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

2. An Introduction to the Spinal Cord, Spinal Nerves, and Spinal Reflexes
Rapid, automatic nerve responses triggered by specific stimuli
Controlled by spinal cord alone, not the brain

3. Figure 13-1 An Overview of Chapters 13 and 14
CHAPTER 14: The Brain
Sensory input over cranial nerves
Motor output over cranial nerves
Effectors
Reflex centers in brain
Sensory receptors
Muscles
CHAPTER 13: The Spinal Cord
Glands
Sensory input over spinal nerves
Motor output over spinal nerves
Reflex centers in spinal cord
Sensory receptors
Adipose tissue 3

4. 13-2 Spinal Cord Gross Anatomy of the Spinal Cord
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

5. 13-2 Spinal Cord 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

6. 13-2 Spinal Cord Gross Anatomy of the Spinal Cord 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

7. 13-2 Spinal Cord 31 Spinal Cord Segments Cervical nerves
Are named for inferior vertebra
All other nerves
Are named for superior vertebra

8. Figure 13-2 Gross Anatomy of the Adult Spinal Cord
Posterior median sulcus
Dorsal root
Dorsal root ganglion
White matter
Central canal
Gray matter C1 C2
Cervical spinal nerves C3 C4 C5
Spinal nerve
Ventral root C6
Cervical enlargement
Anterior median fissure C7 C3 C8
Inferior views of cross sections through representative segments of the spinal cord, showing the arrangement of gray matter and white matter.
The superficial anatomy and orientation of the adult spinal cord. The numbers to the left identify the spinal nerves and indicate where the nerve roots leave the vertebral canal. The spinal cord extends from the brain only to the level of vertebrae L1L2; the spinal segments found at representative locations are indicated in the cross sections. 8

9. Figure 13-2 Gross Anatomy of the Adult Spinal Cord
Thoracic spinal nerves T8
Posterior median sulcus T9
T10
Lumbar enlargement T3
T11
T12
Conus medullaris 9

10. Figure 13-2 Gross Anatomy of the Adult Spinal Cord
Conus medullaris L1 L2
Inferior tip of spinal cord
Lumbar spinal nerves L3 L4
Cauda equina L5 L1 10

11. Figure 13-2 Gross Anatomy of the Adult Spinal Cord
Inferior tip of spinal cord
Cauda equina S1
Sacral spinal nerves S2 S3 S4 S5
Coccygeal nerve (Co1)
Filum terminale (in coccygeal ligament) L2 11

12. 13-2 Spinal Cord The Spinal Nerve Each side of spine Mixed Nerves
Dorsal and ventral roots join
To form a spinal nerve
Mixed Nerves
Carry both afferent (sensory) and efferent (motor) fibers

13. Figure 13-3a The Spinal Cord and Spinal Meninges
Gray matter
White matter
Dorsal root ganglion
Ventral root
Spinal nerve
Dorsal root
Meninges
Pia mater
Arachnoid mater
Dura mater
A posterior view of the spinal cord, showing the meningeal layers, superficial landmarks, and distribution of gray matter and white matter 13

14. Figure 13-3b The Spinal Cord and Spinal Meninges
Dura mater
ANTERIOR
Arachnoid mater
Pia mater
Subarachnoid space
Vertebral body
Autonomic (sympathetic) ganglion
Rami communicantes
Ventral root of spinal nerve
Ventral ramus
Dorsal ramus
Spinal cord
Adipose tissue in epidural space
Denticulate ligament
Dorsal root ganglion
A sectional view through the spinal cord and meninges, showing the peripheral distribution of spinal nerves
POSTERIOR 14

15. 13-2 Spinal Cord The Spinal Meninges
Specialized membranes isolate spinal cord from surroundings
Functions of the spinal meninges include:
Protecting spinal cord
Carrying blood supply
Continuous with cranial meninges
Meningitis
Viral or bacterial infection of meninges

16. 13-2 Spinal Cord The Three Meningeal Layers Dura mater Arachnoid mater
Outer layer of spinal cord
Arachnoid mater
Middle meningeal layer
Pia mater
Inner meningeal layer

