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Neuraxis
Neuraxis
Neuraxis
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Neuraxis
The mammalian nervous system is arranged with the neural tube running along an anterior to posterior axis, from nose to tail for a four-legged animal like a dog. Humans, as two-legged animals, have a bend in the neuraxis between the brain stem and the diencephalon, along with a bend in the neck, so that the eyes and the face are oriented forward.
The embryonic brain develops complexity through enlargements of the neural tube called vesicles; (a) The primary vesicle stage has three regions, and (b) the secondary vesicle stage has five regions.
Anatomical terminology

The neuraxis, also known as the neuroaxis[1] is the axis of the central nervous system. It extends from the brain to the spinal cord and denotes the direction in which the central nervous system lies in both development and in mature organisms. Early on in embryological development, the neuraxis begins as a distinctly straight axis, but quickly develops bends by various flexures, most notably the cephalic flexure, which contributes most to the complex mature structure of the spinal cord and brain.

Embryonic development can help in understanding how complex structures form around the neuraxis The embryonic nervous system in vertebrates is highly conserved, meaning its structure and function have stayed the same across species, and generally appear the same.[2] During development, the formation of the neural tube-and later the brain and spinal cord- define the layout of the neuraxis. This establishes the anterior-posterior dimension of the nervous system. The anterior-posterior dimension of the neuraxis overlays the superior-inferior dimension of the body. Depending on the formation of more differentiated structures, this axis may lose its rigid nature, adopting the curvature introduced by encephalic structures.[3] For example, there is a major curve between the brain stem and forebrain, which is called the cephalic flexure. Because of this, the neuraxis starts in an inferior position—the end of the spinal cord—and ends in an anterior position, the front of the cerebrum. This can be illustrated when looking at a four-legged animal standing up on two legs. Without this flexure in the brain stem and at the top of the neck, a bipedal animal would be unable to look directly in front of them.[4]

Anatomical and clinical significance

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The neuraxis holds a highly relevant role in anatomical and clinical settings. As a key feature of anatomical orientation, it provides a strong framework for identifying other structures, determining directionality, and applying these aspects towards clinical practice. In humans, neuraxis formation is marked by the emergence of a curved axis, increasing the complexity of neurological features. This added axis defies typical anatomical terminology, necessitating adapted terms to accurately describe new features. Once accurately established, the neuraxis provides a reference point to allow clinicians and researchers to accurately make diagnoses, conceptualize brain structures, and enables educators to explain spatial relationships between other parts of the body.[5]

Anatomical orientation and origin of the neuraxis

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The skull uses different anatomical terminology due to its embryonic origin of the neuraxis.

The neuraxis holds great importance anatomically, establishing the localization of the central nervous system. Through development, it establishes the anterior-posterior axis through which other anatomical terms can be applied in different CNS regions. Early on in embryogenesis, during gastrulation, the beginnings of the neuraxis become defined. Here the primitive streak is formed, a precursor the neural tube. The primitive streak marks the beginning of gastrulation and is a transient feature that exists primarily in vertebrates.Following the neural tube formation, a defined axis can be established and an initial neuraxis is formed. The originally straight axis adopts a curve as the brain enlarges, allowing for the formation and distinction of complex structures such as the brain stem and cerebral cortex.[6] The terminology of these structures remains the same after development is complete. Dorsal refers to the back of the body as well as the top of the head, while ventral denotes the front of the body and the region under the neuraxis, the bottom of the head.

Clinical applications of the neuraxis

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The neuraxis provides an importance reference for clinicians, particularly in the fields of neurology, neurosurgery, and radiology. Due to the curved nature of the human neuraxis, common anatomical terms such as rostral, caudal, dorsal, and ventral hold different meanings at the head, underscoring the importance of the neuraxis as a reference point. In radiology, interpretations of the neuraxis allows for accurate image interpretations for cross-sectional imaging and MRIs. Neurosurgery also heavily relies on a strong understanding of the neuraxis, particularly for entry-point localization and risk assessments. Atypical alignment of the neuraxis has been documented as a sign of underlying disease. Insufficient mechanical support and altered vasculature due to misaligned neuraxes causes extreme pathology in several conditions such as scoliosis, Arnold-Chiari malformation, and even some cases of Ehlers-Danlos Syndromes (EDS). This pathology is often marked by a disproportionate degree of neurological dysfunction.[7][8] Extreme conditions of androgen insensitivity syndrome (AIS) can also lead to neuraxis deviation, increasing the chance of further pathogenesis.[9] The neuraxis also plays a relevant role in rehabilitation and treatment, underscoring the importance of its anatomical role.[10]

