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Thoracic dissection revealing vagus nerve
Anterior view
Deeper thoracic dissection revealing vagus nerve
Anterior view
cardiac muscle, and glands. Some of the autonomic nerves even rejoin the somatic pathways to supply the blood vessels
and glands of the body wall. The sympathetic pathways are primarily associated with vascular smooth muscle control, and
the parasympathetic pathways are principally responsible for the regulation and control of gut tube smooth muscle and
glands. The sympathetic nerves are depicted on the opposite page, while the vagus nerve, which carries 75% of the parasympathetic output, is shown below as it follows the derivatives of the gut tube.
38 Thyroid gland
39 Trachea
40 Principal bronchus
41 Lobar bronchus
42 Segmental bronchus
43 Esophagus
44 Lung
45 Right common carotid artery
46 Left common carotid artery
47 Right subclavian artery
48 Left subclavian artery
49 Brachiocephalic artery
50 Pulmonary arteries
51 Pulmonary veins
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53 Cricothyroid muscle
54 Anterior scalene muscle
55 Ligamentum arteriosum
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Cranial nerves segregate into three distinct groups based
on associations they form during development. In number
there are twelve cranial nerves, which originate in pairs
Cranial Nerves
from a rostral to caudal sequence from the brain. The fi rst category, the special sensory cranial
nerves, are afferent pathways established between the the brain and the special sensory structures
of the nose, eye, and ear. The second category, the ventral or somitic motor cranial nerves, are
homologous with the ventral roots of the spinal nerves. They originate from the brainstem as efferent
pathways to somitic skeletal muscles within the head. The fi nal category, comprising the largest of the
Base of brain with cranial nerves
Inferior view
Special Sensory Nerves
1 Olfactory nerve
2 Optic nerve
3 Vestibulocochlear nerve
Somitic Motor Nerves
4 Occulomotor nerve
5 Trochlear nerve
6 Abducens nerve
7 Hypoglossal nerve
Pharyngeal Arch Nerves
8 Trigeminal nerve
9 Trigeminal ganglion
10 Opthalmic branch
11 Maxillary branch
12 Mandibular branch
13 Facial nerve
14 Glossopharyngeal nerve
15 Vagus nerve
16 Accessory nerve
Other Structures
17 Olfactory bulb
18 Optic chiasm
19 Optic tract
20 Infundibulum
21 Mammillary bodies
22 Cerebral peduncle
23 Pons
24 Cerebellum
25 Medulla oblongata
26 Spinal cord
27 Frontal lobe
28 Temporal lobe
29 Insular lobe
30 Parietal lobe
31 Occipital lobe
32 Right lateral ventricle
33 Choroid plexus
34 Falx cerebri
35 Falx cerebelli
36 Straight sinus
37 Superior sagittal sinus
38 Corpora quadrigemina
39 Pineal gland
40 Third ventricle
41 Fourth ventricle
42 Geniculate ganglion
43 Anterior cerebral artery
44 Internal carotid artery
45 Levator palpebrae superioris muscle
46 Superior rectus muscle
47 Lateral rectus muscle
48 Superior oblique muscle
49 Nasociliary nerve
50 Long ciliary nerve
51 Ciliary ganglion
52 Eye
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Intracranial dissection of cranial nerves
Posterolateral view
cranial nerves, are those cranial nerves associated with the pharyngeal arches. The dorsal or
pharyngeal arch cranial nerves are developmentally similar to the dorsal roots of the spinal
nerves. These fi ve dorsal cranial nerves form the general sensory afferent pathways from the
peripheral tissues of the head. However, because these nerve pathways coursed through the
specialized arches forming the pharyngeal wall of the foregut, they established parasympathetic efferent pathways to the glandular tissue of the gut wall, along with motor efferent pathways to the skeletal muscles derived from the pharyngeal arch tissues.
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Cranial nerves V and VII, the trigeminal and facial nerves respectively, have the most extensive
distribution to the tissues of the head. This page
Cranial Nerves
and the three pages that follow depict the peripheral distribution of many of the branches of
the trigeminal and facial nerves.