17. 13-2 Spinal Cord The Dura Mater
The Epidural Space
Between spinal dura mater and walls of vertebral canal
The Interlayer Spaces of Arachnoid Mater
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)

18. 13-2 Spinal Cord The Pia Mater Cerebrospinal Fluid (CSF)
Carries dissolved gases, nutrients, and wastes
Lumbar puncture or 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

19. 13-2 Spinal Cord 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

20. Figure 13-4 The Spinal Cord and Associated Structures
Anterior median fissure
Pia mater
Denticulate ligaments
Dorsal root
Ventral root, formed by several “rootlets” from one cervical segment
Arachnoid mater (reflected)
Dura mater (reflected)
Spinal blood vessel 20

21. 13-3 Gray Matter and White Matter
Sectional Anatomy of the Spinal Cord
White matter
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)

22. 13-3 Gray Matter and White Matter
Organization of Gray Matter
The gray horns
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; contain visceral motor nuclei
Gray commissures
Axons that cross from one side of cord to the other before reaching gray matter

23. 13-3 Gray Matter and White Matter
Organization of Gray Matter
The cell bodies of neurons form functional groups called nuclei
Sensory nuclei
Dorsal (posterior)
Connect to peripheral receptors
Motor nuclei
Ventral (anterior)
Connect to peripheral effectors

24. 13-3 Gray Matter and White Matter
Organization of White Matter
Posterior white columns lie between posterior gray horns and posterior median sulcus
Anterior white columns lie between anterior gray horns and anterior median fissure
Anterior white commissure area where axons cross from one side of spinal cord to the other
Lateral white columns located on each side of spinal cord between anterior and posterior columns

25. 13-3 Gray Matter and White Matter
Organization of White Matter
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

26. Figure 13-5a The Sectional Organization of the Spinal Cord
Posterior white column
Posterior gray horn
Lateral white column
Lateral gray horn
Dorsal root ganglion
Anterior gray horn
Anterior white column
The left half of this sectional view shows important anatomical landmarks, including the three columns of white matter. The right half indicates the functional organization of the nuclei in the anterior, lateral, and posterior gray horns. 26

27. Figure 13-5a The Sectional Organization of the Spinal Cord
Posterior median sulcus
Functional Organization of Gray Matter
Posterior gray commissure
The cell bodies of neurons in the gray matter of the spinal cord are organized into functional groups called nuclei.
Somatic
Sensory nuclei
Visceral
Visceral
Motor nuclei
Somatic
Ventral root
Anterior gray commissure
Anterior white commissure
Anterior median fissure
The left half of this sectional view shows important anatomical landmarks, including the three columns of white matter. The right half indicates the functional organization of the nuclei in the anterior, lateral, and posterior gray horns. 27

28. 13-3 Gray Matter and White Matter
Spinal Cord Summary
Spinal cord has a narrow central canal
Surrounded by gray matter - Containing sensory and motor nuclei
Sensory nuclei are dorsal
Motor nuclei are ventral

29. 13-4 Spinal Nerves and Plexuses
Anatomy of Spinal Nerves
Every spinal cord segment
Is connected to a pair of spinal nerves
Every spinal nerve
Is surrounded by three connective tissue layers
That support structures and contain blood vessels

30. 13-4 Spinal Nerves and Plexuses
Three Connective Tissue Layers of Spinal Nerves
Epineurium
Outer layer
Dense network of collagen fibers
Perineurium
Middle layer
Divides nerve into fascicles (axon bundles)
Endoneurium
Inner layer
Surrounds individual axons

31. Figure 13-6 A Peripheral Nerve
Blood vessels
Connective Tissue Layers
Epineurium covering spinal nerve
Perineurium (around one fascicle)
Endoneurium
Myelinated axon
Fascicle
Schwann cell 31

32. 13-4 Spinal Nerves and Plexuses
Peripheral Nerves
Interconnecting branches of spinal nerves
Surrounded by connective tissue sheaths

33. 13-4 Spinal Nerves and Plexuses
Peripheral Distribution of Spinal Nerves
Spinal nerves
Form lateral to intervertebral foramen
Where dorsal and ventral roots unite
Then branch and form pathways to destination

