1. 14
The Brain and Cranial Nerves

2. Figure 14-12a The Brain in Lateral View
Central sulcus
FRONTAL LOBE
PARIETAL LOBE
OCCIPITAL LOBE
Lateral sulcus
TEMPORAL LOBE
Cerebellum
Pons
Medulla oblongata
Lateral view, cadaver brain 2

3. Figure 14-12b The Brain in Lateral View
Precentral gyrus
Central sulcus
Postcentral gyrus
FRONTAL LOBE
PARIETAL LOBE
OCCIPITAL LOBE
TEMPORAL LOBE
Lateral sulcus
Cerebellum
Pons
Medulla oblongata
Lateral view 3

4. Figure 14-12c The Brain in Lateral View
Insula
Retractors along the lateral sulcus showing the insula 4

5. Figure 14-12d The Brain in Lateral View
Precentral gyrus
Central sulcus
Postcentral gyrus
Cingulate gyrus
PARIETAL LOBE
FRONTAL LOBE
Parieto- occipital sulcus
OCCIPITAL LOBE
Pons
TEMPORAL LOBE
Cerebellum
Medulla oblongata
Midsagittal section 5

6. 14-9 The Cerebrum Three Functional Principles of the Cerebrum
Each cerebral hemisphere receives sensory information from, and sends motor commands to, the opposite side of the body
The two hemispheres have different functions, although their structures are alike
Correspondence between a specific function and a specific region of cerebral cortex is not precise

7. 14-9 The Cerebrum White Matter of the Cerebrum Association fibers
Connections within one hemisphere
Commissural fibers
Bands of fibers connecting two hemispheres
Projection fibers
Connect cerebrum with lower areas

8. 14-9 The Cerebrum Association Fibers Arcuate fibers
Are short fibers
Connect one gyrus to another
Longitudinal fasciculi
Are longer bundles
Connect frontal lobe to other lobes in same hemisphere

9. 14-9 The Cerebrum Commissural Fibers Corpus callosum
Anterior commissure

10. 14-9 The Cerebrum Projection Fibers Pass through diencephalon
Link cerebral cortex with:
Diencephalon, brain stem, cerebellum, and spinal cord
Internal capsule
All ascending and descending projection fibers

11. Figure 14-13a Fibers of the White Matter of the Cerebrum
Arcuate fibers
Longitudinal fasciculi
Lateral view 11

12. Figure 14-13b Fibers of the White Matter of the Cerebrum
Longitudinal fissure
Corpus callosum
Projection fibers of internal capsule
Anterior commissure
Anterior view 12

13. 14-9 The Cerebrum The Basal Nuclei Are masses of gray matter
Are embedded in white matter of cerebrum
Direct subconscious activities

14. 14-9 The Cerebrum Anatomy of Basal Nuclei Caudate nucleus
Curving, slender tail
Lentiform nucleus
Globus pallidus
Putamen

15. Figure 14-14a The Basal Nuclei
Head of caudate nucleus
Lentiform nucleus
Tail of caudate nucleus
Amygdaloid body
Thalamus
The relative positions of the basal nuclei in the intact brain, lateral view 15

16. Figure 14-14b The Basal Nuclei
Corpus callosum
Head of caudate nucleus
Lateral ventricle (anterior horn)
Internal capsule
Septum pellucidum
Putamen
Fornix (cut edge)
Thalamus
Third ventricle
Choroid plexus
Pineal gland
Fornix
Lateral ventricle (posterior horn)
A horizontal section as seen in a dissection 16

17. Figure 14-14c The Basal Nuclei
Lateral ventricle
Corpus callosum
Head of caudate nucleus
Septum pellucidum
Internal capsule
Claustrum
Lateral sulcus
Insula
Anterior commissure
Putamen
Lentiform nucleus
Globus pallidus
Tip of lateral ventricle
Amygdaloid body
Frontal section 17

18. 14-9 The Cerebrum Functions of Basal Nuclei Involved with:
The subconscious control of skeletal muscle tone
The coordination of learned movement patterns (walking, lifting)

19. 14-9 The Cerebrum Motor and Sensory Areas of the Cortex
Central sulcus separates motor and sensory areas
Motor areas
Precentral gyrus of frontal lobe
Directs voluntary movements
Primary motor cortex
Is the surface of precentral gyrus
Pyramidal cells
Are neurons of primary motor cortex