See also

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References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Neuraxis

View on Grokipedia
from Grokipedia
The neuraxis is the central axis of the (CNS), comprising the and , and serving as the primary longitudinal pathway for sensory, motor, and integrative functions along which neurons, axons, and supporting structures are organized. It originates from the embryonic , which forms the foundational structure of the CNS through a process involving the neural plate's and closure, establishing the anterior-posterior dimension from the rostral to the caudal . In vertebrates, including humans, the neuraxis undergoes developmental flexures—such as the cervical, mesencephalic, and pontine bends—that reorient its trajectory, resulting in a vertical and a more horizontal orientation relative to the body's superior-inferior axis. These flexures, influenced by genetic patterning from genes like otx and hox, divide the neuraxis into key regions: the prosencephalon (), mesencephalon (), and rhombencephalon (), which further subdivide into structures like the telencephalon, , , and . Functionally, the neuraxis integrates somatic (external sensory-motor) and visceral (internal regulatory) components, with dorsal regions primarily processing afferent (incoming) signals and ventral areas handling efferent (outgoing) responses for motion, sensation, association, and . Its neuroepithelium acts as a proliferative zone generating neurons, , ependymal cells, and , with ongoing in select areas like the hippocampus and persisting into adulthood in some species. Species-specific variations exist, such as greater structural segregation in compared to , and a 90-degree pontine flexure in humans that alters the fourth ventricle's shape and influences . Clinically, the neuraxis is vulnerable to neurotoxicants causing neuronopathies (e.g., hippocampal damage from trimethyltin), axonopathies (e.g., axonal degeneration from ), and myelinopathies (e.g., from triethyltin), while diagnostic imaging like MRI reveals abnormalities such as melanin-related signal changes in conditions like congenital melanocytic nevi. Overall, the neuraxis provides the scaffold for understanding CNS development, phylogeny across chordates, and neurological disorders, underscoring its role as the structural and functional backbone of neural communication.

Definition and Overview

Definition

The neuraxis, also known as the neuroaxis, is the central axis of the , consisting of the and , which together form the core of the (CNS). This longitudinal structure integrates sensory input, processes information, and coordinates motor outputs throughout the body. In anatomical terms, it serves as an imaginary line delineating the primary orientation of the CNS from the rostral (head) end to the caudal (tail) end. The neuraxis is distinctly separate from the peripheral nervous system (PNS), which encompasses all neural elements outside the CNS, including cranial and spinal nerves, ganglia, and sensory receptors that transmit signals between the CNS and peripheral tissues. While the PNS is adapted for signal conduction over distances without the protection of bone, the neuraxis is encased in the skull and vertebral column to safeguard its delicate neural tissue. This division ensures the CNS's role in higher-order processing remains insulated from external perturbations. Evolutionarily, the neuraxis is a hallmark of bilaterian animals, arising from the centralization of a diffuse into a cord-like structure in their common ancestor. In vertebrates, this manifests as a , likely resulting from a dorsoventral inversion relative to the ventral cords typical in most other bilaterians, enabling efficient and body axis coordination. This configuration underscores the neuraxis's conserved role in bilateral symmetry and neural integration across diverse taxa.

Etymology

The term "neuraxis" derives from the Greek "," meaning or sinew, combined with "axis," referring to an or central line, to denote the longitudinal axis of the . American comparative anatomist Burt Green Wilder used the related term "" in his 1884 Cartwright Lectures to refer to the entire central nervous axis (neuraxis) from to . The English adoption of "neuraxis" is attributed to surgeon Albert H. Buck in 1889, marking its earliest recorded use in English medical literature as a compound term for the brain-spinal cord continuum. Prior to widespread use of "neuraxis," 19th-century anatomists referred to the same structure as the "central nervous axis" in texts such as Jones Quain's Elements of Anatomy (1896 edition, based on earlier volumes), highlighting its role as the core pathway enveloped by peripheral nerves. This terminological shift from descriptive phrases like "central nervous axis" or "medullary axis" (used for the spinal component) to "neuraxis" reflected growing precision in neuroanatomy, aligning with advancements in microscopy and comparative studies during the late 1800s.