34. 13-4 Spinal Nerves and Plexuses
Peripheral Distribution of Spinal Nerves
Motor nerves
The first branch
White ramus
Carries visceral motor fibers to sympathetic ganglion of autonomic nervous system
Gray ramus
Unmyelinated nerves
Return from sympathetic ganglion to rejoin spinal nerve

35. 13-4 Spinal Nerves and Plexuses
Peripheral Distribution of Spinal Nerves
Motor nerves
Dorsal and ventral rami
Dorsal ramus
Contains somatic and visceral motor fibers
Innervates the back
Ventral ramus
Larger branch
Innervates ventrolateral structures and limbs

36. Figure 13-7 Peripheral Distribution of Spinal Nerves
To skeletal muscles of back
Postganglionic fibers to smooth muscles, glands, etc., of back
The spinal nerve forms just lateral to the intervertebral foramen, where the dorsal and ventral roots unite.
The dorsal ramus contains somatic motor and visceral motor fibers that innervate the skin and skeletal muscles of the back.
Dorsal root ganglion
Dorsal root
The axons in the relatively large ventral ramus supply the ventrolateral body surface, structures in the body wall, and the limbs.
The ventral root of each spinal nerve contains the axons of somatic motor and visceral motor neurons.
To skeletal muscles of body wall, limbs
Visceral motor nuclei
Somatic motor nuclei
Rami communicantes
Postganglionic fibers to smooth muscles, glands, etc., of body wall, limbs 
Somatic motor commands
Sympathetic ganglion 
Visceral motor commands
The white ramus is the first branch from the spinal nerve and carries visceral motor fibers to a nearby sympathetic ganglion. Because these preganglionic axons are myelinated, this branch has a light color and is therefore known as the white ramus.
Postganglionic fibers to smooth muscles, glands, visceral organs in thoracic cavity
A sympathetic nerve contains preganglionic and postganglionic fibers innervating structures in the thoracic cavity.
The gray ramus contains postganglionic fibers that innervate glands and smooth muscles in the body wall or limbs. These fibers are unmyelinated and have a dark gray color.
Preganglionic fibers to sympathetic ganglia innervating abdominopelvic viscera 36

37. 13-4 Spinal Nerves and Plexuses
Peripheral Distribution of Spinal Nerves
Sensory nerves
In addition to motor impulses
Dorsal, ventral, and white rami also carry sensory information
Dermatomes
Bilateral region of skin
Monitored by specific pair of spinal nerves

38. Figure 13-7 Peripheral Distribution of Spinal Nerves
From interoceptors of back
From exteroceptors, proprioceptors of back
The dorsal root of each spinal nerve carries sensory information to the spinal cord.
The dorsal ramus carries sensory information from the skin and skeletal muscles of the back.
Somatic sensory nuclei
The ventral ramus carries sensory information from the ventrolateral body surface, structures in the body wall, and the limbs.
Dorsal root ganglion
From exteroceptors, proprioceptors of body wall, limbs
From interoceptors of body wall, limbs
Rami communicantes
Visceral sensory nuclei
Ventral root 
Somatic sensations 
Visceral sensations
The sympathetic nerve carries sensory information from the visceral organs.
From interoceptors of visceral organs 38

39. Figure 13-8 Dermatomes 39 ANTERIOR POSTERIOR C2C3 N V C2C3 C2 C3 C3L1 C6
T10 L2
T11 L4 L3 T1 C6
T12 L5 C7 L1 S S L2 4 S2 3 C8 T1 L3 C8 L1 C7 S5 S1 L5 L4 L2 S2 L5 L3 S1 L4
ANTERIOR
POSTERIOR 39

40. 13-4 Spinal Nerves and Plexuses
Peripheral Neuropathy
Regional loss of sensory or motor function
Due to trauma or compression

41. Figure Shingles 41

42. 13-4 Spinal Nerves and Plexuses
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

43. 13-4 Spinal Nerves and Plexuses
The Four Major Plexuses of Ventral Rami
Cervical plexus
Brachial plexus
Lumbar plexus
Sacral plexus

