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Module 8 Transcript

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 CT Basics: Cross-sectional Anatomy of the Head and Neck
Module 8

1. Title Screen
Welcome to CT Basics Module 8 – Cross-sectional Anatomy of the Head and Neck. This module
was written by Bettye G. Wilson, M.A.Ed., R.T.(R)(CT),RDMS, FASRT

2. License Agreement

3. Objectives
After completing this module, you will be able to:
Name and describe the anatomical planes of the body.
List and define directional terminology related to the body.
Describe human embryo development.
Name the major structures of the head and neck discussed in this module.
Describe the function of each anatomical structure discussed in this module.
Locate specific organs or structures on a schematic or CT image.
Identify the anatomical plane in which cross-sectional images were either acquired or
reformatted.
Recall the structures of the human vascular system.
Name the 12 cranial nerves, their distribution and function.
Identify selected muscular structures.

4. Introduction
All radiologic technologists performing medical imaging and radiation therapy need a strong
foundation in human anatomy. However, as technology advances and computed tomography is used
increasingly to diagnose and treat numerous diseases, technologists will require not only a broad
knowledge of gross and radiographic human anatomy, but also an understanding of cross-sectional
anatomy.
This module covers the basics of cross-sectional anatomy as seen on CT images, although
several other imaging modalities such as magnetic resonance imaging, positron emission tomography
and diagnostic medical ultrasound require practitioners to understand cross-sectional anatomy. Because
it would be difficult for a single module to discuss all the anatomy of the human body, we will only
identify the location, function and appearance of major structures.
This module is designed to provide you with the necessary tools for understanding anatomy in
three dimensions. We assume that you have prior knowledge of overall gross anatomy and a working
knowledge of radiographic anatomy, especially radiographic baselines and landmarks. In turn, we
believe the study of cross-sectional anatomy will enhance your understanding of both gross and
radiographic anatomy.

5. Body Planes and Directional Terminology
Radiologic technologists are generally quite familiar with the body planes and directional
terminology, so we only will review essential terms in this section. The body, especially for imaging
purposes, is divided into the axial, coronal, oblique or orthogonal, sagittal and transverse planes.

©2017 ASRT. All rights reserved. CT Basics: Module 8
6. Axial Plane
An axial plane divides the body into cranial, or superior, and caudal, or inferior, portions. The
axial plane often is referred to as the transverse plane, although “transverse” is a directional term
indicating crosswise or horizontal. CT images are initially acquired along the axial plane only, although
images can be reformatted into other planes and forms, such as sagittal and three-dimensional.

7. Coronal Plane
A coronal plane separates the body into anterior and posterior portions, also termed ventral and
dorsal. The midcoronal plane divides the body into equal anterior and posterior halves. The term
“midcoronal” assumes there is an imaginary line running through the axilla; therefore, some people use
the terms “axillary” and “midaxillary” in reference to the coronal and midcoronal planes.

8. Sagittal Plane
The sagittal plane divides the body into right and left halves. Midsagittal refers to the plane that
divides the body into equal right and left halves.

9. Oblique Planes
Oblique planes, also referred to as orthogonal planes, run at a slant through the body.

10. Directional Terminology
As important as it is to know the body planes, it is equally important to be familiar with
directional terminology. The terms used most frequently are:
Anterior – toward the front of the body.
Posterior – toward the back of the body.
Caudal – toward the inferior part of the body (away from the head).
Cranial – toward the upper part of the body (toward the head).
Proximal – toward or above.
Distal – away from or beneath.
Dorsal – the back portion of the body (posterior surface).
Ventral – toward the anterior surface of the body.
Superior – above or on top of.
Inferior – below or underneath.
Lateral – away from the body or sagittal plane.
Medial – toward the body or sagittal plane.
Prone – lying face down on the ventral surface.
Supine – lying face up on the dorsal surface.

11. Practice Question

12. Practice Question

13. Human Embryo Development
The human ovum is fertilized in the fallopian tubes. After fertilization, the united male sperm
and female ovum, or zygote, travels into the uterus, where major cellular events occur. One of these

©2017 ASRT. All rights reserved. CT Basics: Module 8
events is the formation of a blastocyst, which is implanted in the endometrial layer of the uterine wall
about seven days after ovulation or around the 21st day of the menstrual cycle.
Secure implantation takes about seven days, as the endometrial tissue grows and encompasses
the blastocyst. The blastocyst secrets human chorionic gonadotropin, better known as HCG, to avoid
being aborted by the uterus. Pregnancy tests are based on the presence of HCG in a woman’s blood or
urine, since HCG is only found during pregnancy.
During implantation, changes occur to the inner cell mass of the blastocyst, resulting in the
formation of primary germ layers. The amnionic cavity also develops in the inner cell mass as does a
two-layered, flattened embryonic disk. The primary germ layers are the ectoderm, endoderm and
mesoderm.
All human tissue and organs develop from these primary germ layers. Embryonic human
development begins at this point. The embryonic stage lasts six weeks, from the beginning of week
three through week eight.

14. Ectoderm
Human structures that develop from the ectoderm include the:
1) Epidermis of the skin.
2) Hair, nails and skin glands.
3) Lenses of the eyes.
4) Enamel of the teeth.
5) Adrenal medulla.
6) Receptor cells of the organs of sense.
7) Lining of the oral and nasal cavities, vagina and anus.

15. Central Nervous System
In addition, and most importantly, about 18 to 20 days after conception, the human central
nervous system develops from a thickened area of the ectoderm called the neural plate. The neural
plate develops into a neural crest and a neural tube. The neural tube forms the human brain and spinal
cord, while the neural crest forms the majority of the structures of the peripheral nervous system.
The neural tube initially is open at both the caudal and cranial ends. The cranial end closes
around 24 days after conception, and the caudal end closes about two days after that. Differentiation
and growth of the neural tube is greatest at its cranial end.
The cranial end of the neural tube separates into three primary vesicles: the prosencephalon or
forebrain, the mesencephalon or midbrain, and the rhombencephalon or hindbrain. About a week after
differentiation, two of the three primary vesicles, the prosencephalon and rhombencephalon, divide.
The telencephalon and the diencephalon develop from the prosencephalon. The
rhombencephalon develops into the metencephalon and the myelencephalon. Thus, the three primary
vesicles become five secondary vesicles.

