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Chapter 13: The Spinal Cord, Spinal Nerves, and Spinal Reflexes

Chapter 13: The Spinal Cord, Spinal Nerves, and Spinal Reflexes. General Organization - Nervous System. Highly organized, very efficient . Spinal Reflexes. Rapid, automatic nerve responses triggered by specific stimuli Controlled by spinal cord alone; not the brain . Figure 13–1.

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Chapter 13: The Spinal Cord, Spinal Nerves, and Spinal Reflexes

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  1. Chapter 13: The Spinal Cord, Spinal Nerves, and Spinal Reflexes

  2. General Organization - Nervous System • Highly organized, very efficient Spinal Reflexes • Rapid, automatic nerve responses triggered by specific stimuli • Controlled by spinal cord alone; not the brain Figure 13–1

  3. Gross Anatomy of the Spinal Cord • Adult • About 18 inches (45 cm) long • 1/2 inch (14 mm) wide • Ends between vertebrae L1 and L2 • Bilateral Symmetry • Grooves divide the spinal cord into left and right • Posterior median sulcus: on posterior side • Anterior median fissure: deeper groove on anterior side Figure 13-2

  4. Enlargements of the Spinal Cord • Caused by: • amount of gray matter in segment • involvement with sensory and motor nerves of limbs • Cervical enlargement: • nerves of shoulders and upper limbs • Lumbar enlargement: • nerves of pelvis and lower limbs • The Distal End • Conus medullaris: thin, conical spinal cord below lumbar enlargement • Filum terminale: thin thread of fibrous tissue at end of conus medullaris, attaches to coccygeal ligament • Cauda equina: nerve roots extending below conus medullaris

  5. 31 Spinal Cord Segments • Based on vertebrae where spinal nerves originate • Positions of spinal segment and vertebrae change with age • Naming Spinal Nerves • Cervical nerves:are named for inferior vertebra • All other nerves: are named for superior vertebra • Roots • 2 branches of spinal nerves: • ventral root: contains axons of motor neurons • dorsal root: contains axons of sensory neurons • Dorsal root ganglia:contain cell bodies of sensory neurons

  6. The Spinal Nerve • Each side of spine: dorsal and ventral roots join and form a spinal nerve • Mixed Nerves • Carry both afferent (sensory) & efferent (motor) fibers • Spinal nerves are mixed nerves

  7. Spinal Meninges • Specialized membranes isolate spinal cord from surroundings • Spinal meninges: • protect spinal cord • carry blood supply • continuous with cranial meninges • Meningitis: • viral or bacterial infection of meninges • The 3 Meningeal Layers • Dura mater: outer layer of spinal cord • Arachnoid mater: middle meningeal layer • Pia mater: inner meningeal layer Figure 13–3

  8. The Spinal Dura Mater • Are tough and fibrous • Cranially: • fuses with periosteum of occipital bone • is continuous with cranial dura mater • Caudally: • tapers to dense cord of collagen fibers • joins filum terminale in coccygeal ligament The Epidural Space • Between spinal dura mater and walls of vertebral canal • Contains loose connective and adipose tissue • Anesthetic injection site

  9. The Arachnoid Mater • Middle meningeal layer • Arachnoid membrane: • simple squamous epithelia • covers arachnoid mater Inter-Layer Spaces • Subdural space: • between arachnoid mater and dura mater • Subarachnoid space: • between arachnoid mater and pia mater • contains collagen/elastin fiber network (arachnoid trabeculae) • filled with cerebrospinal fluid(CSF)

  10. Cerebrospinal Fluid(CSF) • Is found in subarachnoid space • Carries dissolved gases, nutrients, and wastes • Spinal tap: • withdraws CSF • The Pia Mater • Is the innermost meningeal layer • Is a mesh of collagen and elastic fibers • Is bound to underlying neural tissue

  11. Structures of the Spinal Cord • Paired denticulate ligaments: • extend from pia mater to dura mater • stabilize side-to-side movement • Blood vessels: • along surface of spinal pia mater • within subarachnoid space

  12. White Matter Sectional Anatomy of the Spinal Cord • Is superficial • Contains myelinated and unmyelinated axons Gray Matter • Surrounds central canal of spinal cord • Contains neuron cell bodies, neuroglia, unmyelinated axons • Has projections (gray horns) Figure 13–5a

