Fact-checked by Grok 2 weeks ago

Motor neuron

A motor neuron, also known as a motoneuron, is a specialized neuron in the that transmits electrical impulses from the or to effector organs, primarily skeletal muscles, to initiate and control voluntary and involuntary movements. These neurons form the final common pathway for motor commands, integrating sensory input and higher brain signals to enable coordinated actions such as walking, grasping, or maintaining . Motor neurons are characterized by their long axons, which can extend from the to distant muscles, and they operate within a two-neuron circuit that ensures precise signal relay. Motor neurons are broadly classified into upper motor neurons and lower motor neurons, each with distinct anatomical locations and functions. Upper motor neurons originate in the , particularly the in layer 5 (Betz cells), and descend through pathways like the to synapse with lower motor neurons in the or . These neurons use as their primary and play a key role in planning, initiating, and modulating movements, with approximately 90% of their fibers crossing the midline at the medullary pyramids to form the . Damage to upper motor neurons often results in and , highlighting their inhibitory and facilitatory influence on lower circuits. In contrast, lower motor neurons are located in the ventral horn of the spinal cord (for limb and trunk muscles) or in brainstem nuclei (for head and neck muscles), directly innervating skeletal muscles via neuromuscular junctions. They release acetylcholine to trigger muscle contraction and are subdivided into somatic types, including alpha motor neurons that innervate extrafusal muscle fibers for generating force, gamma motor neurons that adjust muscle spindle sensitivity to maintain tone and proprioception, and less common beta motor neurons that target both fiber types. Lower motor neurons are organized into motor pools—clusters of 100 to several thousand neurons—each dedicated to a specific muscle, with their axons forming motor units that determine the precision and strength of contractions based on neuron size and firing rate. Lesions here lead to flaccid paralysis, atrophy, and hyporeflexia, underscoring their direct executive role. The diversity of motor neurons arises during embryonic development in the ventral , where progenitor cells in the domain differentiate under the influence of signaling molecules like Sonic Hedgehog (SHH) and (RA), guided by transcription factors such as OLIG2 and MNX1. This process generates over 500 distinct spinal motor neuron pools, tailored to specific muscle targets and exhibiting variations in electrophysiological properties, such as conduction velocity and fatigue resistance, to support complex behaviors like . Overall, motor neurons exemplify the nervous system's precision in translating neural commands into physical action, with their structure and connectivity forming the foundation of .

Overview and Classification

Definition and Role

Motor neurons, also known as motoneurons, are specialized efferent neurons that transmit electrical signals from the (CNS) to peripheral effectors, such as skeletal muscles, smooth muscles, or glands, to elicit responses like or . These neurons form the final common pathway in circuits, integrating inputs from the and to execute precise actions. The concept of motor neurons as distinct cellular units was first elucidated in the late by Spanish neuroscientist , who utilized Camillo Golgi's silver staining technique to visualize and describe their morphology in the . Cajal's detailed illustrations of spinal motor cells demonstrated their individuality and connectivity, laying the groundwork for the neuron doctrine and modern . At their core, motor neurons play a pivotal role in transforming neural impulses into physical outputs, enabling both voluntary movements—such as reaching for an object—and involuntary processes, including arcs and autonomic regulations like glandular . This conversion is essential for coordinating bodily functions, from locomotion to . In contrast to sensory neurons, which carry afferent signals from peripheral receptors toward the CNS to convey environmental or internal stimuli, motor neurons propagate outgoing efferent signals away from the CNS to directly influence effector organs. Motor neurons are broadly classified into upper motor neurons, located in the , and lower motor neurons, situated in the and , though their detailed subtypes are explored elsewhere.

Types of Motor Neurons

Motor neurons are broadly classified into upper and lower types based on their anatomical location and role in the motor pathway. Upper motor neurons (UMNs) originate primarily in the , particularly the (Betz cells in layer V), and in certain brainstem nuclei, where they integrate sensory and cortical inputs to plan and initiate voluntary movements. These neurons project axons via descending tracts, such as the , to with lower motor neurons in the or , using as their primary . In contrast, lower motor neurons (LMNs) are situated in the ventral horn of the or in motor nuclei and serve as the final common pathway, directly conveying motor commands to effector organs like muscles and glands via acetylcholine-mediated transmission. A key classification scheme for motor neurons, particularly LMNs, draws from both phylogenetic and ontogenetic criteria, dividing them into and visceral categories based on evolutionary origins and developmental patterns. Phylogenetically, motor neurons innervate skeletal muscles derived from somites for body wall and limb movements, while visceral motor neurons target smooth muscles, , and glands associated with internal organ regulation. Ontogenetically, this further subdivides into general (common to all vertebrates, e.g., general efferent for axial muscles) and (derived for specific adaptations, e.g., special visceral efferent for muscles). Somatic motor neurons, the primary effectors for voluntary , are located in the and (Rexed lamina IX) and directly innervate skeletal muscles. They include alpha motor neurons, which innervate extrafusal muscle fibers to generate force and ; gamma motor neurons, which regulate intrafusal fibers in muscle spindles to maintain proprioceptive sensitivity; and beta motor neurons, which co-innervate both fiber types, though their role remains less defined. Visceral motor neurons form part of the and are subdivided into general and special types. General visceral motor neurons provide parasympathetic and sympathetic innervation to smooth muscles and glands, with cell bodies in nuclei (e.g., dorsal motor nucleus of the vagus) or spinal intermediolateral columns (T1-L2 for sympathetic, S2-S4 for parasympathetic). Special visceral (branchial) motor neurons, located in nuclei like the , innervate striated muscles of origin in the head and neck, such as those involved in and via V, VII, IX, X, and XI.

Development

Embryonic Formation

Motor neurons originate from progenitor cells in the ventral domains of the developing , specifically within the and . These progenitors are specified through inductive signals, primarily Sonic hedgehog (Shh), secreted by the and overlying floor plate, which establishes a ventral-to-dorsal gradient to pattern the . Shh activates a cascade of transcription factors, including Nkx6.1 and Olig2, in the pMN (motor neuron progenitor) domain, committing cells to the motor neuron fate while suppressing alternative ventral identities like . Along the rostrocaudal axis, Hox transcription factor networks regulate the spatial patterning of motor neuron subtypes, determining columnar identities such as those in , thoracic, and segments. , including Hox4–Hox8 for brachial levels and Hox9–Hox11 for levels, collaborate with cofactors like Foxp1 to diversify motor neuron pools, ensuring appropriate targeting of axial, limb, and body wall muscles. Motor neurons organize into distinct columns during early embryogenesis: the lateral motor column (LMC), which innervates limb muscles and divides into medial and lateral divisions, and the , responsible for axial musculature. This columnar architecture emerges as postmitotic motor neurons migrate and cluster based on Hox-dependent positional cues, with LMC formation restricted to limb-innervating segments. In mice, initial motor neuron specification occurs around embryonic day 9–10 (E9–E10), coinciding with pMN domain induction, followed by postmitotic differentiation by E10.5 and early axon outgrowth shortly thereafter. These events correspond to approximately weeks 4–5 of human gestation, with initial axon outgrowth reaching peripheral targets by week 6.