16. Brain Development
Ultimately, the telencephalon develops into the cerebral hemispheres and basal ganglia; the
diencephalon develops into the thalamus, hypothalamus, pineal gland, third ventricle and optic tract.
The mesencephalon develops into the tectum, corpora quadrigemina, cerebral peduncles and cerebral
aqueduct.
The metencephalon develops into the pons and part of the medulla oblongata, cerebellum and
part of the fourth ventricle. The myelencephalon develops into the remaining parts of medulla
oblongata and fourth ventricle.

©2017 ASRT. All rights reserved. CT Basics: Module 8
17. Endoderm
Structures that develop from the endoderm include the epithelium of the digestive tract, liver,
pancreas, urinary bladder, urethra and respiratory tract. The thyroid, parathyroid and thymus glands
also are formed by the endoderm.

18. Mesoderm
The mesoderm forms the dermis of the skin; cardiac, skeletal and smooth muscles; connective
tissue, including cartilage and bone; the epithelium of the blood vessels, joint cavities and serous
membranes; the kidneys, ureters and adrenal cortex; and the epithelium of the female and male
reproductive systems.
Human pregnancy is approximately 40 weeks in length. After about 26 weeks, development
consists of continued growth and maturation of the organs, tissues and other structures.

19. Practice Question

20. Practice Question

21. The Head and Neck
The major bony structure of the head is the cranium, also called the cranial vault. This structure
encases and protects the brain and pituitary gland. The brain and pituitary gland are vital to the
integration of the body’s activities and functions.

22. Scalp
The skull, or cranium, is covered by the scalp. Ironically, the letters making up the word “scalp”
actually stand for the layers that compose it.
S – skin.
C – connective tissue.
A – aponeurosis.
L – loose connective tissue.
P – periosteum.
The scalp receives its blood supply from the external carotid artery, which is the reason it can bleed
profusely when lacerated.

23. Skull
The term “skull” refers not only to the bones of the cranium, but also to the bones of the facial
skeleton. The skull is said to be the most complex bony structure in the body, consisting of 22 bones that
are connected by sutures, which are immovable joints.
The eight actual cranial bones include one frontal bone, two parietal bones, two temporal
bones, one ethmoid, one sphenoid and one occipital. These eight bones form the cranial cavity, which
contains the brain. The floor of the cavity is divided into anterior, middle and posterior regions called
fossae. This page shows a lateral projection of the bones of the cranium and face.

24. Frontal Bone
The frontal bone forms the forehead and superior portions of the orbits. Housed within the
frontal bone near its midline are the frontal paranasal sinuses. These sinuses connect to the nasal cavity

©2017 ASRT. All rights reserved. CT Basics: Module 8
between the middle and inferior nasal conchae, via the middle nasal meatus. The frontal sinuses usually
are visible radiographically by the age of 7.

25. Parietal Bones
The paired parietal bones form most of the superior portion and some of the lateral aspects of
the cranium. They are located superior to the temporal bone and the posterior aspects of the sphenoid
bone.

26. Temporal Bones
The two temporal bones are inferior to the parietal bones and form part of the lateral portions
of the cranium, as well as its floor or base. Both temporal bones also have a squamous portion that
forms the inferolateral aspects of the cranium. A mastoid process is located on the posterior aspect of
each temporal bone. Extending medially from the temporal bone is its petrous portion.

27. Temporal Bones – Petrous Portion
The wedge-shaped petrous portion of the temporal bone forms part of the base of the cranium
and houses the organs of hearing. The petrous portion has three chambers: external, middle and inner.
The external structures consist of the auricle and the external auditory meatus (EAM) or canal.

28. Auditory Ossicles
The EAM conducts sound to the tympanic membrane, also known as the eardrum, which is
located in the air-filled middle ear. The middle ear, or tympanic cavity, also houses three auditory
ossicles: the incus, malleus and stapes.
The tympanic membrane amplifies and transmits sound vibrations to the auditory ossicles. The
auditory ossicles then convey the sound to the oval window of the inner ear. The inner ear, which is
filled with fluid, contains the vestibule, semicircular canals and the cochlea.

29. Vestibule
The vestibule and semicircular canals control balance and equilibrium, while the cochlea is
responsible for hearing. The vestibule is located between the semicircular canals and the cochlea. The
semicircular canals are easily identified on CT images because they have three separate passages
located at right angles to each other. The round window of the inner ear is located at the basal turn of
the cochlea. The round window allows the fluid in the inner ear to shift slightly so that sound waves can
be propagated.
This page shows the hearing organs in the coronal plane and the proper orientation of the
petrous portion of the temporal bone and its enclosed structures. The petrous portion is said to be the
densest and one of the most intricate bones in the body. Because the petrous portion of the temporal
bone houses the hearing organs, CT has become the major tool to diagnose pathological conditions
involving these structures.

30. Ethmoid
The ethmoid bone is situated between the orbits and forms most of their medial walls. A thin
piece of bone called the perpendicular plate extends from the inferior portion of the ethmoid and forms
a part of the nasal septum. The middle and superior nasal conchae are considered part of the ethmoid
bone.
The ethmoid also contains the ethmoid paranasal sinuses, which are composed of numerous air
sacs. Although newborn babies have ethmoidal air sacs, these sacs generally do not appear

©2017 ASRT. All rights reserved. CT Basics: Module 8
radiographically until around age 3. The ethmoid sinuses connect with the nasal cavity by way of the
superior and middle meatuses.

31. Sphenoid
The sphenoid bone lies at the base of the skull, anterior to the temporal bones. Many imaging
professionals describe this bone as appearing “bat-like.” In keeping with that description, the sphenoid
bone has two parts referred to as the greater and lesser wings. These wings form the anterolateral parts
of the cranium and the lateral walls of the orbits. Embedded within the central portion of the sphenoid
bone is the sella turcica, which houses the pituitary gland.

32. Sphenoid Sinus
The sphenoid sinuses are also located within the sphenoid bone. These sinuses are situated
immediately posterior to the ethmoid sinuses and nasal cavity and communicate with that cavity by way
of the sphenoethmoidal recess, which is situated superior to the superior nasal conchae.
The sphenoid is separated from the optic nerves, optic chiasm and pituitary gland by a sliver of
bone. Although small sphenoid sinuses may present in newborns, they are most radiographically
distinguishable after age 2. This page shows the sphenoid sinuses on a transverse CT image of the head.

33. Occipital Bone
The occipital bone is the most posterior of the cranial bones. It forms the posterior part of the
cranium and part of the base of the skull. The occipital bone contains a large foramen called the
foramen magnum. In addition, on either side of the inferior portion of the occipital bone, there are
condyloid processes called the occipital condyles. The occipital condyles articulate with the lateral
masses of the first cervical vertebra.

