 16, 2016 · In this study, we demonstrate that a single cell type, the striatal cholinergic interneuron, mediates the emergence of exaggerated beta oscillations within CBT ...Striatal Cholinergic... · Results · Striatal Muscarinic...
[51]
https://www.pnas.org/doi/10.1073/pnas.0813176106
[52]
https://www.pnas.org/doi/10.1073/pnas.1605658113
[53]
https://www.cell.com/neuron/fulltext/S0896-6273(05)00934-7
[54]
https://www.cell.com/neuron/fulltext/S0896-6273(01)00212-4
[55]
Cortical interneurons in the developing human neocortex - PMC - NIH
Here we demonstrate that at the beginning of corticogenesis, at embryonic 5 gestation weeks (gw, Carnegie stage 16) in human, early neurons could be labeled ...Missing: timeline | Show results with:timeline
[56]
Extended Production of Cortical Interneurons into the Third ... - NIH
Apr 16, 2015 · In humans, the developmental origins of interneurons in the third trimester of pregnancy and the timing of completion of interneuron ...Missing: timeline | Show results with:timeline
[57]
An Extracellular Perspective on CNS Maturation: Perineuronal Nets ...
During restricted time windows of postnatal life, called critical periods, neural circuits are highly plastic and are shaped by environmental stimuli.2. Pnns And Brain Maturation · 2.3. Pnns And The Regulation... · 3. Pnns And The Mature Brain
[58]
(PDF) Long-term synaptic plasticity in hippocampal interneurons
Aug 6, 2025 · Here we review these contrasting forms of LTP and describe how they are mirrored by two forms of long-term depression. We further discuss how ...<|separator|>
[59]
https://pmc.ncbi.nlm.nih.gov/articles/PMC7957817/
[60]
Enriched and Deprived Sensory Experience Induces Structural ...
Probably the best-known method to compensate sensorial deprivation is by environmental enrichment, also used to compensate the effects of many brain diseases.
[61]
Parvalbumin-Positive Interneurons Regulate Cortical Sensory ...
First, cPVins regulate developmental critical periods and adult plasticity through molecular and structural interactions with the extracellular matrix. Second, ...
[62]
Interneuron Simplification and Loss of Structural Plasticity As ...
Sep 26, 2018 · Here we show that brain aging goes hand in hand with progressive structural simplification and reduced plasticity of inhibitory neurons.
[63]
Age-dependent and region-specific alteration of parvalbumin ...
Nov 7, 2017 · We propose that PNNs surround more neurons as age increases. This aging-related increase in PNNs decreases plasticity in the cerebral cortex and reduces ...
[64]
Parvalbumin Interneuron Dysfunction in Neurological Disorders
May 19, 2024 · This review focuses on the role of dysfunctional PV+ inhibitory interneurons in the generation of epileptic seizures and cognitive impairment
[65]
Proportional loss of parvalbumin-immunoreactive synaptic boutons ...
Reduced inhibition of granule cells might be attributable to fewer synapses from parvalbumin-positive interneurons. In human patients with temporal lobe ...
[66]
Selective Silencing of Hippocampal Parvalbumin Interneurons ...
Temporal lobe epilepsy (TLE) is the most frequent form of focal epilepsies and is generally associated with malfunctioning of the hippocampal formation.
[67]
A Role for Somatostatin-Positive Interneurons in Neuro-Oscillatory ...
Dec 28, 2020 · Alterations in neocortical GABAergic interneurons (INs) have been affiliated with neuropsychiatric diseases, including schizophrenia (SZ).Fig. 3 · Table 1 · Brain Oscillations And The...
[68]
Review Alterations in cortical interneurons and cognitive function in ...
Therefore, GABA neuron dysfunction in the PFC of individuals with schizophrenia could underlie reduced gamma oscillatory power and working memory deficits.Review · Introduction · Interneuron Disturbances In...
[69]
NMDAR hypofunction and somatostatin-expressing GABAergic ...
3.1. Somatostatin changes in schizophrenia models · 3.2. Somatostatin receptors changes in relation to NMDAR activity · 3.3. Cortical oscillation changes and ...
[70]
Interneuron deficits in neurodevelopmental disorders
Jan 1, 2021 · In the last decade, GABA-expressing interneurons (INs), a primary player in maintaining E/I balance, have been the focus of intense research.
[71]
Cortical interneurons in autism - PMC - PubMed Central - NIH
The hypothesized E/I imbalance in favor of excitation was appealing because it could explain the co-occurrence of seizures in autism, even though epilepsy is ...
[72]
Interneuron odyssey: molecular mechanisms of tangential migration
... imbalance and autism-like behaviors through regulation of interneuron migration. ... Molecular control of two novel migratory paths for CGE-derived interneurons ...
[73]
Early synaptic dysfunction of striatal parvalbumin interneurons in a ...
Oct 24, 2024 · In Parkinson's disease (PD), the loss of dopaminergic signaling remodels striatal circuits, causing abnormal network activity.
[74]
Synchronized firing of fast-spiking interneurons is critical to maintain ...
The inhibitory circuits of the striatum are known to be critical for motor function, yet their contributions to Parkinsonian motor deficits are not clear.
[75]
Optogenetic approaches to evaluate striatal function in animal ... - NIH
Here, we focus on how optogenetics has been used over the last decade to probe striatal circuits that are involved in Parkinson disease.
[76]
A historical reflection of the contributions of Cajal and Golgi to the ...
In the present article we shall review some of the main contributions of Cajal and Golgi that can be considered as the foundations of modern neuroscience.
[77]
Golgi Stain - an overview | ScienceDirect Topics
The Spanish neuroanatomist Santiago Ramón y Cajal took quick advantage of the Golgi method to systematically describe the different types of neurons ...The Chromatic Epiphany: New... · Correlative Microscopy: A... · 2 Classical Approaches To...
[78]
John Eccles' pioneering role in understanding central synaptic ...
His team worked out the mechanisms and spinal circuits underlying disynaptic and recurrent inhibition, as well as those of presynaptic inhibition. Not content ...Missing: electrophysiology | Show results with:electrophysiology
[79]
John Eccles' studies of spinal cord presynaptic inhibition
Eccles' studies emphasized presynaptic inhibition of the group Ia monosynaptic reflex pathway but also included group Ib, II and cutaneous afferent pathways.
[80]
In vivo optogenetic identification and manipulation of GABAergic ...
Jan 14, 2014 · The combination of optogenetics and large-scale neuronal recordings allows specific interneuron populations to be identified and perturbed for ...
[81]
Assembloid CRISPR screens reveal impact of disease genes in ...
Sep 27, 2023 · Here we integrate assembloids with CRISPR screening to investigate the involvement of 425 NDD genes in human interneuron development.
[82]
An unsupervised map of excitatory neuron dendritic morphology in ...
Excitatory neurons in the neocortex exhibit considerable morphological diversity, yet their organizational principles remain a subject of ongoing research. Here ...
[83]
First-in-Human Trial of NRTX-1001 GABAergic Interneuron Cell ...
Apr 7, 2025 · NRTX-1001 administration has been well-tolerated in ten patients with drug-resistant TLE, with preliminary data suggesting significant reductions in seizure ...
[84]
First-of-its-kind stem-cell transplant treatment targets drug-resistant ...
Apr 22, 2025 · The experimental treatment is part of the first in-human clinical trial investigating the safety and efficacy of lab-grown interneuron cells to treat seizures.