44. Figure 13-10 Peripheral Nerves and Nerve PlexusesC1
Lesser occipital nerve C2
Great auricular nerve
Cervical plexus C3
Transverse cervical nerve C4 C5
Supraclavicular nerve C6 C7
Phrenic nerve
Brachial plexus C8 T1 T2 T3
Axillary nerve T4 T5 T6 T7
Musculocutaneous nerve T8 T9
Thoracic nerves
T10
T11 44

45. Figure 13-10 Peripheral Nerves and Nerve Plexuses
T12 L1
Radial nerve
Lumbar plexus L2
Ulnar nerve L3
Median nerve L4 L5 S1
Iliohypogastric nerve
Sacral plexus S2 S3 S4
Ilioinguinal nerve S5
Co1
Lateral femoral cutaneous nerve
Genitofemoral nerve
Femoral nerve
Obturator nerve
Superior
Gluteal nerves
Inferior
Pudendal nerve
Saphenous nerve
Sciatic nerve 45

46. 13-4 Spinal Nerves and Plexuses
The Cervical Plexus
Includes ventral rami of spinal nerves C1–C5
Innervates neck, thoracic cavity, diaphragmatic muscles
Major nerve
Phrenic nerve (controls diaphragm)

47. Figure 13-11 The Cervical Plexus
Cranial Nerves
Accessory nerve (XI)
Hypoglossal nerve (XII)
Lesser occipital nerve
Nerve Roots of Cervical Plexus C1 C2 C3 C4 C5
Supraclavicular nerves
Clavicle 47

48. Figure 13-11 The Cervical Plexus
Great auricular nerve
Geniohyoid muscle
Transverse cervical nerve
Thyrohyoid muscle
Ansa cervicalis
Omohyoid muscle
Phrenic nerve
Sternohyoid muscle
Sternothyroid muscle 48

49. Table 13-1 The Cervical Plexus49

50. 13-4 Spinal Nerves and Plexuses
The Brachial Plexus
Includes ventral rami of spinal nerves C5–T1
Innervates pectoral girdle and upper limbs
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

51. 13-4 Spinal Nerves and Plexuses
The Brachial Plexus
Major nerves
Musculocutaneous nerve (lateral cord)
Median nerve (lateral and medial cords)
Ulnar nerve (medial cord)
Axillary nerve (posterior cord)
Radial nerve (posterior cord)

52. Figure 13-12a The Brachial Plexus
Spinal Nerves Forming Brachial Plexus
Trunks of Brachial Plexus
Dorsal scapular nerve C4
Suprascapular nerve C5
Superior C6
Middle C7
Inferior C8 T1
Musculocutaneous nerve
Median nerve
Ulnar nerve
Radial nerve
Lateral antebrachial cutaneous nerve
Superficial branch of radial nerve
Deep radial nerve
Ulnar nerve
Median nerve
Palmar digital nerves
Major nerves originating at the right brachial plexus, anterior view 52

53. Figure 13-12b The Brachial Plexus
Anterior
Posterior
Radial nerve
Ulnar nerve
Median nerve
Areas of the hands serviced by nerves of the right brachial plexus 53

54. Figure 13-12c The Brachial Plexus
Dorsal scapular nerve C5
SUPERIOR TRUNK C6
Suprascapular nerve
MIDDLE TRUNK
Lateral cord C7
Posterior cord
Lateral pectoral nerve C8
Medial pectoral nerve
Subscapular nerves T1
Axillary nerve
INFERIOR TRUNK
Medial cord
Musculocutaneous nerve
First rib
Long thoracic nerve
Medial antebrachial cutaneous nerve
KEY
Median nerve
Ulnar nerve 
Roots (ventral rami)
Posterior brachial cutaneous nerve
Radial nerve 
Trunks
Right brachial plexus, anterior view 
Divisions 
Cords 
Peripheral nerves 54

55. Table 13-2 The Brachial Plexus55

56. 13-4 Spinal Nerves and Plexuses
The Lumbar Plexus
Includes ventral rami of spinal nerves T12–L4
Major nerves
Genitofemoral nerve
Lateral femoral cutaneous nerve
Femoral nerve