34. Practice Question

35. Practice Question

36. Facial Bones
The facial skeleton consists of 14 bones, including:
Two maxillae (the singular term is maxilla).
Two palatines.
Two zygomas.
Two nasals.
Two lacrimals.
One vomer.
Two inferior nasal conchae (the singular term is concha).
One mandible.

37. Maxillae
The maxillae join in the median sagittal plane of the head, forming what many people call the
upper jaw. The upper incisors are embedded in the lower portion of the maxillae. Each maxilla has a
horizontal part called a palatine process. These processes unite to form the roof of the mouth, also
called the hard palate.

©2017 ASRT. All rights reserved. CT Basics: Module 8
 A maxillary sinus is encased within the body of each maxilla. The maxillary sinuses connect with
the middle meatus of the nasal cavity by way of the hiatus semilunaris. The largest of the paranasal
sinuses in adults, the maxillary sinuses occupy most of each maxilla. They are normally present at birth,
but become more visible radiographically when a child approaches puberty.

38. Maxillary Sinus
The transverse CT image on this page shows the maxillary sinuses.

39. Palatine Bones
The two palatine bones are located posterior to the union of the palatine processes of the
maxilla and form the posterior aspects of the hard palate.

40. Zygomatic Bones
Two zygomatic bones, or zygomas, are located on each side of the face. These bones form the
prominence of the cheeks and the lateral borders of each orbit. The anteromedial wall of each orbit is
made up of the two rectangular lacrimal bones. Located posteriorly on each zygomatic bone is a
temporal process. These processes join with the zygomatic processes of the temporal bones to form the
zygomatic arches.

41. Inferior Nasal Conchae
We mentioned earlier that the superior and middle nasal conchae are part of the ethmoid bone.
Many medical imaging practitioners associate all of the nasal conchae with the nasal cavity because of
their location, but remember that only the inferior nasal conchae are truly part of the facial skeleton.
These scroll-shaped bones lie on either side of the median sagittal plane of the nasal cavity. Covered by
mucous membrane, the nasal conchae warm and moisten the outside air as it enters the nasal cavity.

42. Nasal Conchae
This coronal CT scan through the face shows the nasal conchae.

43. Nasal Septum
The union of the two nasal bones at the median sagittal plane forms the bridge of the nose,
while a slender, plow-shaped bone called the vomer forms the most inferior aspect of the nasal septum.

44. Mandible
The most inferior bone of the facial skeleton is the mandible. Each side of the mandible, also
called the lower jaw, has a posterior, superior portion called a ramus. The rami have superior
projections called condyles and coronoid processes. The condyles of the rami join the temporal bones to
form the only moveable joint in the skull, the temporomandibular, or TMJ, joint. The lower incisors are
imbedded within the superior portions of the mandible.

45. Practice Question

46. Practice Question

47. Brain Tissue
The cavity created by the cranial bones houses the brain. The brain weighs approximately 3
pounds, or about 2% of a person’s body weight, and is smaller in women than in men. The weight of the
brain, however, is not indicative of a person’s intellectual capacity. Rather, the brain has folds called gyri

©2017 ASRT. All rights reserved. CT Basics: Module 8
and furrows called sulci. Researchers generally believe that the more sulci and gyri a person has, the
greater his or her intellectual capacity.
The brain is composed of well-organized areas of gray and white matter. The white matter is
made up of myelinated nerve fibers. Myelin is a white fatty substance. Gray matter is composed of
unmyelinated fibers and nerve cell bodies. The nerve cells, or neurons, transmit impulses to other
neurons across a small gap called a synapse. The gray areas are regions of synapse.

48. Sulci and Gyri
The CT image on this page shows the sulci and gyri of the brain on a transverse cut through the
upper portion of the brain.

49. Gray and White Matter
Note the gray and white matter regions in this cadaver segment of the brain.

50. Meninges
Three layers of connective tissue called meninges cover the brain and separate it from the
cranial vault. The meninges also help protect the brain’s surface. The outermost layer of the meninges is
the dura mater, or simply the dura, which is made up of tough, fibrous connective tissue. The term
“dura mater” comes from “dura” meaning hard and “mater” meaning mother.

51. Dura Mater Extensions
Extensions of the dura form four inwardly projecting folds that compartmentalize the brain. The
falx cerebri is located between the cerebral hemispheres, while the falx cerebelli is found between the
cerebellar hemispheres. The tentorium cerebelli divides the cerebrum and the cerebellum, and the
diaphragma sellae forms a bridge over the sella turcica and covers the pituitary gland.

52. Falx Cerebri
The image on this page is a transverse CT scan of the cerebrum showing the falx cerebri within
the longitudinal fissure of the brain.

53. Tentorium Cerebelli
The tentorium cerebelli is shown here. Note its location between the occipital lobe and the
cerebellum.

54. Arachnoid Layer
The arachnoid layer is the middle layer of meninges. It is very thin and quite delicate, with
minute trabeculae extending from its inner surface. The trabeculae resemble a cobweb, thus the reason
for the name “arachnoid.” The arachnoid layer is separated from the innermost meningeal layer by the
subarachnoid space. This space contains cerebrospinal fluid, or CSF, and the larger blood vessels in the
brain.
There also is a space between the arachnoid membrane and the dura mater called the subtotal
space. It contains only a small amount of cerebrospinal fluid to keep the surfaces moist. When the
arachnoid layer reaches the area of the venous sinuses, numerous diverticula penetrate and project into
the dura.

55. Pia Mater
The pia mater, a thin, very vascular membrane, is the innermost layer of meninges. “Pia” means
tender, so pia mater refers to the “tender mother” layer of meninges. The pia mater adheres very

©2017 ASRT. All rights reserved. CT Basics: Module 8
closely to the contours of the brain. The pia and arachnoid membranes together are called the
leptomeninges. These two layers are very close, especially at the uppermost portions of the gyri.
The pia then separates slightly from the arachnoid to follow the dips of the sulci, while the
arachnoid forms a bridge-like structure over the top of the gyri, creating triangular-shaped spaces. These
spaces contain cerebrospinal fluid.

56. Subarachnoid Cisterns
Other spaces between the arachnoid and pia mater are called the subarachnoid cisterns.
Located near the base of the brain, they contain rather large amounts of cerebrospinal fluid.

57. Cerebellomedullary Cistern
Also called the cisterna magna, the cerebellomedullary cistern is formed when the arachnoid
layer of meninges crosses the space between medulla oblongata and the inferior surface of the
cerebellum. It receives cerebrospinal fluid from the foramen of Magendie, or median aperture of the
fourth ventricle. A procedure known as a cisternal puncture is used to sample cerebrospinal fluid from
this space when a lumbar puncture is contraindicated.

