Snell's Clinical Anatomy Chapter 5 - Thorax. Part II (Thoracic Cavity) PDF

Summary

This document details the anatomy of the thorax, specifically focusing on the thoracic cavity. It describes the major structures, including the mediastinum, pleurae, lungs, and elements of the cardiovascular and respiratory systems. The chapter outlines key anatomical features and their relationships.

Full Transcript

54-year-old woman visited ~e emergency department The severe nature of the pain and its radiation to the back

A with a complaint of a sudden excruciating knifelike pain
in the front of her chest During the course of examina-
tion, she said she could also feel the pain in her back between
made a preliminary diagnosis of aortic dissection a strong
possibility. Myocardial infarction commonly results in referred
pain down the inner side of the arm or up into the neck.
the shoulder blades. On dose questioning, she said she felt Pain impulses originating in a diseased descending tho-
no pain down the arms or in the nec:k.. Her blood pressure was racic aorta pass to the central nervous system along the
200/110 mm Hg in ~e right arm and 120/80 mm Hg in the left path of sympathetic nerves and are then referred along the
arm. somatic spinal nerves to the skin of the anterior and posterior
The evaluation of chest pain is one of the most common chest walls. In this patient, the aortic dissection had partially
problems facing an emergency physician. The cause can blocked the origin of the left subclavian artery, which would
vary from ~e simple to one of life-threatening proportions. explain the lower blood pressure recorded in the left arm.

CHAPTER OUTLINE
Overview Serous Pericardium Thoracic Duct
Osteology Perlcardlal Sinuses Right Lymphatic Duct
Thorade Cavity Nerve Supply
Thorade Nerves
Mecllasdnum Heart Vagus Nerves
Superior Medtastlnwn Orlentatlon Phrenic Nerves
Inferior Medlastlnum Heart Structure Sympathetic Trunks
Heart Nerve Supply
Pleurae Heart Arterial Supply Eeophagus
Layers and Cavity Heart Venous Drainage Blood Supply
Nerve Supply Heart Action Lymph Drainage
Nerve Supply
Lower Respiratory Tract Large Thorade Arteries
Trachea Aorta Thymus
Broncht Pulmonary Trunk Blood Supply

Lungs Large Thorade Veins Radlograpblc Anatomy
Lobes and Fissures Brachtocephallc Veins Posteroantertor Radiograph
Bronchopubnonary Segments Superior Vena Cava Right Oblique Radlograph
Blood Supply Azygos Veins Left Oblique Radlograph
Lymph Drainage Inferior Vena Cava Bronchography and Contrast
Nerve Supply Pulmonary Veins Visualization of the Esophagus
Mechanics of Respiration Coronary Angiography
lboractc Lymphattcs Computed Tomography Scanning
Pericardium Thoracic Wall
Fibrous Pericardium Medlastinum

218
 Overview 219

LEARNING OBJECTIVES
The purpose of this chapter is to review the basic anatomy 7. Describe the gross structure of the heart,
of the thoracic cavity in order to understand normal including the fibrous cardiac skeleton.
ftmctional relationships and the basis for common injuries, 8. Trace the course of blood flow through the
pain, motor deficits, congenital defects, medical imaging, right and left sides of the heart. Identify
and general surface examination. the internal structures of each chamber and
the location and structure of each of the
1. Identify the major subdivisions of the thoracic valves.
cavity and describe their contents. Identify the 9. Identify the elementary sounds of the normal
subdivisions of the mediastinum and describe heart. Relate these to the flow of blood
their contents. through the heart and the actions of the cardiac
2. Identify the major longitudinal structures valves.
(e.g., trachea, esophagus, vagus nerves, phrenic 10. Identify the anatomical and auscultation
nerves, aorta, sympathetic networks, azygous proJections of each of the cardiac valves onto the
system, thoracic duct) running through the body surface.
thoracic cavity, and describe their courses and 11. Trace the low of blood through each of the maJor
relationships. coronary vessels. Identify which vessels supply
3. Identify the parietal and visceral pleurae, their the main Oow to and drainage from each of the
different components, the pleural recesses, and chambers and the lnterventrlcular septum and
the boundaries of the pleura in projection onto possible anastomoses and collateral vascular
the body surface. pathways.
4. Identify and differentiate the right and left lungs, 12. Describe the conducting system and extrinsic
including their lobes and fissures. Identify the Innervation of the heart.
impressions made on the surfaces of each lung by 13. Trace the low of blood from the thoracic
the major surrounding structures. walls and cavity to the heart by describing
5. Identify the primary, secondary, and tertiary the formation and courses of the caval and
branches of the bronchial tree. Identify the azygos venous tracts. Indicate anastomoses and
bronchi and the pulmonary arteries and collateral connections between these and other
veins at the hilar surface of each lung. Define tracts and discuss the clinical significance of
a bronchopulmonary segment and relate such connections.
such segmentation to the organization of the 14. Trace the primary drainage routes of lymph from
bronchial and vascular trees. the organs and walls of the thoracic cavity to the
6. Identify the parietal and visceral pericardia, points of venous connection.
their relationship to the parietal pleurae and 15. Identify the major structures of the thorax In
diaphragm, and their projections onto the body standard medical Imaging.
surface.