Anatomy

Structure

The neuraxis comprises the (CNS), specifically the and the , which together form a continuous axis extending from the to the vertebral . This structure serves as the primary conduit for neural processing and transmission within the body. The , located superiorly, is divided into three main divisions: the (prosencephalon), which includes the and ; the (mesencephalon), a small region connecting the forebrain and ; and the (rhombencephalon), encompassing the , , and . These divisions arise from embryonic vesicles and constitute the expanded cephalic end of the neuraxis. The spinal cord forms the inferior continuation of the neuraxis, extending from the foramen magnum to approximately the level of the second lumbar vertebra in adults. In adult males, it measures about 45 cm in length, while in females it is slightly shorter at around 43 cm. The spinal cord is segmented into 31 pairs of spinal nerves, organized as follows: 8 cervical, 12 thoracic, 5 lumbar, 5 sacral, and 1 coccygeal segment. Each segment corresponds to specific vertebral levels and contributes to the overall longitudinal organization of the neuraxis. Histologically, the neuraxis is characterized by an internal organization of gray matter and surrounding , a pattern consistent across both the and . Gray matter primarily consists of neuronal cell bodies, dendrites, unmyelinated axons, glial cells, and synapses, forming regions such as the cortical layers of the and the H-shaped core of the in cross-section. , in contrast, is composed of bundles of myelinated axons that facilitate rapid signal conduction between gray matter regions, appearing lighter due to the lipid-rich myelin sheaths produced by . This dichotomous arrangement supports the structural integrity and efficient information relay along the neuraxis. In the , the gray matter occupies the central butterfly-shaped region, while white matter tracts occupy the peripheral columns (dorsal, lateral, and ventral funiculi).

Orientation

In neuroanatomy, the neuraxis serves as the primary longitudinal axis of the , extending from the to the , and defines key directional conventions for describing the relative positions of neural structures. These terms differ from general anatomical planes used in , where anterior-posterior and superior-inferior orientations predominate, by emphasizing the evolutionary and developmental layout of the along its bent axis. Specifically, rostral refers to a direction toward the or , while caudal indicates toward the tail or posterior end; dorsal denotes toward the back or top, and ventral toward the belly or bottom. Additionally, ipsilateral describes structures on the same side of the body relative to a reference point, whereas contralateral refers to the opposite side. These conventions vary between the and : in the , rostral points anteriorly and dorsal superiorly, but in the , rostral aligns upward along the axis and dorsal posteriorly. The neuraxis exhibits significant bending due to , the evolutionary concentration of in the anterior region, which curves the rostral end of the during development. This results in the cephalic flexure, a ventral bend at the mesencephalon level that persists into adulthood as an approximately 180-degree curvature in the neural axis at the brainstem-forebrain junction. Caused by differential cellular proliferation during weeks 4 to 8 of embryogenesis, this flexure alters directional interpretations, particularly in the brainstem, where rostral-caudal orientations shift relative to the spinal cord's straighter alignment, leading to a heart-shaped with dorsal colliculi and ventral oculomotor structures. In humans, this bending creates a roughly 120-degree angle between the brainstem and axes, compensating for upright posture and complicating direct application of standard body planes. In three-dimensional neuroanatomical modeling, the neuraxis is often aligned with the z-axis in Cartesian coordinate systems to standardize spatial navigation across the bent . This representation facilitates integration of brain regions into orthogonal frameworks, such as the RAS (right-anterior-superior) system, where the z-axis corresponds to inferior-superior directions approximating the neuraxis's primary orientation in standardized atlases like MNI space. By mapping the neuraxis to the z-axis, models account for its while enabling precise volumetric and comparisons between subjects.

