Anatomy of Thoracic Wall and Diaphragm PDF

Summary

This document provides a comprehensive overview of the anatomy of the thoracic wall and diaphragm. It covers various aspects including bony landmarks, soft tissue landmarks, types of ribs, costal cartilages, intercostal spaces, thoracic vertebrae, the sternum, thoracic apertures, diaphragm structures, nerve supply, and clinical notes.

Full Transcript

ANATOMY OF THORACIC
WALL AND DIAPHRAGM
DR. SAIMA TASNEEM
Thorax
Thorax (Latin) chest or breastplate
Upper part of trunk of body.
Supported by skeletal framework,
thoracic cage.
Thoracic cavity contains
❑Principal organs of respiration
lungs
❑Principle organ of circulation, heart
Bony landmarks
Suprasternal/jugular notch
❑Superior border of manubrium between sternal ends of
clavicles.
❑Lies at level of lower border of body of T2. Trachea can be
palpated here.
Sternal angle/angle of Louis:
❑Transverse ridge approx. 5 cm below suprasternal notch.
❑Marks manubriosternal joint
❑Lies at level of 2nd costal cartilage ant., and the disc between T4
& T5 post.
Bony landmarks
Xiphisternal joint:
Costal margin on each side is formed by 7th to 10th costal
cartilages. Between these lies subcostal or infrasternal angle.
Joint lies at level of upper border of T9.
Ribs:
Scapula overlies 2-7 ribs on posterolat. aspect of chest wall.
10th rib the lowest point, lies at 3rd lumbar vertebra level.
11th and 12th ribs are not seen from the front
SIG. OF ANGLE OF LOUIS
✓Counting of ribs. 2nd costal cartilage and 2nd rib located at this
level.
✓Separates sup mediastinum from inf mediastinum
✓Ascending aorta ends here, arch begins and ends here and
descending aorta begins.
✓Trachea divides into 2 principle bronchi
✓Upper limit of base of heart.
Soft Tissue Landmarks
Nipple:
Variable in females, in males in 4th IC space
about 10 cm from midsternal line
Apex beat:
Visible & palpable cardiac impulse in left 5th IC
space, 9 cm from the midsternal line/medial to
midclavicular line.
Trachea:
Palpable in suprasternal notch midway
between 2 clavicles.
Midaxillary line:
Passes vertically between 2 folds of axilla
Scapular line:
Passes vertically along inferior angle of
scapula.
Skeleton Of Thorax
Osseocartilaginous elastic cage;
increases and decreases intrathoracic
pressure
FORMATION OF THORACIC
SKELETON
Ant: sternum
Post: 12 thoracic vertebrae and
intervening intervertebral discs
On each side by 12 ribs with their
cartilages.
Each rib articulates post. with
vertebral column.
Ribs (L. costae)
Curved, flat bones, form most
of the thoracic cage
Light in weight & resilient.
Spongy interior contains
hematopoietic tissue
Types of Ribs
True (vertebrosternal) (1st–7th
ribs):
Attach directly to sternum through
own costal cartilages.
False (vertebrochondral) (8th,
9th, & 10th ribs):
Cartilages are connected to the
cartilage of the rib above, indirectly
connected with sternum.
Floating (vertebral, free) (11th,
12th ribs):
Rudimentary cartilages do not
connect even indirectly with the
sternum
 Features of Typical Ribs
Head; wedge shaped, has 2 facets, separated by
crest; 1 for articulation with corresponding vertebra
other for superior vertebra
Neck: connects head with body at level of tubercle.
Tubercle: 2 parts
Smooth articular part, at junction of neck and
body (articulates with transverse process of
corresponding vertebra);
Rough non-articular part for attachment of
costotransverse ligament
Body (shaft): thin, flat, and curved, esp. at costal
angle where the rib turns anterolat.
Angle marks lat. limit of attachment of deep back
muscles to ribs.
Concave internal surface has costal groove along the
inf. border and provides protection for the