58. Pontine Cistern
The pontine cistern is located on the anterior or ventral surface of the pons. This cistern
contains the basilar artery and receives cerebrospinal fluid from the foramen of Luschka, or lateral
aperture of the fourth ventricle.

59. Pontine Cistern
Note the location of the pontine cistern anterior to the pons on this transverse CT image.

60. Cistern of the Lateral Sulcus
The cistern of the lateral sulcus is formed when the arachnoid meningeal layer crosses the gap
from the frontal to the temporal lobe. This cistern contains the middle cerebral artery.

61. Interpeduncular Cistern
The interpeduncular cistern contains the circle of Willis, or circulus arteriosus cerebri. It is
located between the paired temporal lobes of the brain.

62. Chiasmatic Cistern
The chiasmatic cistern is created by the continuation of the interpeduncular cistern anteriorly
and superiorly. This cistern is associated with the optic chiasm.

63. Cisterna Ambiens
The cisterna ambiens contains the great cerebral vein and the pineal gland. It occupies the space
between the splenium of the corpus callosum and the superior aspect of the cerebellum. This cistern
also is referred to as the cistern of the great cerebral vein, the superior cistern or the quadrigeminal
cistern.

64. Pineal Gland
The pineal gland often appears calcified on skull radiographs and cranial CT and MR images of
adults. You can see a calcified pineal gland on this CT image.

65. Cerebrospinal Fluid

©2017 ASRT. All rights reserved. CT Basics: Module 8
 The choroid plexus is a specialized vascular structure found in the lateral, third and fourth
ventricles. It produces cerebrospinal fluid as the result of filtration and secretion. The primary
constituents of CSF are water, glucose, sodium chloride and protein. Brain diseases often are diagnosed
by measuring changes in the concentration of these substances in CSF. In addition, the presence of
blood and other substances not commonly found in CSF may indicate other disease or traumatic injury.

66. Choroid Plexus
This page shows an axial CT image through the cerebral ventricles of the brain. Note the choroid
plexus within the posterior horns of the lateral ventricles.

67. Ventricles
The two lateral ventricles are located within the hemispheres of the brain. They are separated
by a thin partition at midline called the septum pellucidum. The lateral ventricles drain into the third
ventricle by way of the foramen of Monro, or interventricular foramen, and the third ventricle drains
into the fourth ventricle via the cerebral, or sylvian, aqueduct.
Cerebrospinal fluid flows into the spaces in and around the brain and spinal cord by way of two
openings in the lateral walls and a single opening in the medial wall of the fourth ventricle. The two
lateral openings are called foramina of Luschka, while the medial opening is the foramen of Magendie.

68. Brain Regions
The brain can be divided into four distinct regions: the cerebrum, diencephalon, brainstem and
the cerebellum.

69. Cerebrum
The cerebrum is the most superior and largest part of the brain. It is divided into left and right
hemispheres, which are connected by a central mass of white matter called the corpus callosum.

70. Corpus Callosum
The corpus callosum is divided into four areas: the genu, rostrum, body and splenium. The genu
of the corpus callosum is its most anterior portion, while the rostrum is located inferior and slightly
posterior to the genu. The splenium is the most posterior part of the corpus callosum. This page shows
the parts of the corpus callosum.

71. Longitudinal Fissure
The deep cleft separating the two hemispheres of the brain is called the longitudinal fissure. The
midline structures of the brain are located within this fissure, as is the extension of dura mater called
the falx cerebri. In CT, when the falx cerebri and other midline structures of the brain deviate from their
normal location, it is called “mass effect.” This axial CT image through the cerebrum shows the
longitudinal fissure.

72. Lobes of the Cerebrum
The cerebrum is divided into lobes separated by sulci. These lobes include one frontal lobe, two
parietal lobes, two temporal lobes, one occipital lobe and two lobes called the insulae, or islands of Reil.

73. Lobes of the Cerebrum
This page lists the functions of the lobes. The frontal lobe is associated with personality and
voluntary motor control; the parietal lobes are responsible for peripheral sensations; the occipital lobe

©2017 ASRT. All rights reserved. CT Basics: Module 8
controls vision; the temporal lobes manage the sense of hearing, smell and taste; and the insula directs
motor and sensory organ function.

74. Fissures and Sulci
As we mentioned earlier, the cerebral cortex is organized into folds called gyri and furrows
called sulci. There also are areas throughout the cerebrum with deeper grooves called fissures. In
addition to the longitudinal fissure discussed earlier, there is another important fissure called the sylvian
fissure, or lateral sulcus.
The sylvian fissure separates the frontal and parietal lobes from the temporal lobe. The insula is
located deep in the sylvian fissure toward the median sagittal plane of the head. This page shows the
location of the sylvian, or lateral, fissure.

75. Central Sulcus
The central sulcus is the main sulcus within the cerebrum. It separates the frontal lobe from the
parietal lobe at the precentral and postcentral gyri. The precentral gyrus is considered the brain’s motor
area, while the postcentral gyrus is thought to be the sensory area. Both of these regions can be seen on
CT and MR images. There also is a sulcus that separates the parietal lobe from the occipital lobe, aptly
named the parieto-occipital sulcus.

76. Cerebral Cortex
As we said earlier, the brain is composed of white and gray matter. Most of the gray matter is
located on the surface of the brain, or cerebral cortex, which is only about 1.5 to 5 mm thick. The white
matter is found beneath the cortex. Organized masses of gray matter called basal ganglia are
interspersed throughout the white matter.

77. Diencephalon
The diencephalon is located centrally within the cerebral hemispheres. A midline structure
surrounding the third ventricle, it is composed of the epithalamus, thalamus and hypothalamus. The
largest part of the diencephalon is the thalamus.

78. Thalamus
The thalamus is a mass of gray matter on each side of the third ventricle that creates the
ventricle’s lateral walls. It is a major relay station of the afferent, or sensory, pathway, which transmits
nerve impulses to the cerebral cortex. The epithalamus is superior to the third ventricle and forms its
roof. The pineal gland is a projection off of the epithalamus.
The hypothalamus forms the floor of the third ventricle. The infundibulum, or pituitary stalk,
optic chiasm and the mammillary bodies are located in the inferior aspect of the hypothalamus. The
mammillary bodies are involved in swallowing reflexes.