Postnatal Maturation

After birth, motor neurons undergo significant refinement to achieve functional maturity, integrating embryonic-formed circuits with experience-driven adaptations. This postnatal phase involves the strengthening of synaptic connections, selective elimination of superfluous branches, and enhancement of axonal conduction through myelination, all occurring over critical periods that vary by species but typically span the first few weeks to years in mammals. These processes ensure precise motor control, with human motor pools continuing to mature into early childhood. Synaptogenesis in postnatal motor neurons primarily occurs at central synapses with and at peripheral s, driven by activity-dependent mechanisms involving signaling. Activation of s promotes dendritic elaboration and formation in spinal motor neurons during early postnatal life, as demonstrated in models where blockade of these receptors reduces dendritic branching and synaptic density. At the , initial polyinnervation by multiple motor axons on single muscle fibers transitions to monop innervation through competitive , facilitated by agrin-muscle-specific signaling and glial support from Schwann cells. This process peaks in the first two postnatal weeks in mice, establishing efficient muscle fiber control. Pruning and refine motor neuron connectivity by eliminating excess and axonal branches during sensitive developmental windows. In the , motor neuron axons initially overproduce collaterals that are selectively retracted based on activity patterns, with up to 50% of branches pruned by the end of the second postnatal week in to optimize motor pool specificity. at central inputs involves microglial engulfment of weak connections, while at neuromuscular junctions, synapse elimination reduces multiple inputs to one per , a process that continues into the third postnatal week and is modulated by like BDNF. This allows motor circuits to adapt, with critical periods closing around postnatal day 10-14 in mice, after which rewiring becomes limited. Myelination of motor neuron axons progresses postnatally to accelerate impulse conduction, with central axons ensheathed by oligodendrocytes and peripheral axons by Schwann cells. In developing motor circuits, axon remodeling must complete before myelination initiates, as seen in mouse studies where branch pruning precedes Schwann cell wrapping along peripheral motor axons during the second postnatal week. This sequential process enhances conduction velocity from unmyelinated speeds of ~1 m/s to myelinated rates exceeding 50 m/s in larger fibers, supporting coordinated movements. In humans, peripheral myelination of motor axons matures over the first few years, correlating with motor skill milestones. Sensory and motor activity profoundly shape postnatal motor neuron maturation through experience-dependent mechanisms. Spontaneous limb movements and sensory inputs drive NMDA receptor-mediated dendritic in spinal motor neurons, with deprivation studies in neonatal rats showing reduced dendrite complexity and impaired motor function if activity is blocked early. For instance, exercise in young enhances motor pool refinement via afferent , promoting stabilization and axonal to match behavioral demands. In infancy, crawling and walking experiences similarly refine motor neuron circuits, integrating sensory-motor loops for skill acquisition like grasping.

Anatomy

Upper Motor Neurons

Upper motor neurons (UMNs) are the neurons whose cell bodies reside in the , specifically within the and , and whose axons form the descending motor pathways that influence lower motor neurons. In the , UMNs are primarily located in layer V of the (), particularly in the , where the largest examples, known as Betz cells, are found. Additional cortical populations of UMNs exist in the (, anterior to the ) and the (on the medial surface of the , anterior to the leg representation in the ). These cortical UMNs integrate sensory and associative inputs to initiate and plan voluntary movements. Morphologically, UMNs in the are large pyramidal neurons characterized by prominent apical dendrites that extend toward layer I and extensive basal dendritic arborizations. Betz cells, the gigantopyramidal subset in the , have somata with diameters reaching up to 100 μm and generate long axons that can span the entire length of the . In the , UMNs are situated in subcortical nuclei such as the in the , which contributes to the for limb coordination. Cortical UMNs project to pontine and medullary motor nuclei for cranial nerve control via the . These and cortical UMNs exhibit varied morphologies but share the feature of projecting axons that relay signals to spinal or bulbar levels. UMNs display significant diversity in their organization and function, reflecting the somatotopic mapping of the body. In the , UMNs are arranged in a somatotopic fashion, forming a distorted body representation known as the motor homunculus, where regions controlling the face, upper limbs, trunk, and lower limbs are sequentially organized from lateral to medial along the . This organization ensures precise control over specific muscle groups, with larger cortical areas devoted to fine motor skills like those in the hands. UMNs, in contrast, primarily support spinal motor functions, such as limb coordination, through pathways that target motor nuclei in the . The axonal projections of UMNs form key descending tracts, including the corticospinal and corticobulbar pathways. Corticospinal axons from cortical UMNs descend through the posterior limb of the internal capsule, cerebral peduncles, and medullary pyramids; approximately 90% of these fibers decussate in the lower medulla to form the lateral corticospinal tract, which directly synapses with lower motor neurons in the spinal cord's lateral funiculus for contralateral limb control, while the remaining 10% form the anterior corticospinal tract and decussate at spinal levels for axial musculature. Corticobulbar projections from cortical UMNs target brainstem motor nuclei bilaterally or ipsilaterally, influencing cranial nerves V, VII, IX, X, XI, and XII. Brainstem UMNs, such as those in the red nucleus, provide indirect relays, projecting via the rubrospinal tract to intermediate spinal laminae for upper limb flexion and posture. These projections ultimately connect to lower motor neurons to execute motor commands.

Lower Motor Neurons

Lower motor neurons (LMNs) are the final common pathway for motor commands, with their cell bodies located in the anterior horn of the for muscles of the limbs and trunk, and in cranial nerve nuclei within the for muscles of the head and neck. These neurons receive inputs from upper motor neurons and , integrating signals to directly innervate skeletal muscles. LMNs are multipolar neurons characterized by large cell bodies and extensive dendritic trees that can receive up to 10,000 synaptic inputs, with approximately 2,000 on the and 8,000 distributed across the dendrites. Their axons vary significantly in length, ranging from millimeters in to over 1 meter in spinal nerves extending from the region to the foot. This morphological diversity supports precise control over diverse muscle groups. LMNs are organized into motor pools, clusters of neurons that innervate a single muscle, with the number of neurons per pool varying by muscle size and function—for instance, small hand muscles typically contain about 100 motor neurons. Within these pools, alpha motor neurons innervate extrafusal muscle fibers to generate force, while gamma motor neurons target intrafusal fibers in muscle spindles to regulate sensitivity. Due to their large size and high metabolic demands, LMNs are particularly susceptible to , as they have a reduced to calcium ions compared to other types. This vulnerability contributes to their selective degeneration in certain neurodegenerative conditions.