  13. Posterior gray horns:contain somatic and visceral sensory nuclei • Anterior gray horns: contain somatic motor nuclei • Lateral gray horns: are in thoracic and lumbar segments and contain visceral motor nuclei

  14. Organization of White Matter • 3 columns(funiculi) on each side of spinal cord: • posterior white columns • Lie between posterior gray horns and posterior median sulcus • anterior white columns • Lie between anterior gray horns and anterior median fissure • Area where axons cross from 1 side of spinal cord to the other • lateral white columns • Located on each side of spinal cord • Between anterior and posterior columns

  15. Nuclei • Nuclei: • functional groups of cell bodies • Sensory nuclei: • dorsal (posterior) • connect to peripheral receptors • Motor nuclei: • ventral (anterior) • connect to peripheral effectors Control and Location • Sensory or motor nucleus location within the gray matter determines which body part it controls

  16. Tracts • Tracts or fasciculi: • in white columns • bundles of axons • relay same information in same direction • Ascending tracts: • carry information to brain • Descending tracts: • carry motor commands to spinal cord

  17. Spinal Nerves • Every spinal cord segment: • is connected to a pair of spinal nerves • Every spinal nerve: • is surrounded by 3 connective tissue layers • that support structures and contain blood vessels 3 Connective Tissue Layers • Epineurium: outer layer, dense network of collagen fibers • Perineurium: middle layer, divides nerve into fascicles (axon bundles) • Endoneurium:inner layer, surrounds individual axons Figure 13–6

  18. Peripheral Distribution of Spinal Nerves • Motor • Spinal nerves: • form lateral to intervertebral foramen • where dorsal and ventral roots unite • then branch and form pathways to destination Figure 13–7a

  19. Sympathetic Nerves • Are postganglionic fibers • Innervate smooth muscles, glands, and organs • The first branch - from the spinal nerve: • carries visceral motor fibers • to sympathetic ganglion of autonomic nervous system

  20. White Ramus Gray Ramus • Preganglionic branch • Myelinated axons • Unmyelinated nerves • Return from sympathetic ganglion • Rejoin spinal nerve Rami Communicantes • Also called communicating branches • Formed by gray ramus and white ramus together

  21. Dorsal and Ventral Rami • Dorsal ramus: • contains somatic and visceral motor fibers • innervates the back • Ventral ramus: • larger branch • innervates ventrolateral structures and limbs

  22. Peripheral Distribution of Spinal Nerves • Sensory Nerves • In addition to motor impulses: dorsal, ventral, and white rami also carry sensory information • Sensory fibers Figure 13–7b

  23. Nerve Plexuses • Complex, interwoven networks of nerve fibers • Formed from blended fibers of ventral rami of adjacent spinal nerves • Control skeletal muscles of the neck and limbs The 4 Major Plexuses of Ventral Rami Cervical plexus Brachial plexus Lumbar plexus Sacral plexus

  24. The Cervical Plexus • Includes ventral rami of spinal nerves C1–C5 • Innervates neck, thoracic cavity, diaphragmatic muscles • Major nerve: phrenic nerve (controls diaphragm) Figure 13–10

  25. The Brachial Plexus • Trunks and Cords of Brachial Plexus Nerves • that form brachial plexus originate from: • superior, middle, and inferior trunks • large bundles of axons from several spinal nerves • lateral, medial, and posterior cords • smaller branches that originate at trunks • Includes ventral rami of spinal nerves C5–T1 • Innervates pectoral girdle and upper limbs • Major Nerves of Brachial Plexus • -Musculocutaneous nerve (lateral cord) • Median nerve (lateral and medial cords) • Ulnar nerve (medial cord) • Axillary nerve (posterior cord) • Radial nerve (posterior cord)

  26. Summary: Brachial Plexus Table 13–2 (1 of 2)

  27. The Lumbar and Sacral Plexuses • Innervate pelvic girdle and lower limbs • The Lumbar Plexus • Includes ventral rami of spinal nerves T12–L4 • Major nerves: • genitofemoral nerve • lateral femoral cutaneous nerve • femoral nerve Figure 13–12a, b

  28. The Lumbar and Sacral Plexuses • Innervate pelvic girdle and lower limbs • The Sacral Plexus • Includes ventral rami of spinal nerves L4–S4 • Major nerves: • pudendal nerve • sciatic nerve • Branches of sciatic nerve: • fibular nerve • tibial nerve Figure 13–12a, b