57. 13-4 Spinal Nerves and Plexuses
The Sacral Plexus
Includes ventral rami of spinal nerves L4–S4
Major nerves
Pudendal nerve
Sciatic nerve
Two branches of the sciatic nerve
Fibular nerve
Tibial nerve

58. Figure 13-13a The Lumbar and Sacral Plexuses
Spinal Nerves Forming the Lumbar Plexus
T12
T12 nerve
Nerves of the Lumbar Plexus L1
L1 nerve L2
Iliohypogastric
L2 nerve
Ilioinguinal L3
L3 nerve
Genitofemoral L4
Lateral femoral cutaneous
L4 nerve L5
Femoral
Lumbosacral trunk
Obturator
Lumbar plexus, anterior view 58

59. Figure 13-13b The Lumbar and Sacral Plexuses
Spinal Nerves Forming the Sacral Plexus
Lumbosacral trunk
L4 nerve
L5 nerve
Nerves of the Sacral Plexus
S1 nerve
Superior gluteal
S2 nerve
Inferior gluteal
S3 nerve
S4 nerve
Sciatic S5
Posterior femoral cutaneous
Co1
Pudendal
Sacral plexus, anterior view 59

60. Figure 13-13c The Lumbar and Sacral Plexuses
Iliohypogastric nerve
Ilioinguinal nerve
Genitofemoral nerve
Lateral femoral cutaneous nerve
Femoral nerve
Obturator nerve
Superior gluteal nerve
Inferior gluteal nerve
Pudendal nerve
Posterior femoral cutaneous nerve (cut)
Sciatic nerve
Saphenous nerve
Common fibular nerve
Superficial fibular nerve
Deep fibular nerve
Nerves of the lumbar and sacral plexuses, anterior view 60

61. Figure 13-13d The Lumbar and Sacral Plexuses
Saphenous nerve
Sural nerve
Sural nerve
Saphenous nerve
Sural nerve
Fibular nerve
Tibial nerve
Sural nerve
Saphenous nerve
Fibular nerve
Tibial nerve
Cutaneous distribution of the nerves in the foot and ankle 61

62. Figure 13-13e The Lumbar and Sacral Plexuses
Superior gluteal nerve
Inferior gluteal nerve
Pudendal nerve
Posterior femoral cutaneous nerve
Sciatic nerve
Tibial nerve
Common fibular nerve
Sural nerve
Nerves of the sacral plexus, posterior view 62

63. 13-5 Neuronal Pools 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

64. 13-5 Neuronal Pools 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

65. 13-5 Neuronal Pools Five Patterns of Neural Circuits in Neuronal Pools
Divergence
Spreads stimulation to many neurons or neuronal pools in CNS
Convergence
Brings input from many sources to single neuron
Serial processing
Moves information in single line

66. 13-5 Neuronal Pools Five Patterns of Neural Circuits in Neuronal Pools
Parallel processing
Moves same information along several paths simultaneously
Reverberation
Positive feedback mechanism
Functions until inhibited

67. Figure 13-14a Neural Circuits: The Organization of Neuronal Pools
Divergence
A mechanism for spreading stimulation to multiple neurons or neuronal pools in the CNS 67

68. Figure 13-14b Neural Circuits: The Organization of Neuronal Pools
Convergence
A mechanism for providing input to a single neuron from multiple sources 68

69. Figure 13-14c Neural Circuits: The Organization of Neuronal Pools
Serial processing
A mechanism in which neurons or pools work sequentially 69

70. Figure 13-14d Neural Circuits: The Organization of Neuronal Pools
Parallel processing
A mechanism in which neurons or pools process the same information simultaneously 70

71. Figure 13-14e Neural Circuits: The Organization of Neuronal Pools
Reverberation
A positive feedback mechanism 71

72. 13-6 Reflexes
Reflexes
Automatic responses coordinated within spinal cord
Through interconnected sensory neurons, motor neurons, and interneurons
Produce simple and complex reflexes