Dissection of head exposing branches of the facial nerve
Lateral view
Trigeminal Nerve
1 Auriculotemporal nerve
2 Supraorbital nerve
3 Infraorbital nerve
4 Mental nerve
5 Maxillary branch
6 Nerve of the pterygoid canal
7 Pterygopalatine ganglion
8 Nasopalatine nerve (cut)
9 Superior posterior lateral nasal branch
10 Inferior posterior lateral nasal branch
11 Pharyngeal branch
12 Lesser palatine nerve
13 Greater palatine nerve
Facial Nerve
14 Temporal branches
15 Zygomatic branches
16 Buccal branches
17 Mandibular branches
18 Cervical branch
Other Nerves and Structures
19 Greater occipital nerve
20 Lesser occipital nerve
21 Great auricular nerve
22 Auricularis posterior muscle
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23 Occipital belly of epicranius muscle
24 Galia aponeurotica
25 Frontal belly of epicranius muscle
26 Temporal fascia
27 Temporalis muscle
28 Orbicularis oculi muscle
29 Zygomaticus major muscle
30 Risorius muscle
31 Buccinator muscle
32 Masseter muscle
33 Posterior digastricus muscle
34 Parotid duct
35 External carotid artery
36 Submandibular gland
37 Frontal sinus
38 Cerebrum
39 Falx cerebri
40 Corpus callosum
41 Septum pellucidum
42 Thalamus
43 Midbrain
44 Pons
45 Cerebellum
46 Fourth ventricle
47 Choroid plexus
48 Medulla oblongata
49 Spinal cord
Parasagittal section and dissection of head exposing branches of the trigeminal and facial nerve
Medial view
50 Pituitary gland
51 Torus tubarius
52 Maxillary sinus
53 Middle nasal concha
54 Inferior nasal concha
55 Hard palate
56 Soft palate
57 Uvula
58 Tongue
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Cranial Nerves
1 Nerve to temporalis muscle
2 Buccal nerve
3 Middle superior alveolar nerve
4 Posterior superior alveolar nerve
5 Lingual nerve
6 Chorda tympani nerve
7 Inferior alveolar nerve
8 Nerve to mylohyoid muscle
9 Pterygopalatine ganglion
10 Infraorbital nerve
11 Hypoglossal nerve
12 Submandibular ganglion
13 Superior laryngeal nerve
Other Structures
14 Orbicularis oculi muscle
15 Temporal fascia
16 Temporalis muscle
Dissection of head exposing branches of the trigeminal nerve
Lateral view
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Dissection of head with mandible removed
Lateral view
17 Lateral pterygoid muscle
18 Medial pterygoid muscle
19 Buccinator muscle
20 Posterior digastricus muscle
21 Anterior digastricus muscle
22 Sternocleidomastoid muscle
23 Thyrohyoid muscle
24 Omohyoid muscle
25 Styloglossus muscle
26 Stylohyoid muscle
27 Geniohyoid muscle
28 Mylohyoid muscle
29 Superior pharyngeal constrictor
30 Inferior pharyngeal constrictor
31 Internal jugular vein
32 Common carotid artery
33 Dura mater
34 Cerebrum
35 External acoustic meatus
36 Tongue
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Sensory receptors are the transducers of the nervous system; that is,
they convert the different types of energy we experience such as
mechanical energy (touch, pressure, sound waves, etc.), thermal
Sensory Receptors
energy (heat), chemical energy (taste, smell), and electromagnetic energy (light) into the electrical energy of the nervous
impulse. They do this by facilitating the depolarization of the peripheral terminals of the sensory neurons. This initiates the
nervous impulse along the sensory neuron, and this input is carried by the sensory neuron to the processing centers of the
brain and spinal cord, which will be the topic of the next chapter.
Photomicrograph of corpuscle of touch
200x
Photomicrographs of taste bud
200x (left), 700x (right)
Photomicrograph of lamellated corpuscle
100x
1 Epidermis
2 Corpuscle of touch (Meissner’s)
3 Dermis
4 Dermal papilla
5 Neuron
6 Lamellated corpuscle
7 Taste bud
8 Taste pore
9 Gustatory hair
10 Gustatory receptor cell
11 Supporting cell
12 Basal cell
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While the neuronal circuitry of
the central nervous system is awe inspiring to say the least, the basic
concepts behind this complex integration and control center have a
simple design. At its simplest, the fundamental design of the central
nervous system involves two features: gray matter and white matter.
Th e gray matter centers represent the synaptic integration and control circuits; that is, these centers contain numerous highly dendritic interneurons along with the cell bodies of eff erent neurons
and axon terminals of incoming aff erent neurons, all forming a
myriad of synaptic circuits. In these gray centers input is integrated, compared, sensed, and stored to give rise to coordinated, controlled output. Th e white matter, on the other hand, represents
conduction tracts between the synaptic gray centers. Th ese white
tracts consist mainly of the myelinated axons of interneurons
relaying signals from one gray center to another.
A second simple concept to keep in mind is that the complexity of the central nervous system increases from a caudal to
cranial direction. Th ere is logic to this pattern because in the
spinal cord the gray centers primarily function as integration
networks that regulate input and output for their specifi c spinal
nerve levels. In other words, they are segmental control centers.
Input entering a spinal nerve level initiates refl exive output back
to the peripheral tissues at that same spinal level. Connecting
these segmental gray centers via interneuronal tracts leads to
greater association between neighboring levels, therefore improving integration and control. If one segmental gray center
can relay information received from its center to neighboring
centers, then there can be a greater spread of control generated in
response to local segmental input. Now take this a step further by
relaying information via white tracts from each of the segmental
control centers to higher centers. Th ese higher centers receive input from all the lower segmental centers, integrating the input to
gain a full body perspective, while generating the necessary output
signals to exert coordinated full body control. Because of this added
circuitry the cranial or brain end of the central nervous system increases in size. Th is additive accumulation of interconnected gray centers accounts for the structure of the brain and its amazing functional
properties.