79. Pituitary Gland
The pituitary gland is considered the master gland of the body because it regulates the functions
of many other glands through the manufacture and secretion of six major hormones. The pituitary is
connected to the hypothalamus by the infundibulum, or pituitary stalk.

80. Pituitary Gland
This reformatted sagittal CT image shows the pituitary gland.

81. Brain Stem

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 The brain stem is a small mass of tissue located beneath the cerebrum. It has three major
divisions: the midbrain, pons and medulla oblongata. The smallest region is the midbrain, which is
located between the diencephalon and pons. Consisting primarily of bundles of nerve fibers, the
midbrain surrounds the cerebral aqueduct and is divided into two major parts: the quadrigeminal plate
(colliculi) and the cerebral peduncles.

82. Cerebral Peduncles
The cerebral peduncles are noticeable in cadaver sections because of a darkly pigmented
substance called substantia nigra. Substantia nigra is believed to play a major role in neuromuscular
disorders such as Parkinson disease. The substance produces dopamine, a neurotransmitter that
controls muscular reflexes. Note the cerebral peduncles on this CT image.

83. Pons
The oval-shaped pons is a band of fibers located between the midbrain and medulla oblongata
and posterior to the fourth ventricle. Fibers from the pons extend from the cerebellum to other areas in
the brain, but most connect the two cerebellar hemispheres. The basilar artery travels over the anterior
surface of the pons. The sagittal anatomical model shows the pons in midline. The axial CT demonstrates
the location of the pons in transverse section.

84. Medulla Oblongata
The medulla oblongata is a conical structure located beneath the pons. Extending from the pons
to the foramen magnum, the medulla oblongata is composed of fiber tracts that breach the area
between the brain and spinal cord.
It also contains so-called “vital centers” for the regulation of the body activities such as heart
rate, respiratory rhythm and blood pressure. The median fissure is located on the anterior surface of
medulla oblongata. On either side of the median fissure are small nodule-like structures called pyramids.

85. Cerebellum
The cerebellum is located within the posterior cranial fossa and is situated posterior to the pons
and medulla oblongata. The two cerebellar hemispheres are connected by a central structure called the
cerebellar vermis. The cerebellar vermis is said to resemble a coiled-up worm. In fact, the term “vermis”
is derived from the Latin word “verm,” meaning worm.
As with the cerebrum, the cerebellum is covered with a layer of gray matter called the cerebellar
cortex. White matter lies deep within the cortex. Two round, prominent bulges called cerebellar tonsils
are located on the inferior surface of the cerebellum. The cerebellum is responsible for controlling
muscle tone and coordinating muscular activity.

86. Practice Question

87. Practice Question

88. Cranial Nerves
The brain has 12 pairs of cranial nerves. All except the first and second pair emerge from the
brainstem. They pass through foramina located within the skull and transmit nerve impulses to
structures in the head, neck and viscera of the body. The cranial nerves are named and numbered in the
order that they appear on the inferior surface of the brain. Roman numerals are used as the numbering
format.

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89. Cranial Nerves
Some of the cranial nerves, such as the olfactory (I), optic (II), trigeminal (V) and
vestibulocochlear nerves(VIII), register smell, sight, hearing or equilibrium, bringing information from
the sensory organs to the brain. The trigeminal nerve also controls sensations in the face, scalp and
teeth, and contraction of chewing muscles. Other cranial nerves control muscles.
For example, the oculomotor (III), trochlear (IV) and abducens nerves (VI) are associated with
various eye movements. The accessory nerve (XI) controls the neck and shoulder muscles, while the
hypoglossal nerve (XII) controls the movement of the tongue.
A few the cranial nerves have mixed functions. The mandibular branch of the trigeminal nerve
not only registers sensations in the jaw, tongue, lower lip and teeth, but also controls the movement of
the chewing muscles. The facial nerve (VII)transmits the sense of taste, directs the contraction of facial
and swallowing muscles and controls secretions of the lacrimal and submaxillary glands; the
glossopharyngeal nerve (IX) also transmits the sense of taste and manages parotid gland secretions. The
vagus nerve (X) carries impulses far beyond the head to the larynx, heart, stomach and intestines, and
the bronchial tubes.

90. Cranial Nerves
Of all of the cranial nerves the trigeminal (V) is the largest. The vagus (X) has the widest
distribution, carrying and receiving impulses to help regulate heart rate, blood pressure, digestive
secretions and respiration.

91. Arteries of the Brain
The paired internal carotid and vertebral arteries supply blood to the brain. The internal carotid
arteries begin where the common carotid arteries in the neck divide into external and internal branches.
The external carotid arteries extend to supply the face and scalp. The internal carotid arteries ascend to
the base of the skull where they enter the carotid canals of the temporal bone. They then travel
anteriorly within the cavernous sinus and superiorly and posteriorly through the dura mater.

92. Cerebral Arteries
The image on this page is an axial CT scan showing a contrast-enhanced circle of Willis. The
internal carotids form the middle and the anterior cerebral arteries. The middle cerebral arteries supply
blood to the lateral portions of the cerebrum and divide into numerous branches that travel within the
sylvian fissure. The anterior cerebral arteries and their branches pass through the genu of the corpus
callosum to supply the anterior portion of the frontal lobe and the medial portions of the cerebral
hemispheres.
The short midline anterior communicating artery unites the two anterior cerebral arteries.
These arteries supply blood to the orbital contents, and the frontal, parietal and temporal lobes of the
brain. An additional branch of the internal carotid arteries travels posteriorly to join the posterior
cerebral arteries. In essence, the internal carotid arteries form the anterior portion of the circle of Willis.
The middle cerebral arteries are not considered a part of the circle.

93. Vertebral Arteries
The right and left vertebral arteries are branches of the subclavian arteries. They ascend
vertically within the transverse foramina located in the transverse processes of the cervical vertebrae,
beginning at C6. The arteries pass through the foramen magnum, pierce the dura mater and enter the
cerebellomedullary cistern. The two vertebral arteries join to form basilar artery.

94. Basilar Artery

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 The basilar artery travels over the anterior surface of pons, after which it bifurcates into the two
posterior cerebral arteries. The posterior cerebral arteries supply blood to the occipital lobe of the brain.
These vessels form a configuration called the circle of Willis, or circulus arteriosus cerebri. The circle of
Willis is located in the interpeduncular cistern and encloses the optic chiasm and the infundibulum.
The basilar artery is the site of the most common aneurysm found in the brain — the berry
aneurysm. The axial CT scan on this page shows a contrast-enhanced basilar artery on the ventral
surface of the pons.

95. Basilar Artery
On this reformatted sagittal CT image, you can see a contrast-enhanced basilar artery on the
anterior surface of the pons.