73. 13-6 Reflexes Neural Reflexes
Rapid, automatic responses to specific stimuli
Basic building blocks of neural function
One neural reflex produces one motor response
Reflex arc
The wiring of a single reflex
Beginning at receptor
Ending at peripheral effector
Generally opposes original stimulus (negative feedback)

74. 13-6 Reflexes Five 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

75. Figure 13-15 Events in a Neural Reflex
Dorsal root
Arrival of stimulus and activation of receptor
Activation of a sensory neuron
Sensation relayed to the brain by axon collaterals
Information processing in the CNS
REFLEX ARC
Receptor
Stimulus
Response by effector
Effector
Ventral root
KEY
Sensory neuron (stimulated)
Activation of a motor neuron
Excitatory interneuron
Motor neuron (stimulated) 75

76. 13-6 Reflexes Four Classifications of Reflexes By early development
By type of motor response
By complexity of neural circuit
By site of information processing

77. 13-6 Reflexes Development of Reflexes Innate reflexes
Basic neural reflexes
Formed before birth
Acquired reflexes
Rapid, automatic
Learned motor patterns

78. 13-6 Reflexes Motor Response Nature of resulting motor response
Somatic reflexes
Involuntary control of nervous system
Superficial reflexes of skin, mucous membranes
Stretch or deep tendon reflexes (e.g., patellar, or “knee-jerk,” reflex)
Visceral reflexes (autonomic reflexes)
Control systems other than muscular system

79. 13-6 Reflexes Complexity of Neural Circuit Monosynaptic reflex
Sensory neuron synapses directly onto motor neuron
Polysynaptic reflex
At least one interneuron between sensory neuron and motor neuron

80. 13-6 Reflexes Site of Information Processing Spinal reflexes
Occur in spinal cord
Cranial reflexes
Occur in brain

81. Figure 13-16 The Classification of Reflexes
can be classified by
development
response
response
complexity of circuit
processing site
Innate Reflexes
Somatic Reflexes
Monosynaptic
Spinal Reflexes
• Genetically
• Control skeletal muscle
• One synapse
• Processing in
determined
contractions
the spinal cord
• Include superficial and stretch
reflexes
Acquired Reflexes
Visceral (Autonomic) Reflexes
Polysynaptic
Cranial Reflexes
• Learned
• Control actions of smooth and
• Multiple synapse
• Processing in
cardiac muscles, glands, and adipose tissue
(two to several hundred)
the brain 81

82. 13-7 Spinal Reflexes Spinal Reflexes
Range in increasing order of complexity
Monosynaptic reflexes
Polysynaptic reflexes
Intersegmental reflex arcs
Many segments interact
Produce highly variable motor response

83. 13-7 Spinal Reflexes Monosynaptic Reflexes A stretch reflex
Have least delay between sensory input and motor output
For example, stretch reflex (such as patellar reflex)
Completed in 20–40 msec
Receptor is muscle spindle

84. Figure 13-17 A Stretch Reflex
Receptor (muscle
spindle)
Spinal cord
Stretch
REFLEX ARC
Stimulus
Effector
Contraction
KEY
Sensory neuron (stimulated)
Motor neuron (stimulated)
Response 84

85. 13-7 Spinal Reflexes Muscle Spindles The receptors in stretch reflexes
Bundles of small, specialized intrafusal muscle fibers
Innervated by sensory and motor neurons
Surrounded by extrafusal muscle fibers
Which maintain tone and contract muscle

86. 13-7 Spinal Reflexes The Sensory Region
Central region of intrafusal fibers
Wound with dendrites of sensory neurons
Sensory neuron axon enters CNS in dorsal root
Synapses onto motor neurons (gamma motor neurons)
In anterior gray horn of spinal cord

87. 13-7 Spinal Reflexes Gamma Efferents Axons of the motor neurons
Complete reflex arc
Synapse back onto intrafusal fibers
Important in voluntary muscle contractions
Allow CNS to adjust sensitivity of muscle spindles

88. Figure 13-18 A Muscle Spindle
Gamma efferent from CNS
Extrafusal fiber
To CNS
Sensory region
Intrafusal fiber
Muscle spindle
Gamma efferent from CNS 88

