Spinal Cord Motor Functions (PDF)

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Dr. Taloma

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spinal cord motor functions physiology human anatomy

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This document is a detailed study guide on spinal cord motor functions and reflexes. It covers spinal cord structure, nerves, types of neurons, and neuronal circuits involved in muscle control. It also explains the important roles of muscle spindles and Golgi tendon organs in sensory feedback. The material is well-suited for an undergraduate physiology course.

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# Spinal Cord Motor Functions: The Cord Reflexes ## PHYSIOLOGY - CNS - Brain and Spinal Cord - CNS intimately connected with the peripheral nervous system - PNS - Sensory and Motor components - Spinal Nerves ### Spinal Cord - Extends from the Foramen Magnum of the Skull, starts from C1 to bet...

# Spinal Cord Motor Functions: The Cord Reflexes ## PHYSIOLOGY - CNS - Brain and Spinal Cord - CNS intimately connected with the peripheral nervous system - PNS - Sensory and Motor components - Spinal Nerves ### Spinal Cord - Extends from the Foramen Magnum of the Skull, starts from C1 to between L1 and L2 - Adults: C1 - L1, ends: L3 ### Spinal Cord Structure | Region | Anatomy | |---|---| | Cervical Region | Cervical enlargement C5-T1 of the spinal cord, more gray matter, supply upper limb skeletal muscles | | Thoracic Region | No enlargement | | Lumbar Region | Lumbar enlargement L2 to S3 of the spinal cord, more gray matter, supply lower limb of skeletal muscles| | Sacral Region | No enlargement | | Coccygeal Region | No enlargement | | Conus Medullaris | Tapered terminal end of the spinal cord, between L1-L2 | | Cauda Equina | Bundle of nerve roots from L2 to Co1, looks like horse tail | ### Spinal Cord Cross-Sectional Anatomy: - White matter - Myelinated axons - As we go down from cervical region to coccygeal region - White matter decreases - Ascending Tracts carrying Sensory Information - Becomes thicker as it ascends - Descending Tracts carrying Motor Information - Thicker at the top - Gray Matter - Contains cell bodies (soma), dendrites, unmyelinated axons - As we go down from cervical region to coccygeal region - Gray matter increases - Higher Muscle Mass in the lower extremities - Needs more motor supply ### Spinal Cord: White and Gray Matter Anatomy White Matter | Anatomy | Overall Function | |---|---| | Anterior (Ventral) Funiculus | Contains bundle of myelinated axons called tract, axons transmits signals between CNS and periphery | | Lateral Funiculus | | | Posterior (Dorsal) Funiculus | | | Anterior Median Fissure | | | Posterior Median Sulcus | | Gray Matter | Anatomy | Overall Function | |---|---| | Posterior Dorsal Horn | Contains cell bodies and dendrites of neurons | | Lateral Hom | | | Anterior (Ventral) Hom | | ### Spinal Cord Nerves - Spinal Nerves Coming out of the Spinal Cord are part of Peripheral Nervous System - There are 31 pairs of spinal nerves: - Cervical: 8 pairs - Thoracic: 12 pairs - Lumbar: 5 pairs - Sacral: 5 pairs - Coccygeal: 1 pair ### Spinal Cord Nerves: Anatomy - There are 7 Cervical Vertebrae, but 8 pairs of spinal nerves come out of the cervical segment - Nerves C1-C7 exit above the corresponding vertebrae - C8 spinal nerve exists below the C7 and above T1 - All other nerves exit below the corresponding vertebrae. ## Spinal Cord Control of Muscle Function - Integration of Information: Occurs at all levels of the nervous system to produce motor responses. - Spinal Cord - Controls simple muscle reflexes. - Brain Stem - Manages more complex responses. - Cerebrum - Regulates the most advanced motor skills. ## Types of Neurons in the Spinal Cord ### Anterior Motor Neurons - Located in the anterior horns controlling skeletal muscles - Alpha Motor Neurons - Give rise to large Aa fibers (14 micrometers) - Innervate extrafusal skeletal muscle fibers forming the motor unit. - Gamma Motor Neurons - Transmit impulses through Ay fibers (5 micrometers) - Control intrafusal fibers within the muscle spindle, regulating muscle tone. ### Interneurons - Present in all areas of