Nerve Tracts and Pathways

The motor pathways connecting upper motor neurons (UMNs) in the to lower motor neurons (LMNs) in the and primarily consist of descending tracts that enable voluntary and reflexive movements. These pathways include the as the main direct route and various brainstem-mediated extrapyramidal tracts for coordination and posture. The , part of the pyramidal system, originates mainly from layer V pyramidal cells in the , premotor areas, and supplementary motor areas, with additional contributions from somatosensory and parietal cortices. Approximately 85-90% of its fibers decussate at the medullary pyramids, forming the that descends in the lateral funiculus of the to directly or indirectly with LMNs, primarily controlling skilled, fractionated movements of the distal limbs such as finger dexterity. The remaining 10-15% of fibers remain uncrossed, descending ipsilaterally as the anterior corticospinal tract in the anterior funiculus to influence axial and proximal muscles for trunk and girdle stability. Extrapyramidal pathways, which involve indirect routes through subcortical structures like the and , complement the by modulating , , and automatic movements. The arises from the in the , decussates at the ventral tegmental , and descends contralaterally to facilitate flexor muscle activation and fine , particularly in the upper limbs. The vestibulospinal tracts originate from in the —the lateral from the pontine nuclei and medial from medullary nuclei—and descend without full to activate extensor muscles, maintaining and head during . The reticulospinal tracts, from pontine and medullary reticular formations, project bilaterally to influence extensor and locomotor patterns, integrating sensory inputs for and whole-body coordination. These tracts converge on individual LMNs and spinal , allowing integrated motor output where a single LMN may receive inputs from multiple descending pathways, such as the corticospinal and reticulospinal tracts, to fine-tune movement precision and adaptability. For instance, in , up to 44% of interneurons exhibit excitatory convergence from both pyramidal and medial tracts, supporting coordinated hand and arm actions. This multisynaptic integration ensures that voluntary commands from the are modulated by reflexes for efficient .

Physiology

Signal Generation and Propagation

Action potentials in motor neurons are initiated at the axon hillock or initial segment, where the reaches a of approximately -55 mV through the spatial and temporal of excitatory postsynaptic potentials (EPSPs) from synaptic inputs. This depolarization triggers the opening of voltage-gated sodium channels, leading to a rapid influx of Na⁺ ions and the rising phase of the action potential. The high density of sodium channels at this site lowers the compared to other neuronal regions, ensuring reliable initiation of the all-or-none response. Once generated, action potentials propagate along the via in myelinated motor neuron fibers, where the impulse jumps between nodes of Ranvier, enabling efficient and rapid transmission. This mechanism significantly increases conduction speed compared to continuous conduction in unmyelinated , with velocities reaching up to 120 m/s in large α-motor neuron fibers. Conduction velocity approximates v \approx \sqrt{d}, where d is the diameter, though it scales more linearly with diameter in fully myelinated fibers due to reduced and increased . Larger diameters, common in motor neurons innervating fast-twitch muscles, further enhance velocity to support quick motor responses. Motor neurons exhibit distinct firing patterns adapted to motor functions: tonic firing, characterized by sustained, regular discharges, maintains posture and steady contractions, while phasic firing involves high-frequency bursts for rapid, ballistic movements. These patterns are modulated by recurrent inhibition from Renshaw cells, which receive collaterals from the same motor neuron axon and provide negative feedback to prevent excessive firing and stabilize output. This inhibitory loop helps regulate motoneuron excitability during both tonic and phasic activity, contributing to coordinated muscle activation. The electrophysiological activity of motor neurons imposes high energy demands, primarily met through by the Na⁺/K⁺-ATPase pump, which restores ionic gradients after each and accounts for a major portion of neuronal ATP consumption. Large motor neuron axons, with their extensive myelinated lengths, amplify this requirement, making these cells particularly vulnerable to , where impaired rapidly depletes ATP and disrupts ion .

Neuromuscular Junction

The (NMJ) is a highly specialized formed between the of a and the motor end plate of a fiber, enabling precise chemical transmission for . The presynaptic terminal, or nerve ending, is expanded and contains synaptic vesicles packed with (ACh); mammalian terminals typically harbor 200,000 to 500,000 total vesicles, with 1,200–1,600 docked in the readily releasable pool at active zones. The postsynaptic motor end plate features extensive junctional folds that amplify the surface area, concentrating nicotinic ACh receptors (nAChRs) at densities up to 10,000 per μm² to facilitate rapid signaling. Transmission at the NMJ begins when an action potential, propagated from the neuron soma, reaches the presynaptic terminal, depolarizing the membrane and opening voltage-gated Ca²⁺ channels. This Ca²⁺ influx binds to synaptotagmin on synaptic vesicles, triggering their fusion with the presynaptic membrane through the SNARE complex (involving proteins like syntaxin, SNAP-25, and VAMP), which releases ACh via exocytosis into the 50-nm synaptic cleft. ACh diffuses across the cleft in microseconds and binds to postsynaptic nAChRs, ligand-gated cation channels permeable to Na⁺ and K⁺, causing an influx of Na⁺ that depolarizes the end plate from a resting potential of -90 mV to generate an end-plate potential (EPP) of approximately 40–50 mV. This EPP propagates to adjacent muscle membrane regions, exceeding the threshold to trigger a muscle action potential and contraction. To ensure reliable transmission despite physiological variations, the NMJ incorporates a safety factor where the EPP amplitude surpasses the ~30 mV threshold for muscle action potential initiation by 3–5 times in adult mammals. This robustness arises partly from the quantal content—the average number of vesicles () released per impulse—which ranges from 40–100 in rodent NMJs, releasing thousands of molecules collectively to produce a suprathreshold EPP. Disruptions, such as in where autoantibodies target postsynaptic nAChRs or associated proteins like , diminish receptor density and erode the safety factor, leading to fatiguable weakness (full details in ).