89. 13-7 Spinal Reflexes Postural reflexes Stretch reflexes
Maintain normal upright posture
Stretched muscle responds by contracting
Automatically maintain balance

90. 13-7 Spinal Reflexes Polysynaptic Reflexes
More complicated than monosynaptic reflexes
Interneurons control more than one muscle group
Produce either EPSPs or IPSPs

91. 13-7 Spinal Reflexes The Tendon Reflex Prevents skeletal muscles from:
Developing too much tension
Tearing or breaking tendons
Sensory receptors unlike muscle spindles or proprioceptors

92. 13-7 Spinal Reflexes Withdrawal Reflexes
Move body part away from stimulus (pain or pressure)
For example, flexor reflex
Pulls hand away from hot stove
Strength and extent of response
Depend on intensity and location of stimulus

93. Figure 13-19 A Flexor Reflex
Distribution within gray horns to other segments of the spinal cord
Painful stimulus
Flexors stimulated
Extensors inhibited
KEY
Sensory neuron (stimulated)
Motor neuron (inhibited)
Excitatory interneuron
Inhibitory interneuron
Motor neuron (stimulated) 93

94. 13-7 Spinal Reflexes Reciprocal Inhibition For flexor reflex to work
The stretch reflex of antagonistic (extensor) muscle must be inhibited (reciprocal inhibition) by interneurons in spinal cord

95. 13-7 Spinal Reflexes Reflex Arcs Ipsilateral reflex arcs
Occur on same side of body as stimulus
Stretch, tendon, and withdrawal reflexes
Crossed extensor reflexes
Involve a contralateral reflex arc
Occur on side opposite stimulus

96. 13-7 Spinal Reflexes Crossed Extensor Reflexes
Occur simultaneously, coordinated with flexor reflex
For example, flexor reflex causes leg to pull up
Crossed extensor reflex straightens other leg
To receive body weight
Maintained by reverberating circuits

97. Figure 13-20 The Crossed Extensor Reflex
To motor neurons in other segments of the spinal cord
Extensors inhibited
Flexors stimulated
Extensors stimulated
Flexors inhibited
KEY
Sensory neuron (stimulated)
Motor neuron (inhibited)
Excitatory interneuron
Inhibitory interneuron
Painful stimulus
Motor neuron (stimulated) 97

98. 13-7 Spinal Reflexes
Five General Characteristics of Polysynaptic Reflexes
1. Involve pools of interneurons
2. Are intersegmental in distribution
3. Involve reciprocal inhibition
4. Have reverberating circuits
Which prolong reflexive motor response
5. Several reflexes cooperate
To produce coordinated, controlled response

99. 13-8 The Brain Can Alter Spinal Reflexes
Integration and Control of Spinal Reflexes
Reflex behaviors are automatic
But processing centers in brain can facilitate or inhibit reflex motor patterns based in spinal cord

100. 13-8 The Brain Can Alter Spinal Reflexes
Voluntary Movements and Reflex Motor Patterns
Higher centers of brain incorporate lower, reflexive motor patterns
Automatic reflexes
Can be activated by brain as needed
Use few nerve impulses to control complex motor functions
Walking, running, jumping

101. 13-8 The Brain Can Alter Spinal Reflexes
Reinforcement of Spinal Reflexes
Higher centers reinforce spinal reflexes
By stimulating excitatory neurons in brain stem or spinal cord
Creating EPSPs at reflex motor neurons
Facilitating postsynaptic neurons

102. 13-8 The Brain Can Alter Spinal Reflexes
Inhibition of Spinal Reflexes
Higher centers inhibit spinal reflexes by:
Stimulating inhibitory neurons
Creating IPSPs at reflex motor neurons
Suppressing postsynaptic neurons

103. 13-8 The Brain Can Alter Spinal Reflexes
The Babinski Reflexes
Normal in infants
May indicate CNS damage in adults

104. Figure 13-21a The Babinski Reflexes
The plantar reflex (negative Babinski reflex), a curling of the toes, is seen in healthy adults.
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105. Figure 13-21b The Babinski Reflexes
The Babinski sign (positive Babinski reflex) occurs in the absence of descending inhibition. It is normal in infants, but pathological in adults.
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