20. 14-9 The Cerebrum Motor and Sensory Areas of the Cortex Sensory areas
Postcentral gyrus of parietal lobe
Receives somatic sensory information (touch, pressure, pain, vibration, taste, and temperature)
Primary sensory cortex
Surface of postcentral gyrus

21. 14-9 The Cerebrum Special Sensory Cortexes Visual cortex
Information from sight receptors
Auditory cortex
Information from sound receptors
Olfactory cortex
Information from odor receptors
Gustatory cortex
Information from taste receptors

22. Figure 14-15a Motor and Sensory Regions of the Cerebral Cortex
Primary motor cortex (precentral gyrus)
Central sulcus
Primary sensory cortex (postcentral gyrus)
Somatic motor association area (premotor cortex)
PARIETAL LOBE
Somatic sensory association area
FRONTAL LOBE
Visual association area
Prefrontal cortex
OCCIPITAL LOBE
Gustatory cortex
Visual cortex
Insula
Auditory association area
Lateral sulcus
Auditory cortex
TEMPORAL LOBE
Olfactory cortex
Major anatomical landmarks on the surface of the left cerebral hemisphere. The lateral sulcus has been pulled apart to expose the insula. 22

23. 14-9 The Cerebrum Association Areas Sensory association areas
Monitor and interpret arriving information at sensory areas of cortex
Somatic sensory association area
Interprets input to primary sensory cortex (e.g., recognizes and responds to touch)

24. 14-9 The Cerebrum Sensory Association Areas Visual association area
Interprets activity in visual cortex
Auditory association area
Monitors auditory cortex
Somatic motor association area (premotor cortex)
Coordinates motor responses (learned movements)

25. 14-9 The Cerebrum Integrative Centers
Are located in lobes and cortical areas of both cerebral hemispheres
Receive information from association areas
Direct complex motor or analytical activities

26. 14-9 The Cerebrum General Interpretive Area
Also called Wernicke’s area
Present in only one hemisphere
Receives information from all sensory association areas
Coordinates access to complex visual and auditory memories

27. 14-9 The Cerebrum Other Integrative Areas Speech center
Is associated with general interpretive area
Coordinates all vocalization functions
Prefrontal cortex of frontal lobe
Integrates information from sensory association areas
Performs abstract intellectual activities (e.g., predicting consequences of actions)

28. Figure 14-15b Motor and Sensory Regions of the Cerebral Cortex
Frontal eye field
Speech center
Prefrontal cortex
General interpretive area
The left hemisphere generally contains the general interpretive area and the speech center. The prefrontal cortex of each hemisphere is involved with conscious intellectual functions. 28

29. 14-9 The Cerebrum Interpretive Areas of Cortex Brodmann areas
Patterns of cellular organization in cerebral cortex

30. Figure 14-15c Motor and Sensory Regions of the Cerebral Cortex
Regions of the cerebral cortex as determined by histological analysis. Several of the 47 Brodmann areas are shown for comparison with the results of functional mapping. 30

31. Table 14-8 The Cerebral Cortex31

32. 14-9 The Cerebrum Hemispheric Lateralization
Functional differences between left and right hemispheres
Each cerebral hemisphere performs certain functions that are not ordinarily performed by the opposite hemisphere

33. 14-9 The Cerebrum The Left Hemisphere The Right Hemisphere
In most people, left brain (dominant hemisphere) controls:
Reading, writing, and math
Decision making
Speech and language
The Right Hemisphere
Right cerebral hemisphere relates to:
Senses (touch, smell, sight, taste, feel)
Recognition (faces, voice inflections)

34. Figure 14-16 Hemispheric Lateralization
Left Cerebral Hemisphere
LEFT HAND
Prefrontal cortex
Speech center
C O R P U S
Writing
C A
Auditory cortex
L L O S U M
General interpretive center (language and mathematical calculation)
Visual cortex (right visual field) 34

35. Figure 14-16 Hemispheric Lateralization
Right Cerebral Hemisphere
RIGHT HAND
Prefrontal cortex
Anterior commissure
C O R P U S
Analysis by touch
C A
Auditory cortex
L L O S U M
Spatial visualization and analysis
Visual cortex (left visual field) 35