OVERVIEW Osteology
The thoracic cage and the diaphragm bound the The thoracic skeleton forms an osseocartllaginous,
thoracic cavity. However, the thoracic cavity Is much cageltke unit that encloses the thoracic cavity and
smaller than the limits of the thoracic cage because surrounds and protects the contained heart, lungs,
the diaphragm. deeply lnvaginates the lower margins and adnexa. It also covers all or parts of the upper
of the thoracic cage. Also, the cavity extends upward abdominal organs (e.g., liver, stomach, spleen, kJdneys).
Into the root of the neck about one fingerbreadth above The thoracic cage is a component of the axial skeleton
the clavicle on each side (see Fig. 5.5). The diaphragm and is formed by the sternum, ribs, costal cartllages,
ls the only structure (apart from the pleura and the and thoracic vertebrae. Details of the thoracic skeleton
peritoneum) that separates the thoracic from abdomi- are provided in Chapters 2 (vertebrae) and 4 (sternum,
nal viscera. ribs, and costal cartilages).
220 CHAPTER 5 Thorax, Part II: Thoracic Cavity

Thoracic Cavity The mediasttnwn Is divided into superior and hafe..
The thoracic cavity can be divided into a median dor mecllaltfna by an imaginary plane passing from the
partition, called the meclludnum, and the laterally sternal angle anteriorly to the lower border of the body
placed pleurae and lungs {Figs. 5.1to5.3). Athin, serous of the fourth thoracic vertebra posteriorly (see Fig. 5.2).
pleural membrane covers each lung, passes from each This plane is a noteworthy landmark In that It marks
lung at Its root (I.e., where the main air passages and several key structures. From anterior to posterior, these
blood vessels enter}, and continues onto the Inner sur- are the:
face of the thoracic wall {Fig. 5.4). This arrangement of Joint between the manubrlum and body of the
the pleura forms two independent membranous sacs sternum
called the pleural cavlliea. one on each side of the tho- Second costostemal joint
rax, between the lungs and the thoracic walls. Demarcation between the ascending aorta and the
arch of the aorta
Demarcation between the arch of the aorta and the
MEDIASTINUM descending thoracic aorta
The mediastinum is the area between the sternum, Bifurcation of the trachea
the two pleural cavities, and the vertebral column Level of the left primary bronchus
{Figs. 5.1 and 5.3). Though thick, it is a movable T4 intervertebral disc
partition that extends superiorly to the thoracic out- The inferior mediastinum is further subdivided
let and the root of the neck and inferiorly to the into the middle medludnnm, which consists of
diaphragm. It extends anteriorly to the sternum and the pericardium and heart; the anterior medlud-
posteriorly to the vertebral column. It contains the num, which ls a space between the pericardium and
remains of the thymus, the heart and large blood ves- the sternum; and the posterior mecllastlnum, which
sels, the trachea and esophagus, the thoracic duct and lies between the pericardium and the vertebral
lymph nodes, the vagus and phrenic nerves, and the column.
sympathetic trunks.