intercostal nerve and vessels.
Features of Atypical Ribs
1st rib:
body is widest horizontal,
shortest, and most sharply
curved.
Single facet for articulation with
T1
2 transverse grooves on sup.
surface for subclavian vessels
separated by a scalene tubercle
and ridge (anterior scalene
muscle is attached).
Features of Atypical Ribs
2nd rib:
✓thinner, less curved
✓body, longer than 1st.
✓2 facets for articulation with T1
and T2;
✓rough area on upper surface,
(tuberosity for serratus anterior,
part of muscle originates).
10th–12th ribs: 1 facet on
head.
11th and 12th ribs: short; no
neck or tubercle.
Costal cartilages
Prolong ribs ant.; provide elasticity to
thoracic wall,
Cartilages in length through first 7
and then gradually.
1st 7 cartilages attach to sternum
directly; 8th, 9th, and 10th articulate
with cartilages sup. to them, forming a
cont., cartilaginous costal margin
11th & 12th cartilages form caps on
ant. ends of corresponding ribs and do
not attach to any other bone or
cartilage.
Cartilages of 1–10 anchor the anterior
end of the rib to the sternum, limiting
its overall movement.
Intercostal spaces
Separate ribs & their costal cartilages.
Named as per rib forming superior border of space, e.g., 4th
intercostal space is b/w 4 and 5 ribs.
11 intercostal spaces and 11 intercostal nerves, occupied by
intercostal muscles and membranes, and two sets (main and
collateral) of intercostal blood vessels and nerves, (same no. as no. of
space).
Space below 12th rib isn’t between ribs; known as subcostal space, &
ant. branch of T12 nerve is subcostal nerve.
Spaces are widest anterolat.
Spaces widen with inspiration and on contralateral extension and/or
lateral flexion of the thoracic vertebral column.
Thoracic Vertebrae
Typical thoracic vertebrae; have
bodies, vertebral arches, and seven
processes for muscular and articular
connections.
Characteristic features include:
Bilateral demifacets on bodies, in
inferior and superior pairs, for
articulation with ribs’ heads.
Costal facets on transverse processes
for articulation with ribs’ tubercles,
except for the inferior 2 or 3
vertebrae.
Spinous processes; long & inferiorly
slanting.
Thoracic Vertebrae
Atypical thoracic vertebrae
have whole facets instead of
demi facets.
Superior costal facets of T1 for
head of 1st rib & inferior demi
facet for cranial part of 2nd rib.
T10 has one costal facet, located
on body and its pedicle.
T11 and T12 also have only 1
costal facet, located on pedicles.
Sternum
G. sternon, chest
Flat, elongated bone that forms middle of ant. part of thoracic cage.
Overlies and protects mediastinal viscera and much of the heart.
Consists of three parts:
Manubrium
Body
Xiphoid process
Parts are connected together by cartilaginous joints (synchondroses)
in young adults; ossify during middle to late adulthood.
 Sternum
Manubrium (L. handle)
Trapezoidal shape.
Widest and thickest
Concave center (suprasternal
notch), sternal ends of clavicles
articulate with clavicular notches.
Inferolat. to notch, cartilage of 1st
rib is attached
Manubrium and body lie in
different planes superior and
inferior to manubriosternal joint
Sternum
Body
Long, narrow & thin
Located at T5–T9 level
4 sternebrae (primordial
segments) in young people
articulating with each other at
sternal synchondroses.
In adults body has 3 transverse
ridges representing lines of fusion
(synostosis) of 4 originally
separate sternebrae.
Sternum
Xiphoid process
Smallest part; thin and elongated.
Inf. end lies at T10 level.
Cartilaginous in young people, ossified in
adults older than 40. In elderly it may fuse
with body.
Landmark in the median plane,
xiphisternal joint indicates inf. limit of