Synaptic Inputs and Modulation

Motor neurons receive a variety of synaptic inputs that integrate excitatory and inhibitory signals to precisely control motor output. Excitatory inputs primarily arise from upper motor neurons (UMNs) in the and , as well as from spinal , delivering transmission that depolarizes the motor neuron membrane. These inputs activate ionotropic glutamate receptors, including receptors for rapid, fast excitatory postsynaptic potentials (EPSPs) with decay times of 0.6–2 ms, and NMDA receptors for slower, prolonged EPSPs lasting up to 86 ms due to their voltage-dependent magnesium block and calcium permeability. receptors, composed of GluR1-4 subunits, dominate the initial excitatory drive, while NMDA receptors, featuring NMDAR1 and NMDAR2A-D subunits, contribute to synaptic integration and plasticity in motor neurons. Inhibitory inputs to motor neurons counterbalance excitation, ensuring coordinated muscle activity and preventing overactivation. These inputs originate from spinal , including Renshaw cells and Ia inhibitory , using and as primary neurotransmitters. Renshaw cells provide recurrent inhibition by receiving excitatory collaterals from the same motor neuron pool and releasing onto homonymous and synergistic motor neurons, modulating firing rates through strychnine-sensitive receptors (α1/β subunits) that open channels. Ia inhibitory interneurons mediate , receiving input from Ia afferents of antagonist muscle spindles and projecting glycinergic and GABAergic inhibition to motor neurons of the opposing muscle group, thus facilitating alternating movements like flexion-extension.30004-6) receptors (α2/α3/γ2 subunits) and receptors often co-release transmitters, enhancing inhibitory efficacy on motor neuron dendrites and . Neuromodulatory inputs fine-tune motor neuron excitability beyond direct synaptic excitation or inhibition, often via metabotropic receptors that alter conductances. Monoamines such as serotonin (5-HT) from in the project to spinal motor neurons, binding 5-HT2 receptors to enhance persistent inward currents (PICs), including Na⁺- and Ca²⁺-dependent components, thereby increasing excitability up to fivefold and amplifying synaptic responses. Norepinephrine from the similarly boosts gain through α1 receptors, reducing and promoting plateau potentials. Neuropeptides like , acting via neurokinin-1 (NK1) receptors, further enhance motor neuron excitability by inhibiting conductances and facilitating , as observed in hypoglossal and other cranial motor nuclei. Central pattern generators (CPGs) in the provide rhythmic synaptic inputs to motor neurons, enabling without continuous supraspinal drive. These circuits, comprising in the ventral spinal gray matter, generate alternating excitatory and inhibitory barrages to flexor and extensor motor neuron pools, producing oscillatory patterns at frequencies matching stepping (e.g., 0.5–2 Hz in mammals). and glycinergic/ synapses within the CPG drive phasic activity, modulated by sensory afferents and descending pathways to adapt . In isolated spinal preparations, such as in decerebrate or neonatal , CPG activation elicits fictive locomotion, confirming their role in rhythmogenesis.00581-4)

Function

Somatic Motor Control

Somatic motor control relies on a hierarchical organization where upper motor neurons (UMNs) in the and initiate and plan voluntary movements, while lower motor neurons (LMNs) in the execute these commands by directly innervating fibers. This two-neuron chain enables precise integration of sensory feedback and descending signals to produce coordinated contractions for actions such as walking or grasping. UMNs convey intentions from higher centers, synapsing onto LMNs or , which then generate action potentials that propagate along motor axons to neuromuscular junctions, ultimately resulting in muscle force generation. A key feature of this control is alpha-gamma coactivation, where descending signals simultaneously activate alpha motor neurons innervating extrafusal muscle fibers for and gamma motor neurons innervating intrafusal fibers within muscle to maintain spindle sensitivity to length changes during . This prevents unloading of spindles during shortening, ensuring continuous proprioceptive for smooth and accurate motor adjustments. Without coactivation, reflexes would diminish inappropriately, disrupting and . Computational models demonstrate that this coordination is essential for stable control of both and . Motor unit recruitment follows Henneman's size principle, whereby motor units—comprising one LMN and the muscle fibers it innervates—are activated in order from smallest to largest as force demands increase, allowing graded control from fine precision to high power. Small motor units, with slower-contracting, fatigue-resistant fibers, are recruited first for subtle tasks like maintaining , while larger, faster-fatiguing units add force for vigorous actions. This orderly optimizes efficiency and smoothness, as observed in both animal and human studies of isometric contractions. Reflex arcs provide rapid, automatic adjustments within this system. The monosynaptic stretch reflex, triggered by Ia afferent fibers from muscle spindles, directly excites homonymous LMNs to counteract sudden muscle lengthening, as seen in the knee-jerk response, ensuring stability without higher involvement. In contrast, the polysynaptic withdrawal reflex involves relaying nociceptive input from sensory neurons to multiple LMNs, flexing the limb away from harmful stimuli while often extending the opposite side for balance via crossed extension. These reflexes integrate with voluntary control for protective and adaptive movements. Specific descending pathways fine-tune coordination; for instance, the from the facilitates scaling of grip force in distal muscles by modulating LMN activity during precision tasks like pinching. Similarly, the reticulospinal tract from the pontine and medullary reticular formation adjusts extensor and flexor tone across gait cycles, synchronizing limb phases with for rhythmic locomotion. These inputs ensure seamless transitions between voluntary intent and reflexive .

Visceral Motor Control

Visceral motor neurons, also known as , regulate involuntary functions of internal organs, glands, and through the , distinct from the voluntary control exerted by motor neurons over skeletal muscles. These neurons are divided into general visceral efferent pathways, which target , , and glands, and special visceral efferent pathways, which innervate striated muscles derived from branchial arches. In the general visceral efferent system, preganglionic neurons originate in the central nervous system and synapse with postganglionic neurons in peripheral ganglia before reaching effector organs. For the sympathetic division, these preganglionic neurons are located in the intermediolateral cell column of the spinal cord from thoracic levels T1 to lumbar level L2 (or L3 in some descriptions), forming the thoracolumbar outflow. Sympathetic postganglionic neurons reside in paravertebral chain ganglia or prevertebral ganglia, such as the celiac and superior mesenteric ganglia, enabling widespread distribution to visceral targets like the heart, lungs, and abdominal organs. In contrast, parasympathetic preganglionic neurons arise primarily from nuclei in the brainstem, including the Edinger-Westphal nucleus (cranial nerve III), superior salivatory nucleus (VII), inferior salivatory nucleus (IX), and dorsal motor nucleus of the vagus (X), with additional sacral origins in the intermediolateral column at S2-S4 for pelvic organs. Parasympathetic postganglionic neurons are situated in intramural ganglia close to or within target tissues, such as those in the heart or gastrointestinal tract, facilitating localized control. Special visceral efferent neurons provide motor innervation to skeletal muscles embryologically derived from the branchial arches, supporting functions like and . These neurons are primarily located in the , a column of motor neurons in the that contributes fibers to IX, X, and XI. For example, neurons innervate laryngeal and pharyngeal muscles via the (cranial nerve X), enabling coordinated actions in voice production and airway protection during . This pathway underscores the role of visceral motor control in essential, involuntary orofacial and respiratory reflexes, paralleling control but targeting phylogenetically older muscle groups. Neurotransmitter usage in visceral motor pathways exhibits specific patterns that underpin sympathetic "fight-or-flight" activation and parasympathetic "rest-and-digest" maintenance. All preganglionic neurons in both sympathetic and parasympathetic divisions release () onto nicotinic receptors in autonomic ganglia, ensuring reliable synaptic transmission. Sympathetic postganglionic neurons predominantly release norepinephrine (noradrenaline) onto adrenergic receptors in target tissues, promoting effects like and increased , though some exceptions include sympathetic innervation to sweat glands. Parasympathetic postganglionic neurons, however, release onto muscarinic receptors, eliciting responses such as glandular and slowed cardiac activity. This dual-neurotransmitter strategy allows for diverse modulation of visceral functions without direct conscious oversight. Visceral motor neurons integrate sensory inputs through brainstem reflexes to maintain homeostasis, exemplified by the baroreflex, which adjusts in response to changes. in the and detect pressure variations and relay signals via the glossopharyngeal (IX) and vagus (X) nerves to the tractus solitarius (NTS) in the medulla. The NTS then modulates visceral motor output: elevated pressure activates parasympathetic preganglionic neurons in the dorsal motor nucleus of the vagus to slow , while inhibiting sympathetic preganglionic neurons in the intermediolateral column to reduce vascular tone and . This demonstrates how visceral motor neurons coordinate rapid, involuntary adjustments to sustain cardiovascular stability, integrating with higher brain centers for broader autonomic regulation.