Right lung,
upper lobe-..._

Left oblique
ftssure
Right oblique
fissure

Right lung,~
lower lobe
· Visceral pleura

Pleural space

Figure 5.1 Cross section of the thorax at the level of the eighth thoracic vertebra. Note the arrangement of the pleura
and pleural cavity (space) and the fibrous and the serous pericardia. Recall that cross sections are normally viewed from
below and that the observer's right is the subject's left.
 Mediastinum 221

Superior
mediastinum

Middle
medlastfnum Inferior
m&dlaslfnum
Xlphok:I
process

Figure 5.2 Subdivisions of the medi&$tinum.
Thoracic
wall
For purposes of orientation, it is convenient to
remember that the major mediastinal structures
are arranged in the following order from anterior to
posterior.

Figure 5.4 Formation of the lungs. Note that each lung
bud invaginates the wall of the c:oelomic cavity and then
grows to fill a greater part of the cavity. Note also that the
lung is covered with visceral pleura and the thoracic: wall
is lined with parietal pleura. The original coelomic: cavity
is reduced to a slitlike space called the pleural cavity as a
result of the growth of the lung.

Costa! pleura
(parletal pleura) Superior Mediastinum
(1) Thymus, (2) large veins, (3) large arteries, (4)
trachea. (5) esophagus and thoracic duct, and (6) sym-
pathetic trunks.
The superior mediastlnwn ls bounded in front by the
manubrlum sterni and behind by the first four thoracic
vertebrae (see Flg. 5.2).

Inferior Mediastinum
/ (1) Thymus, (2) heart within the pericardium with the
Dlaphragmalfc pleura phrenic nerves on each side, (3) esophagus and thoracic
(parietal pleura)
duct, (4) descending aorta, and (5) sympathetic trunks.
The inferior mediastinum is bounded in front by the
Figure 5.3 Pleurae from above and in front. Note the body of the sternum and behind by the lower eight tho-
position of the mediastinum and the hilum of each lung. racic vertebrae (see Fig. 5.2).
222 CHAPTER 5 Thorax, Part II: Thoracic Cavity

rO Clinical Notes
Deflection of the Mediastinum Mediastinal Tumors or Cysts
In the cadaver, the medla.stinum is an inflexible, fixed Because many vital structures are crowded together
structure because of the hardening effect of the preserving within the mediastinum, their functions can be interfered
fluids. However, ln the living, lt ls very mobile; the lwtgs, with by an enlarging tumor or organ. A tumor of the
heart, and large arteries are in rhytlunlc pulsation, and the left lung can rapidly spread to involve the mediastlnal
esophagus distends as each bolus of food passes through it. lymph nodes, which on enlargement may compress
H air enters the pleural cavity (a condition called the left recurrent laryngeal nerve, producing paralysis
pneumothoru), the lung on that side immediately collapses of the left vocal fold. An expanding cyst or tumor can
and the mediastinum is displaced to the opposite side. This partially occlude the superior vena cava, causing severe
condltlon reveals itself by the patient being breathless and congestion of the veins of the upper part of the body.
In a state of shock; on examination, the trachea and the Other pressure effects can be seen on the sympathetic
heart are displaced to the opposite side. trunks, phrenlc nerves, and sometimes the trachea, main
bronchi, and esophagus.
Mediastinitis
Mediastinoscopy
The structures that make up themediastinum are embedded
In loose connective tissue that ls continuous with that of Medlastlnoscopy ls a dlagnostlc procedure whereby
the root of the neck Thus, It Is possible for a deep infection speclmens of tracheobronchlal lymph nodes are obtained
of the neck to spread readily Into the thorax, producing a without opening the pleural cavities. A small Incision is
medlastlnitls. Penetrating wounds of the chest involving made in the mldHne in the neck just above the suprasternal
the esophagus may produce a mediastinitis. ln esophageal notch, and the superior mediastinum is explored down to
perforations, air escapes Into the connective tissue spaces the region of the bifurcation of the trachea. The procedure
and ascends beneath the fascia to the root of the neck, can be used to determine the diagnosis and degree of
producing IUbcutmeou emph}9e11Ml. spread of carcinoma of the bronchus.