central part of thoracic cavity;
Joint is site of the infrasternal angle
(subcostal angle) formed by the right and
left costal margins
Midline marker for the superior limit of
the liver, the central tendon of the
diaphragm, and the inferior border of the
heart.
Thoracic Apertures
Thoracic cage is a complete wall peripherally but is open
superiorly and inferiorly.
Cone shaped.
Smaller superior opening (aperture) allows communication with
the neck and upper limbs.
Larger inferior opening provides ring-like origin of diaphragm,
which completely occludes the opening.
Movements of the diaphragm control the volume/internal
pressure of the thoracic cavity helping with air exchange.
Sup Thoracic Aperture
Post.: T1, the body of which
protrudes anteriorly into the
opening.
Lat.: 1st pair of ribs and their
costal cartilages.
Ant.: sup. border of
manubrium.
Structures passing through Sup Thoracic
Aperture
Trachea
Esophagus
Nerves, and vessels supplying &
draining the head, neck, and
upper limbs.
Adult aperture measures
approx. 6.5 cm anteropost. and
11 cm transversely.
Aperture slopes antero-inf. due
to obliquity of the 1st pair of
ribs.
Inferior Thoracic Aperture
Post.: by T12, the body of
which protrudes anteriorly
into the opening.
Posterolat.: by 11th and 12th
ribs.
Anterolat.: joined costal
cartilages of ribs 7–10,
forming the costal margins.
Ant: xiphisternal joint.
Inferior Thoracic Aperture
Diaphragm separates thoracic
and abdominal cavities
almost completely.
Structures passing from the
thorax to the abdomen, or
vice versa, pass through
openings that traverse the
diaphragm (e.g., the
esophagus and inferior vena
cava) or pass posterior to it
(e.g., the aorta).
Diaphragm
Thin muscular and tendinous septum
that separates thorax & abdominal
cavities.
Pierced by structures that pass between
the chest and the abdomen.
Most important muscle of respiration.
Dome shaped and consists of a
peripheral muscular part, which arises
from the margins of the thoracic
opening, and a centrally placed tendon.
 Origin of the diaphragm
A sternal part arising from the posterior surface of the xiphoid process
A costal part arising from the deep surfaces of the lower six ribs and their costal
cartilages & forms the right & left domes
A vertebral/lumbar part arising from upper three lumbar vertebrae; forms
the right & left crura & the arcuate ligaments
Shape of the Diaphragm
It is studied as
(a)Central tendon
(b)Right & left crus
(c)Right & left dome
Insertion of the Diaphragm
Inserted into a central
tendon.
Superior surface of
tendon partially fused
with inferior surface of
fibrous pericardium.
Some of fibers of right
crus pass up to the left
and surround the
esophageal orifice in a
slinglike loop.
These fibers act as a
sphincter and assist in
the prevention of
regurgitation of the
stomach contents into
the thoracic part of the
esophagus.
 Crura & Arcuate Ligaments
Right Crus arises from the sides of the bodies
of the L 1-3 & IV discs;
Left crus arises from the sides of the bodies
of the L 1-2 & IV disc.
Lateral to the crura the diaphragm arises from
the medial & lateral arcuate ligament.
Medial arcuate ligament extends from the side
of the body of L2 to the tip of the transverse
process of L1.
Lateral arcuate ligament extends from the tip
of the transverse process of L1 to the lower
border of the 12th rib.
Medial borders of 2 crura are connected by a
median arcuate ligament which crosses over
the anterior surface of the aorta
Functions of the Diaphragm
Muscle of inspiration: On contraction the diaphragm pulls its central tendon
down and increases the vertical diameter of the thorax. The diaphragm is the most
important muscle used in inspiration.