Embryological Development

Origin

The neuraxis, comprising the central nervous system axis from the to the , originates from the , a derivative of the germ layer that differentiates early in embryonic development and remains distinct from the (which forms structures like the and somites) and (which gives rise to the gut lining). This neuroectodermal tissue forms the foundational structure of the neuraxis during primary neurulation. Neural induction, the initial step in neuraxis formation, occurs during around the third week of human gestation, when the —arising from midline mesodermal cells—secretes signaling molecules such as Sonic hedgehog (Shh) to instruct the overlying ectodermal cells to adopt a neural fate and thicken into the . This inductive interaction establishes the dorsal midline of the embryo as the site of specification, preventing those ectodermal cells from forming instead. Following induction, the bends along its midline to form paired neural folds by the end of the third week, which then elevate, approximate, and fuse dorsally to enclose the —the direct precursor to the neuraxis—by the fourth week. Closure proceeds in a zipper-like manner from the cervical region bidirectionally: the anterior neuropore, at the rostral end, closes on embryonic day 25 (corresponding to the 18-20 stage), while the posterior neuropore, at the caudal end, closes around day 27 (25 stage), completing primary neurulation and isolating the from the surface .

Stages

The development of the neuraxis progresses through distinct stages following the initial induction of the neural plate, with neurulation representing the primary mechanism for neural tube formation. Primary neurulation, which occurs during weeks 3 to 4 of human gestation, establishes the anterior-posterior axis of the central nervous system by transforming the flat neural plate into a hollow tube through a series of cellular deformations. This process begins with the induction of the neural plate by the underlying notochord, followed by the elevation and convergence of neural folds along the midline, forming the neural groove. The folds then fuse in a zipper-like manner, starting cranially and progressing caudally, with the rostral neuropore closing around day 25 and the caudal neuropore around day 27, thereby enclosing the neural tube that will give rise to the brain and most of the spinal cord. During this phase, neural crest cells delaminate from the dorsal aspect of the neural folds at the border with the surface ectoderm, migrating extensively to contribute to the peripheral nervous system (PNS), including sensory ganglia, autonomic neurons, and Schwann cells. Secondary neurulation follows the completion of primary neurulation and accounts for the formation of the caudal portion of the , particularly at , sacral, and coccygeal levels, typically during weeks 5 to 6. In this phase, mesenchymal cells in the tail bud aggregate to form a solid medullary cord, which subsequently undergoes to create a lumen that connects to the of the primary . This process ensures continuity of the neuraxis in the posterior region and involves limited neural crest cell production from the caudal , supporting PNS elements in the sacral region. Unlike primary neurulation, secondary neurulation lacks the overt folding of epithelial sheets and relies more on mesenchymal-to-epithelial transitions, culminating in retrogressive differentiation where excess caudal structures regress to form the . The distinction between these phases highlights the adaptive mechanisms for extending the neuraxis along the full anterior-posterior body axis. By the end of week 5, the rostral undergoes further segmentation into transverse units known as neuromeres, which delineate the foundational domains of the . The (prosencephalon) divides into five prosomeres (P1 through P5), representing transverse segments that correspond to thalamic, prethalamic, hypothalamic, and adjacent telencephalic regions, as described in the prosomeric model of development. This model posits that these prosomeres arise from differential patterns along the anterior-posterior axis, establishing boundaries through signaling centers like the zona limitans intrathalamica between P2 and P3. Concurrently, the (rhombencephalon) segments into twelve rhombomeres (r0 through r11), which serve as transient compartments guiding the migration and differentiation of cranial nerve nuclei and pontine neurons. Rhombomere boundaries are marked by expression of and other transcription factors, with r4 acting as an organizer for adjacent segments via isthmic signaling. These divisions by week 5 provide a blueprint for regional specification, integrating anterior-posterior and dorsal-ventral patterning cues. Spinal cord development, occurring parallel to brain segmentation from weeks 4 onward, involves dorsal-ventral patterning driven by opposing morphogen gradients that specify distinct progenitor domains. Ventral patterning is primarily orchestrated by Sonic hedgehog (Shh), secreted from the and induced floor plate, forming a concentration gradient that decreases dorsally and promotes ventral cell fates such as motor neurons in the ventral horn (pMN domain) and (p3, p2, p1 domains). High Shh levels (above ~25 nM) induce floor plate, while lower levels (~5 nM) specify motor neurons, with the gradient interpreted via Gli transcription factors that act as activators or repressors based on Shh duration and intensity. Dorsally, bone morphogenetic proteins (BMPs), including BMP4, BMP6, and BMP7 from the roof plate and overlying , establish a counter-gradient that specifies sensory populations (dI1 through dI6 domains) and dorsal horn structures. The interplay of Shh and BMP gradients, refined by additional signals like , ensures precise laminar organization, with the ventral-to-dorsal transition occurring over the first 4-5 days of closure in the cervical .