36. 14-9 The Cerebrum Monitoring Brain Activity
Brain activity is assessed by an electroencephalogram (EEG)
Electrodes are placed on the skull
Patterns of electrical activity (brain waves) are printed out

37. 14-9 The Cerebrum Four Categories of Brain Waves Alpha waves
Beta waves
Theta waves
Delta waves

38. 14-9 The Cerebrum Alpha Waves Beta Waves
Found in healthy, awake adults at rest with eyes closed
Beta Waves
Higher frequency
Found in adults concentrating or mentally stressed

39. Alpha waves are characteristic of normal resting adults
Figure 14-17a Brain Waves
Alpha waves are characteristic of
normal resting adults
0 Seconds 1 2 3 4 39

40. Beta waves typically accompany intense concentration
Figure 14-17b Brain Waves
Beta waves typically accompany intense concentration
0 Seconds 1 2 3 4 40

41. 14-9 The Cerebrum Theta Waves Delta Waves Found in children
Found in intensely frustrated adults
May indicate brain disorder in adults
Delta Waves
During sleep
Found in awake adults with brain damage

42. Theta waves are seen in children and in frustrated adults
Figure 14-17c Brain Waves
Theta waves are seen in children and in frustrated adults
0 Seconds 1 2 3 4 42

43. Delta waves occur in deep sleep and in certain pathological conditions
Figure 14-17d Brain Waves
Delta waves occur in deep sleep and in certain pathological conditions
0 Seconds 1 2 3 4 43

44. 14-9 The Cerebrum Synchronization Seizure A pacemaker mechanism
Synchronizes electrical activity between hemispheres
Brain damage can cause desynchronization
Seizure
Is a temporary cerebral disorder
Changes the electroencephalogram
Symptoms depend on regions affected

45. 14-10 Cranial Nerves Cranial Nerves 12 pairs connected to brain
Four Classifications of Cranial Nerves
Sensory nerves carry somatic sensory information, including touch, pressure, vibration, temperature, and pain
Special sensory nerves carry sensations such as smell, sight, hearing, balance
Motor nerves: axons of somatic motor neurons
Mixed nerves: mixture of motor and sensory fibers

46. 14-10 Cranial Nerves Cranial Nerves
Are classified by primary functions
May also have important secondary functions
Distributing autonomic fibers to peripheral ganglia
The 12 cranial nerve groups are identified by:
Primary function
Origin
Pathway
Destination

47. Figure 14-18 Origins of the Cranial Nerves
Olfactory bulb: termination of olfactory nerve (I)
Olfactory tract
Optic nerve (II)
Infundibulum
Oculomotor nerve (III)
Pons
Basilar artery
Vertebral artery
Cerebellum
Medulla oblongata
Spinal cord 47

48. Figure 14-18 Origins of the Cranial Nerves
Optic chiasm
Optic tract
Mamillary body
Trochlear nerve (IV)
Trigeminal nerve (V)
Abducens nerve (VI)
Facial nerve (VII)
Vestibulocochlear nerve (VIII)
Glossopharyngeal nerve (IX)
Vagus nerve (X)
Hypoglossal nerve (XII)
Accessory nerve (XI) 48

49. 14-10 Cranial Nerves Olfactory Nerves (I) Primary function: Origin:
Special sensory (smell)
Origin:
Receptors of olfactory epithelium
Pathway:
Olfactory foramina in cribriform plate of ethmoid
Destination:
Olfactory bulbs

50. 14-10 Cranial Nerves Olfactory Nerve Structures Olfactory bulbs
Located on either side of crista galli
Olfactory tracts
Axons of postsynaptic neurons
Leading to cerebrum

51. Figure 14-19 The Olfactory Nerve
Olfactory tract (to olfactory cortex of cerebrum)
Left olfactory bulb (termination of olfactory nerve)
OLFACTORY NERVE (N I)
Olfactory nerve fibers
Cribriform plate of ethmoid
Olfactory epithelium 51

52. 14-10 Cranial Nerves Optic Nerves (II) Primary function: Origin:
Special sensory (vision)
Origin:
Retina of eye
Pathway:
Optic canals of sphenoid
Destination:
Diencephalon via optic chiasm