PLEURAE and the larger thoracic cavity.) The pleural cavity
normally contains only a small amount of tissue fluid,
The paired pleurae and lungs lie on either side of the the pleural fluid. Pleural fluid covers the surfaces of
medlastlnum. within the thoracic cavity (see Fig. 5.3). the pleura as a thin film, which causes surface ten-
Each pleural membrane has two parts: a parletal layer sion adhesion of the pleural layers and permits them
and a visceral layer. The parietal layer lines the tho- to move on each other with minimal friction. Thus,
racic wall, covers the thoracic surface of the diaphragm the pleural cavity is a potential space under normal
and the lateral aspect of the mediastlnum, and extends conditions and Is discernible only under abnormal
into the root of the neck to Une the undersurface of conditions (e.g., when the lung is displaced by air or
the suprapleural membrane at the thoracic outlet. The excess nuld).
visceral layer completely covers the outer surface of For purposes of description, the parietal pleura
the lung and extends into the depths of the interlobar ls dlvlded according to the region in which it Iles or
fissures (Figs. 5.5 and 5.6; also see Figs. 5.1, 5.3. and 5.4). the surface that lt covers (see Figs. 5.3 and 5.5). The
It is thinner than the parietal layer. cervical pleura (cupula) extends up into the neck,
lining the undersurface of the suprapleural membrane
Layers and Cavity (also see Fig. 4.8). It reaches a level of 1 to 1.5 in.
The two layers are continuous with one another via a (2.5 to 4 cm) above the medial third of the clavicle.
cuff of pleura that surrounds the structures entering The costal pleura lines the inner surfaces of the ribs,
and leaving the lung at the hllum of each lung (see the costal cartllages, the intercostal spaces, the sides
Figs. 5.3 to 5.5). This cuff hangs down as a loose fold of the vertebral bodies, and the back of the sternum.
called the pulmonary ligament and allows for move- The diaphragmatic pleura covers the thoracic surface
ment of the pubnonary vessels and large bronchi during of the diaphragm. In quiet respiration, the costal and
respiration (see Fig. 5.5). diaphragmatic pleurae are In apposition to each other
The parietal and visceral layers of pleura are sepa- below the lower border of the lung. In deep Inspiration,
rated from one another by a slltllke space, the pleural the margins of the base of the lung descend, and the
cavity (see Figs. 5.3 and 5.4). (Clinicians are increas- costal and diaphragmatic pleurae separate. This lower
ingly using the term pleural tpace instead of the ana- area of the pleural cavity into which the lung expands
tomic:: term pleural cavity. This is probably to avoid the on inspiration is referred to as the costodlaphrag-
confusion between the pleural cavity [slitlike] space ma!lc receu (see Figs. 5.4 and 5.5). The mMlatdlnal
 Pleurae 223

Costal plE!(lra Left lung
(parietal pleura)

Diaphragmatic pleura
(parietal ple\lra)

Figure 5.5 Different areas of the parietal pleura. Note the cuff of pleura (dotted lines) that surrounds the structures
forming the root of the left lung at the hilum. The parietal and visceral layers of pleura become continuous here. Arrows
indicate the position of the costodiaphragmatic recess.