  29. Lumbar and Sacral Plexuses Table 13-3 (1 of 2)

  30. Reflexes • Automatic responses coordinated within spinal cord • Through interconnected sensory, motor, and interneurons • Produce simple and complex reflexes

  31. Functional Organization of Neurons • Sensory neurons: • about 10 million • deliver information to CNS • Motor neurons: • about 1/2 million • deliver commands to peripheral effectors • Interneurons: • about 20 billion • interpret, plan, and coordinate signals in and out

  32. Neuronal Pools • Functional groups of interconnected neurons (interneurons) • Each with limited input sources and output destinations • May stimulate or depress parts of brain or spinal cord 5 Patterns of Neural Circuits in Neuronal Pools • Divergence: • spreads stimulation to many neurons or neuronal pools in CNS

  33. Convergence: • brings input from many sources to single neuron • Serial processing: • moves information in single line Figure 13–13b

  34. Parallel processing: • moves same information along several paths simultaneously • Reverberation: • positive feedback mechanism • functions until inhibited Figure 13–13d

  35. Neural Reflexes The Reflex Arc • Rapid, automatic responses to specific stimuli • Basic building blocks of neural function • 1 neural reflex produces 1 motor response • The wiring of a single reflex • Beginning at receptor • Ending at peripheral effector • Generally opposes original stimulus (negative feedback)

  36. 5 Steps in a Neural Reflex • Step 1: Arrival of stimulus, activation of receptor • physical or chemical changes • Step 2: Activation of sensory neuron • graded depolarization • Step 3: Information processing by postsynaptic cell • triggered by neurotransmitters • Step 4: Activation of motor neuron • action potential • Step 5: Response of peripheral effector • triggered by neurotransmitters Figure 13–14

  37. 4 Classifications of Reflexes • By early development • How reflex was developed: • innate reflexes:basic neural reflexes, formed before birth • acquired reflexes: rapid, automatic, learned motor patterns • By type of motor response-Nature of resulting motor response: • somatic reflexes: • involuntary control of nervous system • superficial reflexes of skin, mucous membranes • stretch reflexes (deep tendon reflexes) e.g., patellar reflex • visceral reflexes (autonomic reflexes): • control systems other than muscular syste

  38. By complexity of neural circuit • Complexity of neural circuit: • monosynaptic reflex: • sensory neuron synapses directly onto motor neuron • polysynaptic reflex: • at least 1 interneuron between sensory neuron and motor neuron • By site of information processing • Site of information processing: • spinal reflexes: • occurs in spinal cord • cranial reflexes: • occurs in brain

  39. Spinal Reflexes • Range in increasing order of complexity: • monosynaptic reflexes • simplest of all reflexes • Just one synapse • The fastest of all reflexes • Example – stretch-knee-jerk reflex • polysynaptic reflexes • more common type of reflex • Most have a single interneuron between the sensory and motor neuron • Example – withdrawal reflexes

  40. 1. Monosynaptic Reflexes – patellar reflex

  41. 2. Polysynaptic Reflexes • More complicated than monosynaptic reflexes • Interneurons control more than 1 muscle group • Withdrawal or flexor reflex is an example • Move body part away from stimulus (pain or pressure): e.g., flexor reflex:pulls hand away from hot stove • Strength and extent of response: • depends on intensity and location of stimulus

  42. The Tendon Reflex • Prevents skeletal muscles from: • developing too much tension • tearing or breaking tendons • tendon reflex is less sensitive than the stretch reflex, it can override the stretch reflex when tension is great, making you drop a very heavy weight, for example.

  43. Reflex Arcs • When a reflex arc consists of only two neurons (one sensory neuron and one motor neuron), it is defined as monosynaptic. • In the case of peripheral muscle reflexes (patellar reflex, achilles reflex), brief stimulation to the muscle spindle results in contraction of the agonist or effector muscle. • polysynaptic reflex pathways, one or more interneurons connect afferent (sensory) and efferent (motor) signals. • All but the most simple reflexes are polysynaptic, allowing processing or inhibition of polysynaptic reflexes within the spinal cord.

  44. Crossed Extensor Reflexes • Occur simultaneously, coordinated with flexor reflex • e.g.,flexor reflex causes leg to pull up: • crossed extensor reflex straightens other leg • to receive body weight • maintained by reverberating circuits

  45. The Babinski Reflexes • Normal in infants • May indicate CNS damage in adults Figure 13–19

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