53. 14-10 Cranial Nerves Optic Nerve Structures Optic chiasm Optic tracts
Where sensory fibers converge
And cross to opposite side of brain
Optic tracts
Reorganized axons
Leading to lateral geniculate nuclei

54. Figure 14-20 The Optic Nerve
Eye
Olfactory bulb
Pituitary gland
Olfactory tract
OPTIC NERVE (N II)
Optic chiasm
Optic tract
Lateral geniculate nucleus (in thalamus)
Optic projection fibers
Midbrain (cut)
Visual cortex (in occipital lobes) 54

55. 14-10 Cranial Nerves Oculomotor Nerves (III) Primary function:
Motor (eye movements)
Origin:
Midbrain
Pathway:
Superior orbital fissures of sphenoid

56. 14-10 Cranial Nerves Oculomotor Nerves (III) Destination:
Somatic motor
Superior, inferior, and medial rectus muscles
Inferior oblique muscle
Levator palpebrae superioris muscle
Visceral motor
Intrinsic eye muscles

57. 14-10 Cranial Nerves Oculomotor Nerve Structures Oculomotor nerve
Controls four of six eye-movement muscles
Delivers autonomic fibers to ciliary ganglion
Ciliary ganglion controls intrinsic muscles of iris and lens

58. 14-10 Cranial Nerves The Trochlear Nerves (IV) Primary function:
Motor (eye movements)
Origin:
Midbrain
Pathway:
Superior orbital fissure of sphenoid
Destination:
Superior oblique muscle

59. 14-10 Cranial Nerves The Abducens Nerves (VI) Primary function:
Motor (eye movements)
Origin:
Pons
Pathway:
Superior orbital fissures of sphenoid
Destination:
Lateral rectus muscle

60. Figure 14-21 Cranial Nerves Controlling the Extra-Ocular Muscles
Superior rectus muscle
OPTIC NERVE (N II)
Optic chiasm
OCULOMOTOR NERVE (N III)
TROCHLEAR NERVE (N IV)
Superior oblique muscle
Trochlea
Levator palpebrae superioris muscle
Trigeminal nerve (N V), cut
Inferior oblique muscle
Vestibulocochlear nerve (N VIII), cut
Facial nerve (N VII), cut
Inferior rectus muscle
Medial rectus muscle
Ciliary ganglion
Lateral rectus muscle (cut)
ABDUCENS NERVE (N VI) 60

61. 14-10 Cranial Nerves The Trigeminal Nerves (V) Primary function:
Mixed (sensory and motor) to face
Origin:
Ophthalmic branch (sensory)
Orbital structures
Nasal cavity
Skin of forehead, upper eyelid, and eyebrow
Part of nose

62. 14-10 Cranial Nerves The Trigeminal Nerves (V) Origin:
Maxillary branch (sensory)
Lower eyelid
Upper lip, gums, and teeth
Cheek and nose
Palate and part of pharynx

63. 14-10 Cranial Nerves The Trigeminal Nerves (V) Origin:
Mandibular branch (sensory)
Lower gums, teeth, and lips
Palate and part of tongue
Mandibular branch (motor)
Motor nuclei of pons

64. 14-10 Cranial Nerves The Trigeminal Nerves (V) Pathway:
Ophthalmic branch
Superior orbital fissure
Maxillary branch
Foramen rotundum
Mandibular branch
Foramen ovale

65. 14-10 Cranial Nerves The Trigeminal Nerves (V) Destination:
Sensory nerves
Sensory nuclei in pons
Motor nerves of mandibular branch
Muscles of mastication

66. 14-10 Cranial Nerves Trigeminal Nerve Structures Trigeminal nerves
Largest cranial nerves
With three major branches
Semilunar ganglion
Contains cell bodies of sensory neurons

67. Figure 14-22 The Trigeminal Nerve
Superior orbital fissure
Supra-orbital nerves
Ophthalmic branch
Semilunar ganglion
Ciliary ganglion
Pons
TRIGEMINAL NERVE (N V)
Foramen rotundum
Maxillary branch
Infra-orbital nerve
Foramen ovale
Lingual nerve
Otic ganglion
Submandibular ganglion
Mandibular branch
Pterygopalatine ganglion
Mental nerve 67