pleura covers and forms the lateral boundary of the During inspiration and expiration, the anterior borders
mediastinum. It reflects as a cuff around the vessels of the lungs slide in and out of the recesses.
and bronchi at the hilum of the lung and here becomes The surface projections of the lungs and pleurae are
continuous with the visceral pleura. Thus, each lung described in Chapter 4.
lies free except at its hilum, where it is attached to
the blood vessels and bronchi that constitute the
long root. During full inspiration, the lungs expand Nerve Supply
and fill the pleural cavities. However, during quiet The pleural layers are illllervated differently despite
lnsplratlon, the lungs do not fully occupy the pleural being a continuous membrane. Somatic afferent nerves
cavities at four sites: the right and left costodlaphrag- supply the parietal pleura {Fig. 5.7), which is sensitive
matlc recesses and the right and left costomediastlnal to paln, temperature, touch, and pressure:
recesses. The intercostal nerves segmentally supply the costal
The coetodlaphragmatlc l'ece8le8 are slltllke spaces pleura.
between the costal and diaphragmatic parietal pleurae The phrenlc nerve supplies the medlastlnal pleura.
that are separated only by a capillary layer of pleural The phrenic nerve supplles the diaphragmatic pleura
fluid. During inspiration, the lower margins of the lungs over the dome, and the lower lntercostal nerves sup-
descend into the recesses. During expiration, the lower
margins of the lungs ascend so that the costal and ply the periphery of the diaphragmatic pleura.
diaphragmatic pleurae come together again. Visceral afferent nerves supply the visceral pleura,
The costomedlasdnal recesses are situated along the which Is sensitive to stretch but Is Insensitive to com-
anterior margins of the pleura. They are slltllke spaces mon sensations such as pain and touch. These nerves
between the costal and medlastlnal parietal pleurae, run In company with autonomic nerves from the pulmo-
which are separated by a capillary layer of pleural fluid. nary plexus (see Fig. 5.7).
224 CHAPTER 5 Thorax, Part II: Thoracic Cavity

lnfrahyold muaclee
Left common carotid artery
Left internal jugular vein
Internal thoracic artery

Rightvagus
nerve
1-~~~:~~==t::LLeftvagus nerve
' Left subclavian artery
Cervical dome of
pleura Left mcummt laryngeal
nerve
First thoracic nerve
A Thoracic duct
sympathetic trunk
Esophagus

Right lung

Left lung

B

Esophagus

Figure S.6 Cross sections of the thorax. A. At the thoracic inlet. B. At the fourth thoracic vertebra.

Phrenic nerves
,.(C3, C4, and C5).,..,.,_,
,,.

Figure 5.7 Diagram showing the innervation of the pari-
etal and visceral layers of pleura.
 Lower Respiratory Tract 225

Q Clinical Notes
Pleural Fluid Pleurisy
The pleural cavity normally contains 5 to 10 mL of clear Inflammation of the pleura (pleuriU.orpleurisy), secondary
fluid, which lubricates the apposing surfaces of the visceral to inflammation of the lung (e.g., pneumonia), results in
and parietal pleurae during respiratory movements. ln11ammatory exudate coattng the pleural surfaces, which
Hydrostatic and osmotic pressures stimulate formation causes roughening of the surfaces. This roughening
of the fluid. Because the hydrostatic pressures are produces frtctlon, which can be heard with the stethoscope
greater in the capillaries of the parietal pleura than in the as a ple-ar.l rub on inspiration and expiration. Fibroblasts
capillaries of the visceral pleura (pulmonary circulation), often invade the exudate, resulting in deposition of collagen
the capillaries of the visceral pleura normally absorb the and format.ion of pleural adhealona that bind the visceral
pleural fluid. Any condltlon that Increases the production of pleura to the parietal pleura.
the fluid (e.g., Inflammation, malignancy, congestive heart
disease) or Impairs the drainage of the fluid (e.g., collapsed Pneumothorax,, Empyema, and Pleural Effusion
lung) results In abnormal accumulation of fluid, called a
pleural effwdon. The presence of 300 mL of fluid in the Air can enter the pleural cavity from the lungs or through
costodlaphragmatlc recess In an adult ls sufficient to enable the chest wall (pneumothorax) as the result of disease or
Its clinical detection. The clinical signs Include decreased lnJury (e.g., lnterstltlal lung disease, gunshot wounds). In
lung expansion on the side of the effusion, with decreased the old treatment of tuberculosis, air was purposely lDJected
breath sounds and dullness on percussion over the effusion Into the pleural cavity to collapse and rest the lung. This
(Flg.5.8). was known as artlftclal pneumothorax. A..,ontaneou.
poeumotborax Is a condition In which air enters the pleural
cavity suddenly without its cause being immediately
apparent. lnvesUgatlon usually reveals that air has entered.----Trachea from a diseased lung and a bulla (bleb) has ruptured.
dlsplaced to left Wounds that penetrate the thoracic wall (e.g., stab
wounds) may pierce the parietal pleura so that the pleural
cavity is open to the outside air. This condltlon ts called open
Collapsed pneumolhoru. Each time the patient inspires, it is possible
right lung to hear a!r under atmospheric pressure being sucked Into
the pleural cavity. Sometlmes, the clothing and the layers of
the thoracic wall combine to form a valve so that air enters
on inspiration but cannot exit through the wound. In these
circumstances, the air pressure builds up on the wounded
sideand pushes themediastinum toward the opposite side. Jn
this situation, a collapsed ltmg ls on the injured side, and the
opposite lung Is compressed by the deflected medlastlnum.
Serous This dangerous condition Is called a temlon paeumoeboru.
fluid Air in the pleural cavity associated with serous ftuid
is known as hydropneamothorax. associated with pus
Pleural effusion as pyopneumothorax, and associated with blood as
hemopneumothoru.. ln hemopneumothorax, trauma to the
chest may result In bleeding from blood vessels In the chest
Figure 5.8 A case of a right-sided pleural effusion. wall, from vessels In the chest cavity, or from a lacerated
The mediastinum is displaced to the left, the right lung. A collection of pus (without air) In the pleural cavity
is called an empyema. The presence of excess serous fluid
lung is compressed, and the bronchi are narrowed.
in the pleural cavity ls referred to as a pleural effUllon (see
Auscultation would reveal only faint breath sounds over Fig. 5.8). Fluid (serous, blood, or pus) can be drained from
the compressed lung and absent breath sounds over the pleural cavity through a wide-bore needle, as described
fluid in the pleural cavity. In Chapter 4 (see Needle Thoracostomy).