gray matter. - More numerous than motor neurons. - Involved in integrative functions like reflexes through various circuits (e.g., diverging, converging, repetitive discharge). - Excitability: Can fire rapidly (up to 1500 times/second). - Interconnected with motor neurons for reflex actions. ## Neuronal Circuits - **Interneurons:** Play a critical role in processing incoming signals before relaying them to motor neurons. - **Renshaw Cells:** Provide lateral inhibition to adjacent motor neurons. - Inhibit nearby neurons to sharpen motor signals, much like sensory lateral inhibition sharpens sensory inputs. ## Multisegmental Connections - **Propriospinal Fibers:** Facilitate connections between different segments of the spinal cord. - These fibers allow multi segmental reflexes, coordinating simultaneous limb movements. - Sensory fibers bifurcate upon entry into the spinal cord, spreading signals to multiple segments, enabling coordinated motor actions. ## Muscle Sensory Receptors and Their Roles in Muscle Control - **Key Sensory Receptors:** - **Muscle Spindles:** Located in the muscle belly, providing information about muscle length and rate of change of length. - **Golgi Tendon Organs:** Found in tendons, transmitting data on tendon tension and rate of change of tension. - **Sensory Feedback:** - Operates mostly at a subconscious level. - Provides essential input to the spinal cord, cerebellum, and cerebral cortex for precise muscle control. ### Muscle Spindle Function - **Structure:** - Contains 3-12 intrafusal fibers surrounded by larger extrafusal muscle fibers. - Central region acts as a sensory receptor (non-contractile), while end portions contract through gamma motor nerve fibers. - **Sensory Innervation:** - **Primary Afferent Ending:** (Type la fibers) - Encircles intrafusal fibers. - Transmits signals at 70-120 m/s, among the fastest in the body. - **Secondary Afferent Ending:** (Type II fibers) - Located beside primary endings. - Transmits sensory signals at 8 micrometers diameter, often spreading like branches. - **Intrafusal Fiber Types:** - **Nuclear Bag Fibers:** - Several nuclei form a "bag" in the central receptor area. - Primary endings respond to both nuclear bag and nuclear chain fibers. - **Nuclear Chain Fibers:** - Smaller and thinner, with aligned nuclei. - Secondary endings mainly respond to these fibers. - **Responses of Muscle Spindle:** - **Static Response:** - Slow stretch of the spindle increases impulse transmission from both primary and secondary endings. - Continues signaling for several minutes. - **Dynamic Response:** - Sudden stretch triggers strong signals from the primary endings only, corresponding to rapid changes in length. - Important for detecting quick changes in muscle position. - **Control of Responses via Gamma Motor Nerves:** - **Gamma-Dynamic (y-d) Nerves:** Enhance dynamic response by exciting nuclear bag fibers. - **Gamma-Static (y-s) Nerves:** Enhance static response by exciting nuclear chain fibers. ### Muscle Stretch Reflex - **Basic Circuit:** A monosynaptic pathway involving Type la fibers from muscle spindle to anterior motor neurons, resulting in reflex contraction. - **Types of Stretch Reflex:** - **Dynamic Stretch Reflex:** Reacts to sudden stretch, causing strong contraction to resist changes in muscle length. - **Static Stretch Reflex:** Maintains steady muscle contraction after the initial response, keeping muscle length stable. - **Damping Function of Stretch Reflex** - **Prevents Jerkiness:** Both dynamic and static stretch reflexes smooth out contractions, ensuring fluid movements. - **Absence of this damping mechanism:** Leads to jerky, unsmooth muscle movements, as demonstrated experimentally. - **Role of the Muscle Spindle in Voluntary Motor Activity:** - **Gamma Efferent System:** - 31% of motor fibers to muscles are type A gamma efferent fibers. - **Coactivation:** Alpha and gamma motor neurons are activated simultaneously, causing both extrafusal and intrafusal fibers to contract together. - **Functions of Coactivation:** - Prevents changes in the length of the muscle spindle receptor during contraction. - Maintains the damping function of the spindle for smooth muscle control. - **Control of