68. 14-10 Cranial Nerves The Facial Nerves (VII) Primary function: Origin:
Mixed (sensory and motor) to face
Origin:
Sensory
Taste receptors on anterior 2/3 of tongue
Motor
Motor nuclei of pons
Pathway:
Internal acoustic meatus to facial canals (stylomastoid foramina)

69. 14-10 Cranial Nerves The Facial Nerves (VII) Destination: Sensory
Sensory nuclei of pons
Somatic motor
Muscles of facial expression
Visceral motor
Tear and nasal mucous glands
Submandibular and sublingual salivary glands

70. 14-10 Cranial Nerves Facial Nerve Structures Facial nerve branches
Temporal
Zygomatic
Buccal
Mandibular
Cervical branches

71. 14-10 Cranial Nerves Facial Nerve Structures Geniculate ganglia
Hold cell bodies of sensory neurons
Pterygopalatine ganglia
Postganglionic fibers innervate glands (lacrimal, nasal cavity, and pharynx)
Submandibular ganglia
Innervate salivary glands

72. Figure 14-23a The Facial Nerve
Pterygopalatine ganglion
Greater petrosal nerve
Geniculate ganglion
FACIAL NERVE (N VII)
Temporal branch
Pons
Zygomatic branches
Posterior auricular branch
Buccal branch
Stylomastoid foramen
Chorda tympani nerve (with mandibular branch of N V)
Mandibular branch
Lingual branch (with lingual nerve of N V)
Cervical branch
Submandibular ganglion
The origin and branches of the facial nerve 72

73. Figure 14-23b The Facial Nerve
Temporal branch
Zygomatic branch
Buccal branch
Mandibular branch
Cervical branch
The superficial distribution of the five major branches of the facial nerve 73

74. 14-10 Cranial Nerves The Vestibulocochlear Nerves (VIII)
Primary function:
Special sensory
Vestibular branch
Balance and equilibrium
Cochlear branch
Hearing

75. 14-10 Cranial Nerves The Vestibulocochlear Nerves (VIII) Origin:
Receptors of inner ear
Pathway:
Internal acoustic meatus of temporal bones
Destination:
Vestibular and cochlear nuclei of pons and medulla oblongata

76. 14-10 Cranial Nerves Vestibulocochlear Nerve Structures
Vestibular branch
Originates at receptors of vestibule (balance)
Connects to vestibular nuclei of pons and medulla oblongata
Cochlear branch
Originates at sensors of cochlea (hearing)
Connects with cochlear nuclei of pons and medulla oblongata

77. Figure 14-24 The Vestibulocochlear Nerve
Tympanic cavity (middle ear)
Semicircular canals
Vestibular branch (N VIII)
Facial nerve (N VII), cut
Internal acoustic meatus
VESTIBULOCOCHLEAR NERVE (N VIII)
N V
Pons
N VI
N VII
N IX
N XII
N X
Medulla oblongata
N XI
Tympanic membrane
Auditory tube
Cochlea
Cochlear branch (N VIII) 77

78. 14-10 Cranial Nerves The Glossopharyngeal Nerves (IX)
Primary function:
Mixed (sensory and motor) to head and neck

79. 14-10 Cranial Nerves The Glossopharyngeal Nerves (IX) Origins: Sensory
Posterior 1/3 of tongue
Part of pharynx and palate
Carotid arteries
Motor
Motor nuclei of medulla oblongata

80. 14-10 Cranial Nerves The Glossopharyngeal Nerves (IX) Pathway:
Jugular foramina between occipital and temporal bones
Destination:
Sensory
Sensory nuclei of medulla oblongata
Somatic motor
Nerves involved in swallowing
Visceral motor
Parotid salivary gland

81. 14-10 Cranial Nerves Glossopharyngeal Nerve Structures
Superior and inferior ganglion
Sensory neurons of tongue and pharynx
Otic ganglion
Synapse visceral motor fibers

82. Figure 14-25 The Glossopharyngeal Nerve
Pons
N V
N VIII
N VII
N VI
GLOSSOPHARYNGEAL NERVE (N IX)
Otic ganglion
Medulla oblongata
Inferior (petrosal) ganglion
Superior (jugular)
ganglion
Parotid salivary gland
Lingual branch
Pharyngeal branches
Carotid sinus branch
Carotid body
Carotid sinus
Common carotid artery 82