Because much of the central nervous system circuitry is of a more microscopic nature and beyond the scope of this book. In this chapter we attempt to depict the basic gross anatomy of the central nervous system and its
protective coverings.
14 Central Nervous System
231
REAL ANATOMY
Find more information
about the central nervous
system in
232
1 Dorsal horn of gray matter
2 Lateral horn of gray matter
3 Ventral horn of gray matter
4 Posterior funiculus of white matter
5 Lateral funiculus of white matter
6 Anterior funiculus of white matter
Photomicrograph of spinal cord
50x
Extending from the brainstem is a long slender rod of nerve tissue, the spinal cord. The
cord exits the foramen magnum of the skull and descends within the vertebral canal of
the boney vertebral column. It is about 45 cm long (18 inches) and ends between the fi rst
Spinal Cord
7 Central canal
8 Dorsolateral fasciculus
9 Dorsal root of spinal nerve
10 Dorsal root ganglion
11 Ventral root of spinal nerve
12 Spinal cord
and second lumbar vertebrae. Although there are some slight regional variations, the cross-sectional anatomy of the spinal
cord is generally the same throughout its length. The gray matter of the spinal cord forms a butterfl y-shaped region in the
center of the cord that is surrounded by the white matter. As is the theme throughout the central nervous system, gray matter consists primarily of neuronal cell bodies and their dendrites, short interneurons, and glial cells. The white matter is organized into tracts, which are bundles of myelinated nerve fi bers (axons of long interneurons and sensory neurons) that
communicate between the gray circuit centers at all levels of the spinal cord and brain.
Each side of the H-shaped gray matter of the spinal cord has a dorsal horn and a ventral horn sandwiching an intermediate gray region. Entering the dorsal horns from the dorsal rootlets are the axons of the afferent neurons, which
synapse with small interneuron pools to form segmental integration centers for that level of the body. The dorsal horn and
intermediate gray matter contain numerous small interneurons. The intermediate gray also contains, at certain levels, the
preganglionic efferent neurons of the autonomic output. The ventral horns are primarily populated by the efferent neurons
to the skeletal muscles of their respective spinal levels. The white matter tracts are grouped into columns of myelinated
axons that extend the length of the cord. Each of these tracts begins or ends within a particular area of the cord and brain,
and each is specifi c in the type of information that it transmits. Some are ascending tracts that carry signals derived from
sensory input. For example, one tract carries information derived from pain and temperature receptors, whereas another
carries information regarding touch. Other tracts are descending tracts that relay messages from the brain to motor neurons
in the ventral horn.
Both the white and gray matter exhibit regional differences throughout the length of the spinal cord. There is relatively more white matter at the cranial end of the spinal cord than at the caudal end. Notice that the gray matter, especially
the ventral horn, is the largest at lower cervical levels and at lower lumbar-upper sacral levels. These levels correspond to
upper and lower limb anatomy respectively, where large amounts of muscle tissue require motor innervtion from the ventral
horn motor neuron pools.
13 Conus medullaris
14 Cauda equina
15 Dorsal rami of spinal nerve
16 Cerebrum
17 Cerebellum
18 First lumbar vertebra
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Cervical spinal cord
Thoracic spinal cord
Lumbar spinal cord
Sacral spinal cord
Dissection of vertebral column and skull revealing brain and spinal cord
Posterior view, with call-out of terminal end of cord
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The brain is the large, anterior-expansion of the neural tube situated within the cranium. Rapid development of
the rostral e nd of the neural tube forms three expanded regions — the prosencephalon, mesencephalon,
and rhombencephalon. The prosencephalon undergoes further development to form the telencephalon
Brain
and diencephalon, and the rhombencephalon continues to develop to form a metencephalon and myelencephalon. These
fi ve embryonic regions give rise to the brain. The telencephalon becomes the cerebrum, the diencephalon becomes the
thalamic regions, the mesencephalon becomes the midbrain, the metencephalon becomes the cerebellum and pons, and the
myelencephalon becomes the medulla oblongata. A variety of views of the full brain are depicted on this and the facing page.
1 Spinal cord
2 Medulla oblongata
3 Pons
4 Cerebellum
5 Midbrain
6 Diencephalon
7 Frontal lobe of cerebrum
8 Parietal lobe of cerebrum
9 Occipital lobe of cerebrum
10 Temporal lobe of cerebrum
11 Longitudinal fissure
12 Transverse fissure
13 Lateral cerebral sulcus
14 Anterior median fissure
15 Gyrus
16 Sulcus
Brain
Lateral view
17 Central sulcus
18 Precentral gyrus
19 Postcentral gyrus
20 Precentral sulcus
21 Postcentral sulcus
22 Inferior frontal gyrus
23 Superior temporal gyrus
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