Clinical Aspects

Motor Neuron Diseases

Motor neuron diseases encompass a group of progressive neurodegenerative disorders characterized by the selective degeneration of upper motor neurons (UMNs) in the and lower motor neurons (LMNs) in the and , leading to , , and eventual . These conditions primarily impair voluntary and can involve respiratory and bulbar functions, with varying etiologies including genetic mutations and unknown sporadic factors. The most prominent examples include (ALS), (SMA), and (PBP), each demonstrating distinct patterns of motor neuron vulnerability. Amyotrophic lateral sclerosis (ALS), also known as Lou Gehrig's disease, involves the simultaneous degeneration of both UMNs and LMNs, resulting in a combination of upper and lower motor neuron signs. Approximately 90% of cases are sporadic with no identifiable cause, while 10% are familial, often linked to mutations in genes such as SOD1 (accounting for 12-20% of familial cases) or C9orf72 (25-40%). Clinical presentation typically includes muscle fasciculations, spasticity from UMN involvement, progressive weakness, and atrophy from LMN loss, beginning in the limbs or bulbar region and spreading relentlessly. The incidence of ALS is estimated at 1 to 2 cases per 100,000 person-years, with higher rates in individuals aged 55-75 and a slight male predominance. Spinal muscular atrophy (SMA) is a hereditary disorder primarily affecting LMNs in the , caused by deletions or mutations in the gene on 5q13, which encodes the survival motor neuron (SMN) protein essential for motor neuron maintenance. This autosomal recessive condition leads to insufficient SMN protein levels, resulting in progressive LMN degeneration and severe weakness without UMN involvement. In its most common infantile form (Type I, Werdnig-Hoffmann disease), symptoms manifest before 6 months of age as profound , reduced fetal movements, feeding and breathing difficulties, and delayed motor milestones, often progressing to . The number of gene copies, which partially compensates for SMN1 loss, influences disease severity, with fewer copies correlating to earlier onset and worse prognosis. Progressive bulbar palsy (PBP) represents a subtype of motor neuron disease characterized by early and predominant degeneration of LMNs in the nuclei that innervate bulbar muscles. This leads to progressive weakness in the muscles of the face, , pharynx, and larynx, manifesting as (slurred or nasal speech), (difficulty swallowing with choking risk), tongue atrophy and fasciculations, and reduced gag reflex. Often considered a bulbar-onset variant of , PBP's mirrors sporadic or genetic ALS mechanisms but with selective vulnerability, and many cases progress to involve limb muscles and signs.

Diagnostic and Therapeutic Approaches

Diagnosis of (MNDs), particularly (ALS), is primarily clinical, requiring evidence of progressive degeneration in both upper motor neurons (UMNs) and lower motor neurons (LMNs) across multiple spinal regions, without sensory or autonomic involvement. Standardized criteria, such as the revised or Awaji criteria, guide classification from possible to definite ALS based on the number of affected regions and the presence of UMN signs like and alongside LMN signs such as fasciculations and . These criteria emphasize the need for longitudinal assessment to confirm progression, as initial presentations may mimic other neuromuscular disorders. Electrophysiological studies form the cornerstone of confirmatory testing. Needle (EMG) reveals active (fibrillation potentials, positive sharp waves) and chronic reinnervation (large potentials) in clinically affected and subclinical muscles, often fulfilling the Awaji criteria for earlier by equating potentials to . conduction studies (NCS) are normal or show reduced muscle potentials in advanced but help exclude demyelinating neuropathies. (TMS) can quantify UMN dysfunction through prolonged central motor conduction times, aiding in cases with equivocal clinical UMN . Imaging and laboratory tests exclude mimics and support diagnosis. (MRI) of the and is recommended to rule out compressive lesions or other pathologies, with T2 hyperintensities in the occasionally seen in but not diagnostic. Blood tests assess (elevated in ), thyroid function, and vitamins, while cerebrospinal fluid analysis may show elevated neurofilament light chain as a of neuronal damage. , targeting genes like SOD1, C9orf72, and TARDBP, is indicated for familial (5-10% of cases) or early-onset sporadic disease, informing prognosis and targeted therapies. Therapeutic approaches for MNDs focus on disease modification, symptom relief, and supportive care through multidisciplinary teams, which improve survival and . , approved in 1995, is the first-line disease-modifying agent; it inhibits glutamate release, extending median survival by 2-3 months when administered at 50 mg twice daily, with monthly liver function monitoring required initially. , an intravenous or oral introduced in 2017 and 2022 respectively, reduces and slows functional decline by approximately 33% in early-stage patients over 24 weeks. For SOD1-mutated (about 2% of cases), (Qalsody), an intrathecal antisense approved by the FDA in 2023, targets mutant mRNA to decrease toxic protein levels, leading to reduced light chain and slower progression in clinical trials. For (), approved disease-modifying therapies target SMN protein production and have dramatically improved outcomes, especially with early intervention. (Spinraza), an approved by the FDA in 2016, is administered intrathecally every 4 months after loading doses to enhance SMN2 splicing and increase functional SMN protein. (Zolgensma), a one-time intravenous approved in 2019 for children under 2 years, delivers a functional copy using an AAV9 . (Evrysdi), an oral approved in 2020 for patients aged 2 months and older (with a tablet formulation approved in 2025), modulates SMN2 splicing to boost SMN protein levels. These treatments can enable motor milestone achievement and prolong survival in SMA types I-III when started presymptomatically or early. Symptomatic management addresses common complications. (NIV), initiated at below 50%, prolongs survival by 7 months and enhances in patients with preserved bulbar function. Nutritional support via (PEG) is recommended at 10% to maintain intake, potentially extending survival despite limited randomized evidence. is treated with or , sialorrhea with glycopyrrolate or injections, and with dextromethorphan-quinidine (Nuedexta). Physical and speech therapies preserve function, while multidisciplinary care in specialized centers reduces hospitalization rates by up to 50%. Emerging precision medicine targets genetic subtypes, with ongoing trials for C9orf72-directed therapies and transplants showing promise in preclinical models but no widespread approval as of 2025.