Functions

Signaling

Neural signaling along the neuraxis primarily occurs through the propagation of action potentials, which are rapid changes in driven by the sequential opening of voltage-gated ion channels. In neurons of the (CNS), is initiated by the influx of sodium ions (Na⁺) through voltage-gated sodium channels, reaching a peak near +40 mV, followed by via efflux of ions (K⁺) through voltage-gated potassium channels. This electrochemical process allows signals to travel longitudinally along axons within the and , forming the core mechanism for information relay in the neuraxis. In myelinated fibers, which predominate in the CNS tracts of the neuraxis, propagation occurs via , where the impulse "jumps" between nodes of Ranvier—gaps in the sheath enriched with channels. This insulation by sheaths, produced by in the CNS, confines flow to these nodes, dramatically increasing conduction efficiency and speed compared to continuous conduction in unmyelinated axons. Conduction velocities in such myelinated fibers can reach up to 120 m/s, enabling rapid transmission essential for coordinated neural activity along the axis. Chemical signaling complements electrical propagation at synapses throughout the neuraxis, where are released from presynaptic terminals to modulate postsynaptic neurons. Upon arrival of an , calcium influx triggers vesicular , releasing neurotransmitters such as glutamate—the principal excitatory transmitter in the CNS—or gamma-aminobutyric acid (GABA), the main inhibitory . Glutamate binds to ionotropic receptors like and NMDA, facilitating excitatory postsynaptic potentials, while GABA activates GABA_A receptors to induce influx and hyperpolarization, thus inhibiting signal transmission. These processes occur at junctions within CNS structures, ensuring precise communication between neurons aligned along the neuraxis. Specific neural tracts parallel the neuraxis to channel signals in ascending and descending directions. The , an ascending pathway, conveys pain and temperature sensations from the to the , with fibers decussating shortly after entering the cord and traveling contralaterally in the anterolateral funiculus. In contrast, the represents a major descending motor pathway, originating in the and descending through the and lateral spinal funiculus to with lower motor neurons, with most fibers crossing at the medullary pyramids to control contralateral voluntary movements. These tracts exemplify how signaling is organized longitudinally along the neuraxis to integrate sensory input and motor output.

Integration

The neuraxis exhibits a that enables progressive levels of information processing and coordination, with the handling basic reflex arcs and the serving as a higher for complex sensory-motor loops. At the lowest level, the processes sensory inputs through local and motor neurons to generate rapid, automatic responses, such as the , which protects the body from harm without requiring supraspinal input. This segmental integration allows for efficient, decentralized control of locomotion and posture. Higher up the neuraxis, the and refine these signals, while the telencephalon, particularly the , synthesizes multisensory data to orchestrate voluntary movements and adaptive behaviors, forming closed-loop systems that modulate spinal outputs based on contextual demands. This layered architecture ensures that simple reflexes can be overridden or enhanced by descending pathways from the , facilitating coordinated organismal function. Feedback loops within the neuraxis play a crucial role in maintaining by integrating sensory feedback with efferent commands across its rostrocaudal extent. For instance, the hypothalamic-pituitary axis exemplifies a core mechanism where hypothalamic neurons detect physiological perturbations, such as stress or hormonal imbalances, and coordinate pituitary hormone release to restore equilibrium, with circulating factors providing inhibitory signals back to the . This loop, centered in the and extending to spinal autonomic outputs, regulates vital processes like cardiovascular tone and through bidirectional signaling along the neuraxis. Such mechanisms prevent overexcitation and promote stability, with spinal contributing to local reflex adjustments that feed into supraspinal circuits for global . Neural plasticity along the neuraxis, particularly through mechanisms like (LTP), underpins learning and adaptive integration by strengthening synaptic connections in response to patterned activity. LTP, first demonstrated in hippocampal pathways, involves persistent enhancement of synaptic efficacy following high-frequency stimulation, enabling the encoding of experiences into lasting neural modifications. This phenomenon extends to spinal circuits, where LTP in dorsal horn synapses refines and , such as in skill acquisition during locomotion. Across the neuraxis, these plastic changes allow for hierarchical refinement, with cortical LTP integrating spinal feedback to support higher-order functions like and behavioral flexibility.