LOWER RESPIRATORY TRACT Trachea
The respiratory tract (respiratory tree) ts the network The trachea ls a mobtle cartilaginous and membranous
of passageways that supplies air to the lungs. The tube (Figs. 5.10 to 5.12; also see Fig. 5.9). It begins in
upper respiratory 1ract Includes the nasal passages the neck as the continuation of the larynx at the lower
and sinuses. pharynx, larynx, and upper portion of the border of the cricoid cartilage at the level of the sixth
trachea. The lower respiratory tract (1racheobron- cervical vertebra. It descends in the midline of the nedc.
ddal tree) includes the lower portion of the trachea, In the thorax, the trachea runs through the superior
the bronchi, and the bronchioles (Fig. 5.9). mediastinum, in approximately the midline. It ends by
226 CHAPTER 5 Thorax, Part II: Thoracic Cavity

Left principal bronchus

Respirator bronchiole

Alveolus

Figure 5.9 The lower respiratory tract, including the trachea, bronchi, bronchioles, alveolar duets, alveolar sacs, and
alveoli. Note the path taken by inspired air from the trachea to the alveoli.

dividing into right and left principal (main) bronchi at free ends of the cartilages. The posterior discontinuity
the level of the sternal angle (opposite the disc between permits the esophagus to expand Into the trachea dur-
the fourth and fifth thoracic vertebrae). During expira- ing swallowing.
tion, the bifurcation rises by about one vertebral level The relations of the trachea ln the neck are described
and during deep inspiration may lower as far as the in Chapter 12.
sixth thoracic vertebra. In adults, the trachea is about The relations of the trachea in the superior medlasti-
4 1/2-in. (11.25-cm) long and 1 in. (2.5 cm) in diameter. num of the thorax are as follows:
U-shaped bars (tracheal rings) of hyaline cartilage
embedded in the tracheal wall support and maintain Anteriorly: The sternum, the thymus, the left bra-
the patency of the trachea (see Fig. 5.9). The trachee.- chlocephallc vein, the origins of the brachlocephalic
118 moscle (a smooth muscle) connects the posterior
and left common carotid arteries, and the arch of the
aorta (see Figs. 5.6A, 5.10, and 5.30)
 Lower Respiratory Tract 227

Tractiea

Right
upper
bronchus
Bractliocephalic _ _ ~~~frJ.:::---
artery

Arch of aorta1-----.1."""-
Rtght prfnclpal
bronchus

Figure 5.11 Relationship of the pulmonary arteries to the
bronchial tree.