References

  1. [1]
    Neuroanatomy, Motor Neuron - StatPearls - NCBI Bookshelf
    Jul 24, 2023 · Motor neurons (or motoneurons) comprise various tightly controlled, complex circuits throughout the body that allows for both voluntary and involuntary ...
  2. [2]
    Motor Units and Muscle Receptors (Section 3, Chapter 1 ...
    The motor neurons that control limb and body movements are located in the anterior horn of the spinal cord, and the motor neurons that control head and facial ...Missing: definition | Show results with:definition
  3. [3]
    Motor neurons and the generation of spinal motor neuron diversity
    Motor neurons (MNs) are neuronal cells located in the central nervous system (CNS) controlling a variety of downstream targets. This function infers the ...
  4. [4]
    [PDF] Santiago Ramón y Cajal - Nobel Lecture
    A, spinal-cord motor cell of the hibernating lizard; a, another funicular cell;. B, b, the same spinal-cord cells of the lizard after several hours at a ...
  5. [5]
    Speed read: Exposing the forest - NobelPrize.org
    Sep 16, 2009 · Golgi's silver staining method for nerves went unappreciated, until Ramón y Cajal enhanced its resolution and used this technique to investigate ...
  6. [6]
    Types of neurons - Queensland Brain Institute
    Motor neurons. Motor neurons of the spinal cord are part of the central nervous system (CNS) and connect to muscles, glands and organs throughout the body.
  7. [7]
    Overview of neuron structure and function (article) - Khan Academy
    Sensory neurons bring signals into the CNS, and motor neurons carry signals out of the CNS. Diagram of the human nervous system. Central nervous system: ...
  8. [8]
    An Overview of Brainstem and Cranial Nerve Anatomy - Neupsy Key
    Jul 19, 2016 · The cell columns are divided into motor (efferent) and sensory (afferent) and into general and special, somatic and visceral cell types.
  9. [9]
    Motor Neuron - an overview | ScienceDirect Topics
    In adults, somatic MNs are classified into three different classes: (1) α (alpha) MNs, (2) β (beta) MNs, and (3) γ (gamma) MNs. α-MNs are the most abundant ...
  10. [10]
    Physiology, Motor Cortical - StatPearls - NCBI Bookshelf
    Jun 8, 2024 · The primary function of the motor cortex is to send signals to direct the body's movement. The motor cortex is part of the frontal lobe and is anterior to the ...Missing: morphology | Show results with:morphology
  11. [11]
    Betz cells of the primary motor cortex - PMC - PubMed Central - NIH
    Betz cells are 'gigantopyramidal' extratelencephalic projection neurons of the primary motor cortex that are part of the monosynaptic cortico‐motoneuronal ...
  12. [12]
    Red nucleus structure and function: from anatomy to clinical ...
    Nov 12, 2020 · The red nucleus (RN) is a large subcortical structure located in the ventral midbrain. Although it originated as a primitive relay between the cerebellum and ...Missing: corticobulbar | Show results with:corticobulbar
  13. [13]
    Motor Cortex (Section 3, Chapter 3) Neuroscience Online
    Individual alpha motor neurons control the force exerted by a particular muscle, and spinal circuits can control sophisticated and complex behaviors such as ...
  14. [14]
    Neuroanatomy, Corticobulbar Tract - StatPearls - NCBI Bookshelf
    Corticobulbar tract carries upper motor neuron input to motor nuclei of trigeminal, facial, glossopharyngeal, vagus, accessory, and hypoglossal nerves. The ...
  15. [15]
    Anatomy of the Spinal Cord (Section 2, Chapter 3) Neuroscience ...
    Lower motor neuron nuclei are located in the ventral horn of the spinal cord. They contain predominantly motor nuclei consisting of α, β and γ motor neurons and ...
  16. [16]
    Disorders of the Motor System (Section 3, Chapter 6) Neuroscience ...
    Furthermore, nearby motor neuron pools control nearby muscles. Thus, restricted damage to lower motor neurons, either within the spinal cord or at the ventral ...Missing: definition | Show results with:definition
  17. [17]
    Organization of Cell Types (Section 1, Chapter 8) Neuroscience ...
    For instance, an average spinal motor neuron with a moderate-sized dendritic tree, receives 10,000 contacts, with 2,000 of these on the soma and 8,000 on the ...
  18. [18]
    Axonal Length Determines Distinct Homeostatic Phenotypes in ...
    Their axons extend up to 1m in length and require a complex interplay of mechanisms to maintain cellular homeostasis.Missing: lower | Show results with:lower
  19. [19]
    Motor unit estimation: anxieties and achievements - PubMed
    A small muscle of the hand contains about 100 motor units and greater numbers are found in larger muscles; beyond 60 years the numbers begin to decline.
  20. [20]
    Gamma and alpha motor neurons distinguished by expression of ...
    Aug 11, 2009 · Alpha motor neurons predominate within motor pools and innervate force-generating extrafusal muscle fibers at neuromuscular junctions (13).Missing: length | Show results with:length
  21. [21]
    Selective loss of alpha motor neurons with sparing of gamma motor ...
    For example, within the mammalian spinal cord, lower motor neuron pools in the ventral grey horn contain both alpha motor neurons (α‐MNs), which innervate ...
  22. [22]
    Motor Neuron Susceptibility in ALS/FTD - PMC - PubMed Central - NIH
    Motor neurons may be vulnerable to excitotoxicity because they possess a lower capacity than other neurons to buffer Ca2+ upon stimulation (Van Den Bosch et ...
  23. [23]
    Motor neuron vulnerability and resistance in amyotrophic lateral ...
    Apr 13, 2017 · Here, we discuss the pattern of lower MN degeneration in ALS and review the current literature on OMN resistance in ALS and differential spinal MN ...
  24. [24]
    Neuroanatomy, Pyramidal Tract - StatPearls - NCBI Bookshelf - NIH
    The pyramidal tract originates from the cerebral cortex, and it divides into two main tracts: the corticospinal tract and the corticobulbar tract.
  25. [25]
    Neuroanatomy, Extrapyramidal System - StatPearls - NCBI Bookshelf
    From all these centers, numerous subcortical tracts, or the extrapyramidal tracts, stem out and terminate in the spinal cord. However, the majority of tracts ...
  26. [26]
    Convergence of Pyramidal and Medial Brain Stem Descending ...
    We investigated the control of spinal interneurons by corticospinal and medial brain stem descending tracts in two macaque monkeys.
  27. [27]
    Threshold Potential - an overview | ScienceDirect Topics
    At the axon hillock the resting potential is about –70 mV and the threshold potential is about –55 mV. In neurons, the sequence of action potentials is referred ...
  28. [28]
    Axonal Action-Potential Initiation and Na+ Channel Densities in the ...