Clinical Significance

Pathologies

Traumatic injuries to the neuraxis, particularly the , represent a major category of acute pathologies that disrupt neural transmission and lead to profound motor and sensory deficits. (SCI) often results from high-impact trauma such as motor vehicle accidents or falls, causing compression, contusion, or transection of the cord. Depending on the level of injury, cervical SCI can produce quadriplegia, characterized by and loss of sensation in all four limbs due to disruption of descending motor pathways from the to the , while thoracic or injuries typically cause , affecting the lower limbs only. The severity of these impairments is classified using the American Spinal Injury Association () Impairment Scale, which grades injuries from A (complete: no sensory or motor function preserved in sacral segments S4-S5) to E (normal: motor and sensory function intact), guiding prognosis and rehabilitation planning. Neurodegenerative disorders targeting the neuraxis involve progressive loss of neuronal integrity, leading to demyelination or direct neuronal death along the central axis. (MS), an autoimmune condition, causes focal demyelination in the brain and , forming plaques that interrupt axonal conduction and result in symptoms such as , , and sensory disturbances; these lesions preferentially affect the tracts of the neuraxis, contributing to relapsing-remitting or progressive disability. (ALS), in contrast, features selective degeneration of upper motor neurons in the and lower motor neurons in the and , leading to , , and eventual ; this motor neuron loss occurs throughout the neuraxis, with an average overall reduction of 55% in affected individuals. Congenital malformations of the neuraxis arise primarily from neural tube defects (NTDs), failures in the embryonic closure of the that forms the and . Anencephaly, a lethal NTD, results from incomplete closure of the anterior , leading to absence of the cerebral hemispheres and vault of the , with affected pregnancies occurring in approximately 1 in 1,000 worldwide, though most end in or . Spina bifida, stemming from posterior neural tube defects, manifests as incomplete vertebral arch fusion, often exposing the and causing lower limb paralysis, bladder dysfunction, and in severe cases (myelomeningocele); its incidence is about 1 in 2,875 live births , with global rates for NTDs averaging 2 per 1,000 births. These defects trace back to disruptions in early embryological stages but present as structural anomalies at birth. Prevention through periconceptional folic acid supplementation (400-800 mcg daily) can reduce NTD risk by 50-70%, and mandatory in many countries has significantly lowered incidence rates.

Applications

Magnetic resonance imaging (MRI) serves as a primary diagnostic tool for assessing the integrity of the neuraxis, enabling detailed visualization of the and structures. Conventional MRI sequences, such as T1-weighted imaging, provide excellent anatomical contrast for delineating gray and boundaries, while T2-weighted sequences highlight and detect or lesions along the axis. These modalities are particularly useful in evaluating traumatic injuries, degenerative conditions, and inflammatory processes affecting neuraxial continuity. Functional MRI (fMRI) extends these capabilities by mapping neural activity within the neuraxis, offering insights into dynamic processes like motor and sensory integration. By measuring blood-oxygen-level-dependent (BOLD) signals, fMRI identifies active regions during tasks, aiding in preoperative planning for surgeries involving the or . For instance, it has been applied to characterize hand motor function by simultaneously imaging and responses. Therapeutic interventions targeting the neuraxis include neuromodulation techniques such as (DBS) and spinal cord stimulation (SCS). DBS involves implanting electrodes in the subthalamic nucleus to deliver electrical pulses, significantly alleviating motor symptoms in , including bradykinesia, rigidity, and , with improvements observed in up to 70% of patients over long-term follow-up. This approach modulates circuits within the neuraxis, enhancing function without ablative risks. Similarly, SCS uses epidural electrodes to stimulate the dorsal columns of the , interrupting pain signals via the and providing relief for chronic refractory to conventional therapies, with success rates of 50-70% pain reduction in responsive patients. As of 2025, emerging therapies show promise for neuraxis disorders. For , the FDA-approved antisense oligonucleotide targets mutations, slowing progression in eligible patients, while accelerated approval of the Sodesta addresses broader genetic forms. In MS, tyrosine kinase inhibitors (BTKis) like tolebrutinib reduce and progression, and CAR-T has been administered to the first patients, targeting B cells for potential remission. For SCI, non-invasive spinal cord stimulation devices and therapies, such as Neuro-Cells from autologous , are advancing in clinical trials to promote recovery. Pharmacological approaches focus on agents that penetrate the blood-brain barrier to influence neuraxial signaling pathways. , a gamma-aminobutyric acid-B (GABA-B) receptor agonist, is administered intrathecally to bypass limited and directly target receptors, effectively reducing in conditions like or by inhibiting monosynaptic and polysynaptic reflexes. This method achieves higher concentrations with fewer systemic side effects compared to oral dosing, improving and mobility in severe cases.