the Gamma Motor System:** - **Excitatory Inputs to the gamma system come from:** - Bulboreticular facilitatory region of the brain stem. - Cerebellum. - Basal ganglia. - Cerebral cortex. - **Importance in Antigravity Muscles:** Gamma system helps stabilize posture during walking and running by damping movements through muscle spindles. - **Stabilization of Body Position During Motor Activity:** - **Muscle Spindle System:** - Helps stabilize joint position during intense or delicate motor actions. - Activation of muscle spindles on both sides of a joint increases reflexive muscle contraction, stabilizing the joint. - **Application:** Stabilizes body during intricate motor tasks, such as fine movements of the fingers during detailed voluntary actions. - **Clinical Applications of the Stretch Reflex:** - **Purpose:** Used to assess the background muscle tone and level of brain excitation sent to the spinal cord. - **Knee Jerk Test:** - Striking the patellar tendon elicits a dynamic stretch reflex, causing the quadriceps muscle to contract and the leg to jerk forward. - Muscle jerks can be elicited from various muscles by striking their tendons or bellies. - **Assessment of Spinal Cord Sensitivity:** - **Exaggerated Jerks:** Indicate heightened facilitation from the brain. - **Weakened or Absent Jerks:** Suggest reduced facilitation or damage to the motor areas. - **Clonus: Oscillation of Muscle Jerks:** - **Definition:** Repeated rhythmic contractions of muscles due to oscillation of the stretch reflex. - **Example:** Ankle clonus occurs when stretching the gastrocnemius muscle triggers a stretch reflex, lifting the body, followed by muscle relaxation, leading to repeated oscillations. - **Clinical Significance:** Clonus indicates a highly sensitized stretch reflex, often due to brain lesions or conditions like decerebration. ### Golgi Tendon Reflex: Key Functions - **Golgi Tendon Organ:** - Sensory receptor located in muscle tendons, connected to 10-15 muscle fibers. - Detects muscle tension, unlike muscle spindles which detect muscle length. - **Responses:** - **Dynamic Response:** Reacts to sudden increases in muscle tension. - **Static Response:** Provides steady-state firing proportional to ongoing muscle tension. - **Transmission of Impulses:** - **Type Ib nerve fibers:** Conduct signals rapidly to the spinal cord, cerebellum, and cerebral cortex. - **Inhibitory Reflex:** - Local inhibitory interneurons in the spinal cord inhibit anterior motor neurons. - Prevents excessive muscle tension, protecting muscle from damage. - **Protective Mechanism: Lengthening Reaction** - **Function:** Prevents muscle tearing or tendon avulsion. - When muscle tension becomes extreme, the reflex causes instantaneous muscle relaxation. - A key negative feedback mechanism. - **Equalization of Contractile Force** - **Role:** Ensures even distribution of muscle load. - Fibers with excess tension are inhibited, while fibers with less tension are stimulated. - Prevents overloading and damage to specific areas of the muscle. - **Higher-Level Motor Control:** - **Instantaneous Feedback:** - Dorsal spinocerebellar tracts transmit rapid signals (up to 120 m/sec) to the cerebellum and brain stem. - Critical for feedback control in motor areas of the cerebral cortex. - **Clinical Relevance:** Provides feedback for fine-tuning motor signals originating from higher brain centers (cerebellum, brainstem, cerebral cortex). ## Flexor Reflex and Withdrawal Reflexes - **Flexor Reflex:** - Triggered by cutaneous sensory stimuli (e.g., pain, pinprick). - Causes contraction of flexor muscles to withdraw the limb from a stimulus (also called nociceptive reflex). - **Neuronal Mechanism:** - Pathway involves interneurons before reaching motor neurons. - Includes diverging circuits (activating necessary muscles), reciprocal inhibition circuits (inhibiting antagonist muscles), and afterdischarge (sustained reflex response). - **Crossed Extensor Reflex:** - **Delayed Reflex:** (0.2-0.5 seconds after flexor reflex) - Opposite limb extends to stabilize the body or push away from the painful stimulus. - Involves signals crossing the spinal cord to activate extensor muscles on the opposite