    A long-standing hypothesis is that action potentials initiate first in the axon hillock/initial segment (AH–IS) region because of a locally high density of Na ...
  29. [29]
    Excitatory Postsynaptic Potential - an overview | ScienceDirect Topics
    An excitatory postsynaptic potential (EPSP) is a graded depolarization caused by the arrival of a neurotransmitter at the postsynaptic membrane.
  30. [30]
    Motor Axon - an overview | ScienceDirect Topics
    Conduction velocities of myelinated axons range from 120 m/s in α motor neurons to less than 0.5 m/s in postganglionic sympathetic fibers.Missing: saltatory formula
  31. [31]
    Saltatory Conduction along Myelinated Axons Involves a Periaxonal ...
    Dec 26, 2019 · The propagation of electrical impulses along axons is highly accelerated by the myelin sheath and produces saltating or “jumping” action ...Missing: formula | Show results with:formula
  32. [32]
    Conduction Velocity - an overview | ScienceDirect Topics
    The conduction velocity in a large myelinated fiber is on the order of 100 m s−1. Thus, the action potential is spread out over a distance of 100 m s−1×0.002 s= ...
  33. [33]
    The optimal neural strategy for a stable motor task requires a ...
    In the model, phasic and tonic gamma motor neuron ... Renshaw cell recurrent inhibition improves physiological tremor by reducing corticomuscular coupling at 10 ...
  34. [34]
    Recurrent inhibition of individual Ia inhibitory interneurones and ...
    ... inhibition of the Ia inhibitory interneurones, is predominantly linked with rapid phasic, rather than slow tonic, motoneuronal firing. The functional role ...
  35. [35]
    Developmental Disruption of Recurrent Inhibitory Feedback Results ...
    When activating muscles, motor neurons in the spinal cord also activate Renshaw cells, which provide recurrent inhibitory feedback to the motor neurons.
  36. [36]
    Brain Na+, K+-ATPase Activity In Aging and Disease - PMC
    As mentioned above, the major source of energy demand in neurons is the Na+, K+-ATPase pump that restores ionic gradients across the plasma membrane subsequent ...
  37. [37]
    Energy metabolism in ALS: an underappreciated opportunity? - PMC
    Moreover, the remarkable vulnerability of motor neurons to ATP depletion has become increasingly clear. Here, we review metabolic alterations present in ALS ...Fig. 2 · Targeting Oxidative Stress · Fueling Energy Metabolism
  38. [38]
    Synaptic Vesicle Endocytosis in Different Model Systems - Frontiers
    The total number of active zones per neuromuscular junction ranges between 50–250 (110 on average). ... number of vesicles (about 2 vesicles per active ...<|control11|><|separator|>
  39. [39]
    Presynaptic active zones of mammalian neuromuscular junctions
    Early observations showed that the size of active zones correlates with the quantal content or the number of synaptic vesicles released by the presynaptic ...
  40. [40]
    Physiology, Neuromuscular Junction - StatPearls - NCBI Bookshelf
    Feb 17, 2025 · The neuromuscular junction (NMJ) is a specialized synapse that connects motor neurons and skeletal muscle fibers.
  41. [41]
    Physiology, Neuromuscular Transmission - StatPearls - NCBI - NIH
    Mar 9, 2025 · The neuromuscular junction (NMJ) is responsible for the chemical transmission of electrical impulses from nerves to muscles (skeletal, smooth, or cardiac)
  42. [42]
    Chapter 4: Synaptic Transmission and the Skeletal Neuromuscular ...
    Indeed, the amplitude of the endplate potential is about 50 mV, but only about 30 mV is needed to reach threshold. The extra 20 mV is called the safety factor.
  43. [43]
    Safety factor at the neuromuscular junction - PubMed
    In normal adult mammals, the safety factor is generally 3-5. Both pre- and postsynaptic components change during development and may show plasticity in ...
  44. [44]
    Post-synaptic specialization of the neuromuscular junction
    Jun 19, 2022 · In mouse and rat NMJs, the quantal content is about 40–100, while the humans usually are about 20, so the activation of endplate areas occurs at ...
  45. [45]
    Synaptic Control of Motoneuronal Excitability - PMC - PubMed Central
    ... synaptic inputs from multiple classes of afferent fibers. We refer the ... motor neuron identity. Cell. 1996;87:661–673. doi: 10.1016/s0092-8674(00) ...
  46. [46]
    Principles of interneuron development learned from Renshaw cells ...
    Motoneurons are arranged in pools that innervate different muscles. While Renshaw cells receive inputs from certain pools and provide feedback inhibition to ...
  47. [47]
    Motoneuron excitability: the importance of neuromodulatory inputs
    Using the example of cat medial gastrocnemius motoneurons, the threshold range is from about 3 nA to more than 30 nA (Heckman and Binder, 1991). Most of this ...
  48. [48]
    Central Pattern Generation of Locomotion: A Review of the Evidence
    This article reviews the evidence for CPGs governing locomotion and addresses other factors, including supraspinal, sensory, and neuromodulatory influences.Abstract · Evidence of Locomotor CPGs · Supraspinal Influences on...
  49. [49]
    Hierarchical motor control in mammals and machines - Nature
    Dec 2, 2019 · We review these core principles of hierarchical control, relate them to hierarchy in the nervous system, and highlight research themes that we anticipate will ...
  50. [50]
    Coordinated alpha and gamma control of muscles and spindles in ...
    The results argue that coordinated γ control with α activation is essential for accurate and stable control of movement and posture. Preliminary analysis of ...
  51. [51]
    The size principle: a rule describing the recruitment of motoneurons
    This size principle dictates the order of recruitment in the stretch reflex and . . . the flexor reflex.” At the end of this paper, the concept of “usage” is ...
  52. [52]
    Assessment of size ordered recruitment - PMC - PubMed Central
    Jun 30, 2014 · The purpose of this short article is to clarify the basic essence of size ranked or orderly recruitment of motoneurons by addressing conclusions about the ...
  53. [53]
    Spinal Reflexes and Descending Motor Pathways (Section 3 ...
    Descending motor pathways arise from multiple regions of the brain and send axons down the spinal cord that innervate alpha motor neurons, gamma motor neurons, ...
  54. [54]
    Formation of Specific Monosynaptic Connections between Muscle ...
    May 1, 1997 · Ia afferents from one muscle make strong monosynaptic excitatory synapses with motoneurons supplying the same and synergistic muscles, but Ia ...
  55. [55]
    Physiology, Withdrawal Response - StatPearls - NCBI Bookshelf - NIH
    The withdrawal reflex is polysynaptic, meaning that, in addition to the sensory and motor neurons, this response utilizes interneurons, which pass signals ...