History

Early Concepts

The earliest conceptualizations of the neuraxis emerged in , where the was understood as a vital extension of the , often referred to as "marrow" or "spinal marrow" (notiaios myelos). In the , dating to the 5th and 4th centuries BCE, the was described as a continuous, warm structure originating from the and extending downward through the vertebral column, serving as a conduit for sensations and movements. Hippocratic texts emphasized its role in transmitting neural impulses, with injuries to this "marrow" causing or loss of sensation below the site of damage, reflecting an early recognition of its axial continuity and functional importance. Building on these ideas, the Roman physician (129–c. 216 CE) advanced the understanding of the neuraxis through his ventricular theory of brain function, positing that the brain's ventricles—connected to the —housed distinct mental faculties. , drawing from dissections primarily of animal s, described the neuraxis as comprising the and its extending to the spinal marrow, with the anterior ventricle associated with imagination, the middle with cognition, and the posterior with memory. This model portrayed the neuraxis as the central pathway for "animal spirits" that mediated sensory perception and , influencing medical thought for over a millennium. During the Renaissance, anatomical illustrations provided more precise visualizations of the neuraxis as a unified structure. In his seminal 1543 work De humani corporis fabrica, depicted the as a continuous, cord-like extension from the through the vertebral canal, challenging prior Galenic inaccuracies with detailed woodcuts based on human dissections. These illustrations highlighted the 's segmentation and enclosure within the , marking a shift toward empirical observation of its . By the , experimental refined these anatomical insights into functional principles. The Bell-Magendie law, established in the 1820s, demonstrated that the anterior (ventral) roots of spinal nerves convey motor impulses, while the posterior (dorsal) roots transmit sensory information, thus clarifying the neuraxis's role in bidirectional neural signaling. first proposed the motor function of anterior roots in 1821 based on lesion studies in animals, and François Magendie confirmed the sensory role of posterior roots in 1822 through vivisections that preserved or severed specific roots. This law provided foundational evidence for the neuraxis as a segregated pathway for efferent and afferent signals, bridging and .

Modern Understanding

In the mid-20th century, advancements in revolutionized the understanding of signal propagation along the neuraxis, with the Hodgkin-Huxley model providing a foundational mathematical description of action potentials in neuronal membranes. Developed by and through experiments on the , this model demonstrated how voltage-gated sodium and channels enable the rapid and that underpin nerve impulse conduction throughout the central and peripheral nervous systems. Their work, which earned the 1963 Nobel Prize in Physiology or Medicine, established that action potentials travel as self-regenerating waves along axons, a mechanism essential to neuraxial communication. The late 20th century saw a neuroimaging revolution that enabled non-invasive visualization of the neuraxis, beginning with the introduction of computed tomography (CT) in the 1970s. Invented by , the first CT scanner produced cross-sectional images of the and , allowing clinicians and researchers to detect structural abnormalities without ; the inaugural clinical scan occurred in 1971 at Atkinson Morley Hospital in . Building on this, magnetic resonance imaging () emerged in the 1980s, pioneered by and , who developed techniques to generate detailed images based on signals from hydrogen atoms in tissues. MRI's superior soft-tissue contrast facilitated high-resolution mapping of neuraxial anatomy, including tracts, and its non-ionizing nature made it ideal for repeated studies of neural structures. These technologies shifted research from invasive methods to precise, assessments of the neuraxis. Entering the 21st century, has advanced the study of neuraxial pathways through large-scale mapping initiatives, exemplified by the (HCP) launched in 2010. Funded by the , the HCP employs advanced diffusion MRI, resting-state functional MRI, and to chart structural and functional connections across the and in healthy adults, creating a publicly accessible atlas of over 1,200 subjects. This effort has revealed intricate network architectures, such as the default mode network's role in integrating sensory and cognitive signals along the neuraxis, and has set standards for quantifying connectivity variability. Ongoing extensions, including lifespan and pediatric cohorts, continue to refine models of neuraxial development and plasticity.

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