96. Circle of Willis (C.O.W.)
The image on this page is an axial CT scan showing a contrast-enhanced circle of Willis.

97. Venous System
Just as in other areas of the body, arteries carry blood to the brain and veins drain the blood
away. However, the venous system of the brain is somewhat different from normal veins in the body.
The brain’s venous system is primarily composed of the dural, or venous, sinuses, superficial cortical
veins and the deep veins of the cerebrum.
All the veins of the head drain into the dural sinuses, which in turn empty into the internal
jugular veins. While the other veins in the body have valves to keep the blood flowing in the correct
direction, the dural sinuses do not.

98. Dural Sinuses
The dural sinuses include superior and inferior sagittal, straight, transverse, sigmoid, cavernous
and petrosal parts.

99. Superior Sagittal Sinus
The superior sagittal sinus is located in the median plane between the falx cerebri and the
calvarium, or cranial bones. Beginning at the crista galli, it runs the entire length of the falx and ends at
the occipital protuberance. The superior sagittal sinus often appears as a triangular-shaped structure at
the superior and inferior portions of CT and MR images of the head. Note the superior sagittal sinus
anteriorly and posteriorly on this axial CT image of the head.

100. Inferior Sagittal Sinus
The inferior sagittal sinus, which is much smaller than the superior sagittal sinus, extends
posteriorly, immediately beneath the free edge of the falx cerebri. The inferior sagittal sinus joins the
great vein of Galen (the great cerebral vein) to form the straight sinus. The straight sinus travels along
tentorium cerebelli until it reaches the occipital protuberance, where it continues as the lateral sinus.
Although the lateral sinuses are continuations of the straight sinus or superior sagittal sinus,
they usually form a common area at their origin called the confluence of sinuses. The confluence of
sinuses is located at the level of the occipital protuberance. The lateral sinuses branch into transverse
and sigmoid sinuses.

101. Sigmoid Sinus

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 The sigmoid sinus is a continuation of the transverse sinus. The sigmoid sinus follows an S-
shaped path that loops over the petrous and mastoid portions of the jugular foramen, where it
continues as the internal jugular vein.

102. Cavernous Sinus
A large venous sinus called the cavernous sinus is located on each side of the body of the sella
turcica. The cavernous sinus receives venous blood from the ophthalmic and middle cerebral veins and
is drained by the small petrosal sinuses that empty into the sigmoid sinus or jugular vein. The cavernous
sinus not only contains venous structures, but the internal carotid artery also enters the sinus via the
foramen lacerum, turns sharply and exits the sinus to enter the subarachnoid space.
You can see the internal carotid arteries within the cavernous sinus on this coronal CT image.
The abducens cranial nerve (VI) is closely related to the internal carotid artery as it travels through the
cavernous sinus. From superior to inferior, the oculomotor (III) and trochlear (IV) nerves, and the
ophthalmic and maxillary divisions of the trigeminal nerve (V) also are associated with the cavernous
sinus.

103. Practice Question

104. Practice Question

105. Structures Within the Facial Skeleton
Several nonosseous structures are located within the skeletal bones of the face. In this portion
of the module, we will focus on the orbits and their contents, and structures posterior to the oral and
nasal cavities. In addition, we will discuss the salivary glands.

106. Orbits
The bony orbit is described as pyramid shaped. Its apex is the most posterior aspect, the base its
most anterior aspect and its walls are shaped like triangles. The medial walls are formed by the lacrimal
bone and the orbital plates of the ethmoid and palatine bones. The lateral walls are formed by the
zygomatic bones and the greater wings of the sphenoid bone.
The orbital plates of the frontal bone make up the roof of each orbit, while the floor is formed
by the maxillae and a small portion of zygomatic bones. This image shows the bony orbits. You can see
their position within the facial skeleton and the anatomical contributions of the bones that form the
orbits.

107. Organs of Sight
The orbits contain the organs responsible for vision. The primary organs of sight are the bulbus
oculi, which are commonly known as the eyeballs. Each eyeball is roughly spherical in shape and 2 to 3
cm in diameter. The walls of the eyeball are composed of three layers called tunics: the external or
fibrous layer, middle or vascular layer and innermost or retinal layer.

108. Bulbus Oculi
Each bulbus oculi has several parts. You can see the bulbus oculi and the lens of the eye
distinctly on this axial CT scan through the orbits. The optic nerves also are visible. The ganglion cells of
each eyeball join to form the optic nerve. The optic nerve emerges from the eye posterior to the optic
disc, which is located in the center of the posterior aspect of bulbus oculi.

©2017 ASRT. All rights reserved. CT Basics: Module 8
 The optic nerves continue posteriorly until they cross at the optic chiasm, or area of
decussation. From the area of decussation, the optic nerves continue through the brain until they reach
the occipital lobe, which is the visual cortex and is responsible for sight.

109. Eye Muscles
The eye moves using six muscles that are inserted in the sclera. These muscles are the medial,
lateral, superior and inferior rectus, and the superior and inferior obliques. You can see the eye muscles
and the optical disc on this coronal CT image. In some cases, the ophthalmic artery can be seen on a
diagonal course through this same section, and is sometimes mistaken for one of the extraocular
muscles.

110. Salivary Glands
Three pairs of salivary glands are found in the lower portion of the facial skeleton: the parotid,
submandibular and sublingual. Although considered part of the digestive system or gastrointestinal
tract, these glands are located in the facial skeleton. They are responsible for secreting fluid that
moistens food. The secretions contribute to the taste of food and aid in swallowing. In addition, the
salivary glands produce amylase, a substance that begins carbohydrate digestion.

111. Parotid Glands
The parotid glands are the largest and most superiorly situated of the salivary glands. These
glands are positioned between the mastoid portion of the temporal bone and the ramus of the
mandible. They can be palpated by placing the index and middle fingers just anterior and inferior to the
ear lobe.
The major duct of the parotid gland is the Stensen duct. This duct communicates with the oral
cavity through an opening in the mouth near the upper second molar. Note the parotid glands on this
axial CT image.

112. Submandibular Glands
The submandibular glands are sometimes referred to as the submaxillary glands. This gland can
be palpated as a small lump medial to the body and angle of the mandible. Its major duct, the Wharton
duct, opens into the oral cavity near the frenulum of the tongue. This reformatted coronal CT image of
the face shows the submaxillary glands.