  56. [56]
    Corticospinal vs Rubrospinal Revisited: An Evolutionary Perspective ...
    Jun 11, 2021 · In the last 150 years, there has been a dispute about the functions of corticospinal (CS) and rubrospinal (RS) tracts. Both are descending motor ...
  57. [57]
    Differential modulation of descending signals from the reticulospinal ...
    We suggest that during locomotion the activity in interneuronal pathways mediating signals from the reticulospinal system is subject to strong modulation by the ...
  58. [58]
    Reticulospinal Systems for Tuning Motor Commands - PMC
    Apr 18, 2018 · In this review article, we first discuss nomenclature of the RF, and then examine the reticulospinal motor command system through evolution.
  59. [59]
    Anatomy, Autonomic Nervous System - StatPearls - NCBI Bookshelf
    Dorsal nucleus: provides parasympathetic output to the viscera. Nucleus ambiguus: produces motor fibers and preganglionic neurons that innervate the heart.
  60. [60]
    Special Visceral Efferent - an overview | ScienceDirect Topics
    Special visceral efferent motor neurons innervate striated muscle derived from branchial arch mesoderm and are found in cranial nerves V, VII, IX, X, and XI.
  61. [61]
    Sympathetic nervous system: Definition, anatomy, function - Kenhub
    Sympathetic nervous system ; Preganglionic neurons, Neurons of the intermediolateral column of the spinal cord, found within the levels T1-T12 and L1-L3.
  62. [62]
    The Sympathetic Division of the Visceral Motor System - NCBI - NIH
    The sympathetic division prepares the body for "flight or fight" by maximizing resources, and is tonically active to maintain target function.
  63. [63]
    Neuroanatomy, Parasympathetic Nervous System - StatPearls - NCBI
    Those preganglionic parasympathetic neurons that begin in the brainstem leave the central nervous system (CNS) through cranial nerves. Cranial nerves ...Bookshelf · Structure And Function · Clinical Significance
  64. [64]
    Parasympathetic nervous system: Anatomy and functions - Kenhub
    The presynaptic neurons of the parasympathetic system are located within the medulla oblongata and sacral spinal cord.Structure · Cranial Part · Functions
  65. [65]
    Neuroanatomy, Nucleus Ambiguus - StatPearls - NCBI Bookshelf
    The nucleus ambiguus is the location of cell bodies of motor nerves that innervate the ipsilateral muscles of the soft palate, pharynx, larynx and upper ...
  66. [66]
    Cranial nerve nuclei: Anatomy and embryology | Kenhub
    General somatic efferent (motor) nuclei. The general somatic efferent column consists of the following nuclei that supply striated (skeletal) muscles of ...
  67. [67]
    Neurotransmitters of Autonomic Nervous System - IntechOpen
    Sep 19, 2023 · Acetylcholine and norepinephrine are the two major neurotransmitters involved in ANMJ [1, 5]. Acetylcholine is the neurotransmitter released by ...
  68. [68]
    3 Autonomic Neurotransmission - Oxford Academic
    May 1, 2014 · ACh is the primary neurotransmitter of preganglionic neurons, most parasympathetic ganglion neurons, sympathetic ganglion neurons ...<|control11|><|separator|>
  69. [69]
    Physiology, Baroreceptors - StatPearls - NCBI Bookshelf
    Increased stimulation of the nucleus tractus solitarius by arterial baroreceptors results in increased inhibition of the tonically active sympathetic outflow ...Missing: motor | Show results with:motor
  70. [70]
    Baroreceptor Reflex - an overview | ScienceDirect Topics
    The baroreceptor reflex is a physiological mechanism where increased blood pressure is offset by slower heart rates, and vice versa, regulating cardiovascular ...
  71. [71]
    Cardiovascular Brain Circuits | Circulation Research
    May 25, 2023 · Activation of vagal cardiac afferents triggers physiological reflexes to regulate heart rhythm, blood pressure, cardiac output, respiration, and ...
  72. [72]
    Motor Neuron Diseases | National Institute of Neurological Disorders ...
    Mar 26, 2025 · Spinal muscular atrophy (SMA) refers to a group of hereditary diseases that affect lower motor neurons. The most common form is caused by a ...
  73. [73]
    Motor Neuron Disease - StatPearls - NCBI Bookshelf
    Aug 7, 2023 · Amyotrophic lateral sclerosis (ALS):​​ Patients may present with predominantly upper motor neuron (UMN) symptoms (hyperreflexia and spastic ...
  74. [74]
    Amyotrophic Lateral Sclerosis (ALS)
    Mar 26, 2025 · Amyotrophic lateral sclerosis (ALS), formerly known as Lou Gehrig's disease, is a neurological disorder that affects motor neurons.Missing: epidemiology | Show results with:epidemiology
  75. [75]
    Amyotrophic lateral sclerosis: a clinical review - PMC
    The hallmark of ALS is progressive muscle weakness, accompanied by muscle atrophy, fasciculations, muscle cramps and slowness of movements with muscle stiffness ...
  76. [76]
    Risk factors for amyotrophic lateral sclerosis - PMC - PubMed Central
    Amyotrophic lateral sclerosis (ALS) is the most common motor neuron disease. It is typically fatal within 2–5 years of symptom onset. The incidence of ALS ...
  77. [77]
    Spinal Muscular Atrophy
    Jul 30, 2024 · People with SMA experience respiratory infections, scoliosis, and joint contractures (chronic shortening of muscles and tendons). The most ...What is spinal muscular atrophy? · How is spinal muscular...
  78. [78]
    Spinal Muscular Atrophy - GeneReviews® - NCBI Bookshelf - NIH
    Spinal muscular atrophy (SMA) is characterized by muscle weakness and atrophy resulting from progressive degeneration and irreversible loss of the anterior horn ...
  79. [79]
    Motor neurone disease: a practical update on diagnosis and ...
    In the absence of a definitive diagnostic test, the diagnosis of MND is made clinically. Electrophysiology lends support while other investigations are tailored ...Missing: methods | Show results with:methods
  80. [80]
    https://www.ninds.nih.gov/health-information/disorders/spinal-muscular-atrophy
  81. [81]
    Electrodiagnosis in Amyotrophic Lateral Sclerosis - PubMed Central
    The electrodiagnostic evaluation in a suspected MND case requires peripheral NCS and needle EMG. Additional techniques such as repetitive stimulation, single ...
  82. [82]
    Novel approaches to assessing upper motor neuron dysfunction in ...
    The present review will discuss the utility of TMS and brain neuroimaging derived biomarkers of UMN dysfunction in MND, focusing on recently developed TMS ...
  83. [83]
    https://doi.org/10.1080/146608200300079536
  84. [84]
    Medications for Treating ALS - The ALS Association
    Qalsody is a genetically targeted therapy approved by the Food and Drug Administration (FDA) in 2023 to treat ALS associated with a mutation in the superoxide ...
  85. [85]
    https://pubmed.ncbi.nlm.nih.gov/38705104/