Muscle of abdominal straining: The contraction of the diaphragm assists the
contraction of the muscles of the anterior abdominal wall in raising the intra-
abdominal pressure for micturition, defecation, and parturition.

Weight lifting muscle: In a person taking a deep breath and holding it (fixing
the diaphragm), the diaphragm assists the muscles of the anterior abdominal wall
in raising the intra-abdominal pressure. Before doing this make sure that a person
have adequate sphincteric control of the bladder and anal canal under these
circumstances.

Thoracoaabdominal pump: The descent of the diaphragm decreases the
intrathoracic pressure & increases the intra-abdominal pressure. This compresses
the blood in the inferior vena cava and forces it upward into the right atrium of the
heart. Within the abdomin lymph in vessels is also compressed, and its passage
upward within the thoracic duct is aided by the negative intrathoracic pressure.
The presence of valves within the thoracic duct prevents backflow.
Openings in the Diaphragm
The diaphragm has three main
openings:
The caval opening lies at the level of the
T 8 vertebra in the central tendon.
Inferior vena cava & branches of the right
phrenic nerve.

The esophageal opening lies at the level
of the T 10 vertebra in a sling of muscle
fibers derived from the right crus at the left
of median plane.
Esophagus, the right and left vagus nerves,
the esophageal branches of the left gastric
vessels, & the lymph vessels.

The aortic opening lies anterior to the
body of the T 12 vertebra between the
crura.
Aorta, thoracic duct, & azygos vein.
Nerve Supply of the Diaphragm
Motor nerve supply:
The right and left phrenic nerves (C3, 4, 5)

Sensory nerve supply:
The parietal pleura and peritoneum covering the central surfaces of the
diaphragm are from the phrenic nerve and the periphery of the diaphragm
is from the lower six intercostal nerves.
 Clinical Notes
Hiccup
Involuntary spasmodic contraction of diaphragm accompanied by
approximation of vocal folds and closure of glottis of larynx. It is a common
condition in normal individuals and occurs after eating or drinking as a result
of gastric irritation of the vagus nerve endings. It may, however, be a symptom
of disease such as pleurisy, peritonitis, pericarditis, or uremia.

Paralysis of the Diaphragm
A single dome of the diaphragm may be paralyzed by crushing or sectioning of
the phrenic nerve in the neck. Occasionally, the contribution from the fifth
cervical spinal nerve joins the phrenic nerve late as a branch from the nerve to
the subclavius muscle. This is known as the accessory phrenic nerve. To obtain
complete paralysis under these circumstances, the nerve to the subclavius
muscle must also be sectioned.

Penetrating Injuries of the Diaphragm
Any penetrating wound to the chest below the level of the nipples should be
suspected of causing damage to the diaphragm until proved otherwise. The
arching domes of the diaphragm can reach the level of the fifth rib (the right
dome can reach a higher level).
Clinical
Cervical rib:
Rib attached to C7.
Seen in about 0.5% of subjects
Exerts traction on lower trunk of
brachial plexus which arches over a
cervical rib.
Pt complains of paraesthesia or
abnormal sensations along the ulnar
border of the forearm, and wasting of
the small muscles of the hand
supplied by segment T1.
Clinical
In coarctation or narrowing of the
aorta, the posterior intercostal
arteries get enlarged greatly to
provide a collateral circulation.

Pressure of the enlarged arteries
produces characteristic notching
Clinical
Thoracic cage injuries result from
trauma and often involve rib
fractures.
Ribs 1, 11, and 12 are the least
fractured ribs.
Rib fractures may occur in a
transverse plane or an oblique plane
or at multiple sites on the same rib,
resulting in a free floating segment
(stove-in, or flail chest, injury).
Pain is intense because of the
continued expansion and
contraction of the rib cage necessary
during respiration
Clinical
Intercostals assist the diaphragm and, along with other
accessory muscles of respiration (e.g., the scalene muscles), can
become hypertrophied if a respiratory pathologic process occurs
(e.g., in a chronic obstructive pulmonary disease such as
emphysema).
Chest trauma can lead to very painful breathing. Injection of a
local anesthetic agent into the intercostal space (intercostal
nerve block) can relieve this pain.
Clinical
Thoracic ventral rami (intercostal nerves) run in the costal
groove at the inferior margin of each rib; physicians must be
aware of this positioning when entering the intercostal space
(for injections or chest tube placements)
Thoracic outlet syndrome
Caused by cervical rib or abnormal scalene muscle or first rib
form
Neurogenic
Venous
Arterial