side. - **Afterdischarge:** Prolonged reflex keeps the body away from the painful stimulus. - **Reciprocal Inhibition and Innervation:** - **Reciprocal Inhibition:** Excitation of one muscle group inhibits the antagonist muscles. - Common in flexor and extensor muscle reflexes to prevent co-contraction. - **Reciprocal Innervation:** Seen in bilateral muscle reflexes, such as flexor reflexes in opposite limbs. - Prevents simultaneous contraction of opposing muscle groups on both sides of the body. ## Reflexes of Posture and Locomotion - **Positive Supportive Reaction:** - Pressure on the footpad causes the limb to extend. - Helps maintain body weight and posture, especially in animals with spinal cord injury. - **Cord Righting Reflex:** - An animal with a spinal cord injury makes movements to stand up from a lying position. - Some complex postural reflexes are integrated in the spinal cord. - **Stepping and Walking Movements:** - **Rhythmical Stepping Movements:** Alternating flexion and extension of a limb occurs rhythmically, even after sensory nerves are cut. - Likely due to reciprocal inhibition circuits in the spinal cord. - **Stumble Reflex:** If a foot encounters an obstruction, the spinal cord adjusts by lifting the foot higher to clear the object. - **Reciprocal Stepping of Opposite Limbs:** In intact lumbar spinal cords, stepping in one limb causes backward movement of the opposite limb through reciprocal innervation. - **Diagonal Stepping (Mark Time Reflex):** In animals with spinal cord transection, stepping occurs diagonally between forelimbs and hindlimbs due to reciprocal innervation. - **Scratch Reflex:** - **Trigger:** Initiated by itch or tickle sensations. - **Functions:** - **Position Sense:** Locates the exact point of irritation. - **To-and-Fro Movement:** Involves reciprocal innervation circuits similar to stepping movements. ## Spinal Cord Reflexes Causing Muscle Spasm - **Muscle Spasm from Pain:** - **Broken Bone:** Pain from bone injury causes tonic muscle contraction around the fracture. Pain relief through anesthesia resolves the spasm. - **Peritonitis:** Abdominal muscle spasm occurs due to irritation of the peritoneum. Deep anesthesia is needed during surgeries to prevent excessive muscle contraction. - **Muscle Cramps:** - **Causes:** Cold, lack of blood flow, or over exercise. - **Mechanism:** Positive feedback loop - initial irritation triggers contraction, which stimulates more sensory signals, leading to full-blown muscle cramps. ## Autonomic Reflexes in the Spinal Cord - **Types of Reflexes:** - Vascular tone changes due to local skin heat. - Sweating induced by localized heat. - Intestino Intestinal reflexes control gut motor functions. - Peritoneo Intestinal reflexes inhibit gut motility in response to peritoneal irritation. - Evacuation reflexes for bladder and colon emptying. - **Mass Reflex:** - Triggered by strong pain stimulus or visceral distention (e.g., bladder). - **Effects:** - Flexor muscle spasm throughout the body. - Bladder and colon evacuation. - Elevated blood pressure (over 200 mmHg). - Profuse sweating. - Similar mechanism to epileptic seizures, involving reverberating circuits in the spinal cord. ## Spinal Shock and Recovery - **Spinal Shock:** - Occurs after spinal cord transection in the upper neck, causing immediate depression of all cord functions and reflexes. - **Cause:** Loss of tonic excitation from higher centers, such as reticulospinal, vestibulospinal, and corticospinal tracts. - **Recovery:** - Cord neurons regain excitability after hours to weeks. - Sympathetic nervous system and skeletal muscle reflexes return gradually (stretch reflexes return first). - Bladder and colon reflexes are suppressed initially but usually recover over weeks. ## Transections at the Spinal Cord - **Paraplegia:** Loss of voluntary movements below level of the lesion. - Loss of conscious sensation below the level of the lesion. - **Spinal Shock:** - Limbs flaccid, reflexes absent immediately after transection. Partial recovery may occur after sometime (after several hours to a few weeks) - C7 transection: HR and BP decreases - C3 transection: breathing stops - C1 transection: death

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