83. 14-10 Cranial Nerves The Vagus Nerves (X) Primary function:
Mixed (sensory and motor)
Widely distributed in thorax and abdomen

84. 14-10 Cranial Nerves The Vagus Nerves (X) Origins: Sensory
Part of pharynx
Auricle and external acoustic meatus
Diaphragm
Visceral organs of thoracic and abdominopelvic cavities
Motor
Motor nuclei in medulla oblongata

85. 14-10 Cranial Nerves The Vagus Nerves (X) Pathway: Jugular foramina
Between occipital and temporal bones

86. 14-10 Cranial Nerves The Vagus Nerves (X) Destination: Sensory
Sensory nuclei and autonomic centers of medulla oblongata
Visceral motor
Muscles of the palate and pharynx
Muscles of the digestive, respiratory, and cardiovascular systems in thoracic and abdominal cavities

87. 14-10 Cranial Nerves Vagus Nerve Structures Vagus nerves
Branch and radiate extensively
Superior (jugular) ganglion and inferior (nodose) ganglion
Hold sensory neurons

88. Figure 14-26 The Vagus Nerve
Superior pharyngeal branch
VAGUS NERVE (N X)
Pons
Medulla oblongata
Auricular branch to external ear
Superior ganglion of vagus nerve
Inferior ganglion of vagus nerve
Pharyngeal branch
Superior laryngeal nerve
Internal branch
Superior laryngeal nerve
External branch 88

89. Figure 14-26 The Vagus Nerve
Recurrent laryngeal nerve
Cardiac branches
Cardiac plexus
Right lung
Left lung
Liver
Anterior vagal trunk
Spleen
Stomach
Celiac plexus
Pancreas
Colon
Small intestine
Hypogastric plexus 89

90. 14-10 Cranial Nerves The Accessory Nerves (XI) Primary function:
Motor to muscles of neck and upper back
Origin:
Motor nuclei of spinal cord and medulla oblongata

91. 14-10 Cranial Nerves The Accessory Nerves (XI) Pathway:
Jugular foramina between occipital and temporal bones
Destination:
Internal branch
Voluntary muscles of palate, pharynx, and larynx
External branch
Sternocleidomastoid and trapezius muscles

92. 14-10 Cranial Nerves Accessory Nerve Structures Spinal root
Motor fibers that originate in anterior gray horns of first five cervical segments of spinal cord
Cranial root
Motor fibers that originate in medulla oblongata

93. 14-10 Cranial Nerves Accessory Nerve Structures Internal branch
Joins the vagus nerve
External branch
Controls muscles of neck and back

94. 14-10 Cranial Nerves The Hypoglossal Nerves (XII) Primary function:
Motor (tongue movements)
Origin:
Motor nuclei of medulla oblongata
Pathway:
Hypoglossal canals of occipital bone
Destination:
Muscles of tongue

95. Figure 14-27 The Accessory and Hypoglossal Nerves
HYPOGLOSSAL NERVE (N XII)
Trigeminal nerve (N V)
ACCESSORY NERVE (N XI)
Internal branch: to palatal, pharyngeal, and laryngeal muscles with vagus nerve
Medulla oblongata
Cranial root of N XI
Intrinsic muscles of tongue
Spinal root of N XI
Styloglossus muscle
External branch of N XI
Genioglossus muscle
Geniohyoid muscle
Spinal cord
Hyoglossus muscle
Trapezius muscle
Hyoid bone
Thyrohyoid muscle
Sternocleidomastoid muscle
Sternohyoid muscle
Ansa cervicalis (cervical plexus)
Sternothyroid muscle
Omohyoid muscle 95

96. Table 14-9 Cranial Nerve Branches and Functions96

97. Table 14-9 Cranial Nerve Branches and Functions97

98. 14-10 Cranial Reflexes Cranial Reflexes
Monosynaptic and polysynaptic reflex arcs
Involve sensory and motor fibers of cranial nerves
Clinically useful to check cranial nerve for brain damage

99. Table 14-10 Cranial Reflexes99