113. Sublingual Glands
The smallest and most deeply located of the salivary glands are the sublingual glands. These
glands are found in the floor of the mouth beneath the mucous membrane of the oral cavity. United
anteriorly at the frenulum of the tongue, the two sublingual glands open into the oral cavity via a larger
duct called the Bartholin duct and several smaller ducts referred to as the Rivinus ducts.
On occasion, the sublingual glands may open into the Wharton duct, the major duct of the
submandibular glands. This coronal CT image of the face shows the sublingual glands.

114. Pharynx
The pharynx extends from the base of the skull to the sixth cervical vertebra. Therefore, it is
considered one of the structures within the facial skeleton, but it also continues into the neck. The
pharynx is about 12 cm long, with walls composed of mucous membrane covered by overlapping
constrictor muscles. The pharynx is divided into three parts: nasal, oral and laryngeal.

©2017 ASRT. All rights reserved. CT Basics: Module 8
115. Pharynx
The nasal portion of the pharynx, appropriately termed the nasopharynx, is located posterior to
the nasal cavity, extending from the base of the skull to the soft palate. It is an open space that
communicates with the nasal cavity through the choanae. The eustachian tubes from the ears open into
the nasopharynx from the lateral walls. An aggregation of lymphoid tissue known as the pharyngeal
tonsil can be found within the posterior wall of the nasopharynx.
The oropharynx, or oral portion, is located posterior to the mouth. The oropharynx begins at the
soft palate and extends inferiorly to the tip of the epiglottis. The lateral walls of the oropharynx are lined
with lymphoid tissue called the palatine tonsils, commonly referred to as just the tonsils. The lingual
tonsils, another aggregation of lymphoid tissue, are located in the anterior walls of the oropharynx.
The laryngopharynx, or laryngeal portion, begins at the superior border of the epiglottis and
travels inferiorly to the cricoid cartilage. The cricoid cartilage is located at the union of the larynx and
the trachea at the C6 vertebral level. The walls of the laryngopharynx extend laterally around the
opening to the larynx, forming the piriform recesses.
A space, known as the retropharyngeal space, is located between the cervical vertebrae and the
musculature and the fascia surrounding the pharynx. The space is filled with loose connective tissue that
allows movement of the esophagus, larynx, pharynx and trachea. This movement is necessary for
swallowing. The retropharyngeal space is closed to the skull superiorly but opens into the thoracic cavity
inferiorly. The opening allows infections in the space to move directly into the mediastinum. The
pharynx extends the length of the neck before becoming the esophagus at the sixth cervical vertebra.

116. Practice Question

117. Practice Question

118. The Neck
The region of the body referred to as the neck is located between the thorax and head. Seven
cervical vertebrae, the skeletal components of the neck, support the cranium. The neck also contains
structures that pass from the head into the thorax and the abdominal cavity.

119. Cervical Vertebrae
The cervical vertebrae are convex anteriorly. Although similar to the other vertebrae, cervical
vertebrae have some interesting and unique characteristics. The first cervical vertebra, or C1, is also
called the atlas. It is an oval, ring-like structure that does not have a body or spinous process. The lateral
aspects of the atlas include lateral masses with indented articular facets.
The lateral condyles of the occipital bone fit into these indentations. This articulation, which
supports the cranial and facial skeleton, allows the back-and-forth movement of the skull when we nod
yes. The atlas also has inferior facets or processes that articulate with the second cervical vertebra.

120. Atlas
This axial CT scan shows the atlas. The parts of this particular vertebra are labeled on the image.

121. Axis
The second cervical vertebra, called the axis, is unique among other vertebrae in that it has a
superiorly projecting process called the odontoid process, or dens. The dens projects through the
vertebral foramen of the atlas.

©2017 ASRT. All rights reserved. CT Basics: Module 8
 Along with muscular support, this articulation allows the pivot-like motion of the skull when we
shake our heads side to side. Notice the lateral portions of the atlas (C1) and the odontoid process of the
axis (C2) on this coronal CT scan through the neck.

122. Dens
This axial CT image shows the dens of the axis (C2) projecting through the atlas (C1).
123. Transverse Foramina
One of the most distinctive characteristics of the cervical vertebrae is that they have holes
within their transverse processes. These holes, or transverse foramina, provide a passageway for the
vertebral arteries and other essential structures.

124. Spinous Process
The spinous processes of the cervical vertebrae also are unique, in that, when present, they
have bifid tips, meaning that they are forked in appearance. Sometimes the spinous process is not bifid,
but is long and pointed. This configuration allows the seventh cervical vertebra at the base of the neck
to be palpated easily. C7 often is referred to as the “vertebra prominens.” The bifid process of a cervical
vertebra is shown on this axial CT scan through the neck.

125. Vertebral Prominens
The vertebra prominens (C7) is shown on this reformatted sagittal CT image.

126. Neck Muscles
In addition to the cervical vertebrae, muscles provide additional support for the structures of
the neck. Neck muscles usually are divided into anterior and posterior triangles. The triangles are further
described as being located anterior or posterior to the sternocleidomastoid muscle. Extending from the
sagittal plane of the neck to the anterior border of the sternocleidomastoid muscle, the muscles of the
anterior triangle also help form the floor of the mouth.
The base of the anterior triangle is formed by the lower border of the mandible, while its apex is
the manubrium of the sternum. All of the muscles of the anterior triangle are attached to the hyoid
bone. This axial CT image shows the major muscles of the anterior triangle.
Just as the neck muscles are divided into two groups, the muscles of the anterior triangles also
are described as either infrahyoid or suprahyoid. As the name suggests, the infrahyoid muscles are
inferior to the hyoid bone. These muscles pull the hyoid bone and larynx inferiorly during swallowing,
and return them to their normal position afterward.
The infrahyoid muscles include the omohyoid, sternohyoid, sternothyroid and thyrohyoid. The
suprahyoid muscles are superior to the hyoid bone. This muscle group includes the digastric, geniohyoid,
mylohyoid and stylohyoid. These muscles elevate the hyoid bone during swallowing, or if the hyoid bone
doesn’t move, the muscles open the temporomandibular articulations.

127. Carotid Sheath
The anterior triangle muscles of the neck are interesting in that they contain the carotid sheath.
Remember that the carotid sheath is composed of a carotid artery, either common or internal
depending on the level; the internal jugular vein; and vagus nerve.

128. Posterior Triangle
The posterior triangle muscles are located posterior to the sternocleidomastoid muscle and
extend from its posterior border to the trapezius muscle. The base of the triangle is made up of several

©2017 ASRT. All rights reserved. CT Basics: Module 8
muscles, including the levator scapulae; anterior, middle and posterior scalenes; and the splenius
capitis.
The apex of the posterior triangle is formed by the junction of the sternocleidomastoid and the
trapezius. Notice the association of the selected muscles with the sternocleidomastoid and trapezius
muscles.