Stomacti

A

Csrlna

B Left prfnclpal bronchus

Figure S.10 Thoracic part of the trachea. A. Note that
the right principal bronchus is wider and is a more direct
continuation of the trachea than the left. B. The bifurcation
of the trachea as viewed from above.

Posteriorly: The esophagus and the left recurrent
laryngeal nerve (see Fig. 5.6A)
Right llcle: The azygos vein, the right vagus nerve,
and the pleura (Figs. 5.13A and 5.14A; also see
Fig. 5.6) Figure 5.12 A plastinated specimen of an adult trachea,
left llde: The arch of the aorta. the left common principal bronchi, and lung. Some of the lung tissue has
carotid and left subclavian arteries, the left vagus been dissected to reveal the larger bronchi. Note that the
and left phrenic nerves, and the pleura (see Figs. 5.6, right main bronchus is wider and a more direct continua-
5.138, and 5.14B) tion of the trachea than the left main bronchus.
228 CHAPTER 5 Thorax, Part II: Thoracic Cavity

Esophagus

Right brachiooephalic vein

\fi'~-"lt------ Right phrenlc nerve
Azygos vein -7'1'~~~~~.m -. l\"i~lt-l!H--- Superior vena cava

Right bronchi -~~~~~L~M~~....,""._.-:-""""-~

Pulmonary veins

Greater splanchnic nerve

l.e$ser splanchnic nerve

A

Left brachiocephalic vein.

Left pulmonary artery
Left bronchi
Left ventricle
covered by pericardium --He- - Left pulmonary veins

Descending aorta

~~~~'IP:-- Greater splanchnlc
nerve
~~~'-1-- Diaphragm

B Esophagus

Figure 5.13 Lateral views of the mediastinum. A. Right side. B. Left side.
 Lower Respiratory Tract 229

Right subdavlan vein

Sympathettc Right clavicle

ght subcfavius
CutrU
usele

Azygosve temal thoracic
1ery

lntercostal llE
1perfor vena cava

BC:endlng aorta
Right bror

Pulmonary"'
Rightabium
Greater spland
nc

Inferior vena <

light cupola of
liaphragm

1NTERIOR

vul costal cartilage

Sympatt'letic
Left aubclavl trunk
artt
Leftvagus
Leftcommc nerve
carotid arte1 Descending
aorta
Arch of
aorta Left auricle

Pulmonary tri

Right ventrlc

Left phrenic
nerve
ANTERIO.eft ventricle

Apexof hel.eft cupola of
iaphragm

Figure 5.14 Dissection ofthe mediastinum. The lungs, pericardium, and costal parietal pleura have been removed.
A. Right side. B. Left side.
230 CHAPTER 5 Thorax, Part II: Thoracic Cavity

Figure 5.15 The interior of the bronchial tree as seen through an operating bronchoscope. A. The bifurcation of the
trachea. Note the ridge of the carina in the center and the opening into the right main bronchus on the right, which is a
more direct continuation of the trachea. B. The left main bronchus. The openings into the left upper lobe bronchus and its
division and the left lower lobe bronchus are indicated. (Both images are courtesy of E. D. Andersen.)

Blood Supply (Fig. 5.lSA; also see Fig. 5.lOB). The bronchi divide
The inferior thyroid arteries (branches of the sub- dichotomously, eventually giving rise to several mil-
clavian arteries) supply the upper two thirds of the lion terminal bronchioles that terminate in one or more
trachea. and the bronchial arteries (branches of the respiratory bronchioles. Each respiratory bronchiole
thoracic aorta) supply the lower third. dlvtdes into 2 to 11 alveolar ducts that enter the alveolar
sacs. The alveoli arise from the walls of the sacs as dlver-
tlcula (see Bronchopubnonary Segments, to follow).
Lymph Drainage
Each principal bronchus supplies an entire lung (see
The lymph drains into the pretracheal and paratracheal Fig. S.12). The principal bronchi next divide Into lobar
lymph nodes and the deep cervical nodes. (secondary) bronchi that supply the individual lobes of
the lungs. The right principal (main) bronchus is wider.
Nerve Supply shorter, and more vertical than the left and ls about
The vagus and recurrent laryngeal nerves carry the 1-in. (2.5-