129. Organs of the Neck
Although some organs belong strictly to the neck such as the thyroid and parathyroid glands,
other organs are continuations of structures located within the cranium and face, such as the pharynx.
Remember that the pharynx actually originates posterior to the nasal cavity and continues inferiorly as
the oropharynx and laryngopharynx, ultimately transitioning into the esophagus at C6.

130. Larynx
Essentially an air passageway, the larynx also functions as the major organ of voice production.
The larynx normally begins at the level of third cervical vertebra (C3) in men; in women and children, the
organ is normally positioned more superior to C3. The larynx culminates at the level of C6. The organ is
made up of nine cartilages connected by ligaments, which compose its skeleton. Some of the cartilages
are paired, while others are unpaired.
The arytenoid, corniculate and cuniculate cartilages are paired, while the thyroid, cricoid and
epiglottic cartilages are unpaired. Of these, the arytenoids, thyroid and cricoid are considered hyaline
cartilages, which can calcify later in life. The others are considered elastic in nature.

131. Thyroid Cartilage
The largest of the cartilages, the thyroid cartilage, forms the anterior wall of the larynx. Most
often, the thyroid cartilage is simply referred to as the Adam’s apple. This sagittal CT reformation of the
neck shows the opening into the larynx.

132. Thyroid Gland
One of the other organs within the neck region is the thyroid gland. The thyroid gland is the
largest endocrine gland in the body. The gland is composed of two lobes connected by the thyroid
isthmus. The isthmus passes across the second and third rings of the trachea. The lobes of the gland are
situated lateral to the inferior part of the larynx and the superior part of the trachea. The lobes also
relate to the esophagus on their posterior aspects.

133. Thyroid Gland
The thyroid gland is responsible for the production of vital hormones that regulate normal
growth and metabolism. The gland requires the mineral iodine to synthesize some of these hormones.
Two parathyroid glands are situated in the posterior and inferior portions of each thyroid lobe. They
generally are embedded within the lobar tissue. This axial CT scan through the thyroid gland shows both
the lobes and the isthmus.

134. Major Arteries
There is a strong vascular system in the neck region that includes both major and minor arteries
and veins. Let’s talk about the major arteries first, starting with the vertebrals, since they were discussed
briefly earlier in the module. The left and right vertebral arteries originate at their respective subclavian
arteries. The vertebrals ascend through the neck, enclosed by the transverse foramina of C6 to C1.
Notice the location of the vertebral arteries within the transverse foramina of the cervical vertebrae.

©2017 ASRT. All rights reserved. CT Basics: Module 8
135. Vertebral Arteries
This sagittal CT reformation shows the vertebral artery within the transverse foramina of the
cervical vertebrae. After exiting the transverse foramina at C1, the vertebral arteries travel through the
foramen magnum, traverse the dura mater and arachnoid meninges and enter the subarachnoid space
within the cerebellomedullary cistern.
When they reach the inferior aspect of the pons, the vertebral arteries join to form a single
artery called the basilar artery. As mentioned earlier, the basilar artery passes over the anterior surface
of pons, and forms the posterior portion of the circle of Willis.

136. Basilar Artery
The sagittal CT reformation of the neck on the left shows the basilar artery on the anterior
surface of the pons. The axial CT image on the right shows the basilar artery in the interpeduncular
cistern.

137. Carotid Artery
The next major artery found in the neck is the carotid. The right common carotid artery begins
as a branch off the brachiocephalic artery posterior to the sternoclavicular articulation. The left common
carotid artery branches directly off of the aortic arch. Both common carotids ascend the neck in what is
called the carotid sheath.

138. Carotid Artery
Note the location of the carotid artery within the carotid sheath on this contrast-enhanced axial
CT image of the neck. The carotid artery is medial to the larger of the vascular structures shown here.
The lateral vessel is a jugular vein.

139. Carotid Artery
You can see the carotid arteries on this contrast-enhanced reformatted coronal CT image of the
neck.

140. Carotid Sinus
The common carotid arteries ascend the neck until they reach the superior border of the thyroid
cartilage, where they divide into the internal and external carotid arteries. The common and internal
carotid arteries are dilated at that division. The dilation is known as the carotid sinus, and it contains
receptors that regulate blood pressure.

141. Major Veins
The major venous structures of the neck are the internal and external jugular veins. You might
remember that the dural or venous sinuses drain blood away from the head. These sinuses empty into a
common sinus, the sigmoid sinus. The sigmoid sinus then drains blood into the internal jugular veins. As
they travel inferiorly, the internal jugular veins pass posterior to the sternocleidomastoid muscles.
The veins then turn anteriorly to a point posterior to the sternal end of the clavicle, where they
connect to the subclavian veins and then form the brachiocephalic veins. The internal jugular veins are
the largest vascular structures of the neck region. In most people, the right internal jugular is larger than
the left. The external jugular veins have two major branches: anterior and posterior.
The external jugulars receive blood from structures in the face, neck and scalp, and the contents
empty into the appropriate subclavian vein, which then form the brachiocephalic veins. These veins then
drain into the superior vena cava.

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142. Jugular veins
You can see the jugular veins on this reformatted coronal CT image of the neck.

143. Conclusion
This concludes CT Basics Module 8 – Cross-sectional Anatomy of the Head and Neck. You should
now be able to:
Name and describe the anatomical planes of the body.
List and define directional terminology related to the body.
Describe human embryo development.
Name the major structures of the head and neck discussed in this module.
Describe the function of each anatomical structure discussed in this module.
Locate specific organs or structures on a schematic or CT image.
Identify the anatomical plane in which cross-sectional images were either acquired or
reformatted.
Recall the structures of the human vascular system.
Name the 12 cranial nerves, their distribution and function.
Identify selected muscular structures.

144. Bibliography
Applegate E. The Sectional Anatomy Learning System: Concepts. 2nd ed. Philadelphia, PA: WB
Saunders; 2002.

Hofer. CT Teaching Manual: A Systematic Approach. 3rd ed. New York, NY; Thieme Publishers;
2007.

Kelley L, Petersen C. Sectional Anatomy for Imaging Professionals. 2nd ed. St Louis, MO: Mosby
Publishers; 2007.

Madden M. Introduction to Sectional Anatomy. 2nd ed. Philadelphia, PA: Lippincott, Williams &
Wilkins; 2008.

145. Development Team

146. Final Slide

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