Anatomy of Thorax & Chest PDF

Summary

This document provides an overview of the anatomy of the thorax and chest, including the ribs, sternum, diaphragm, and intercostal muscles. It also includes a discussion of the function and structure of these components. The document appears to be lecture notes, rather than an exam past paper.

Full Transcript

Anatomy of thorax & chest

Dr.Maha Samir Younis
Lecturer of pt for cardiopulmonary disorders and its surgery
Department of internal pt – May UNIVERSITY

Thorax
Area between head and abdomen
contains heart, lung and blood vessels

Surrounded by thoracic cage formed of:
12 ribs
Sternum
Thoracic vertebrae
Clavicle
Intercostal muscles
Set of 12 ribs
Articulates posteriorly with vertebral column from
Ribs
T1-T12
Terminate anterior with cartilage called costal
cartilage
Types of ribs:
1. True ribs (vertebrosternal) attached to sternum from 1-
7
2. False ribs: doesn’t connect to sternum
Last 5 ribs (8 to 12)
1st 3 pairs called vertebrochondlar as they connect to
sternum through costal cartilage of rib above
Last 2 pairs are floating ribs as they connect to
vertebrae alone
Space between ribs called intercostal space and
contains intercostal muscles, neuromuscular
bundles and intercostal nerves, veins, arteries.

Superficial surface of rib cage is covered with
thoracolumbar facia which gives attachment to
neck, pectorals, back and abdominal muscles.
 Each rib consists of:

1. Head: articulate with thoracic vertebrae
through (superior costal facet of same
vertebra, inferior costal facet of upper
vertebra, transverse costal facet of same
vertebra)
2. Neck: extends 3 cm laterally from the head
and has 2 surfaces (anterior soft surface
and posterior rough surface for the
attachment of costotransverse ligament.
3. Shaft contains angle of the rib and extends
downward and laterally
Sternum
 Flat vertical bone at center of chest
 To protect heart and muscles
 Connect the ribs through costal
cartilage to form anterior rib cage
 Divided to:
1. Manubrium: superior segment
2. Body: a middle portion
3. Xiphoid process: narrow distal
segment
 STERNUM COMMON DEFORMITIES
1. Pectus excavatum (funnel chest)
 More common
 Sternum depressed posteriorly leading
to depression of adjacent costal
cartilage inward and depression of
anterior chest wall
2. Pectus carinatum:
 Outward displacement of sternum and
costal cartilage leading to abnormal Pectus excavatum Pectus carinatum
protrusion of anterior chest wall
 Diaphragm
This muscle separating thoracic cavity from
abdominal cavity
When it’s relaxed its dome shape (during expiration)
When it contracts it’s flattened to increase the volume
in the thoracic cavity (during inspiration)
Structure:
Upward curved, c shape structure of muscle and
fibrous tissue
Separate thoracic cavity from abdominal cavity
Formed of:
Central tendon forms the crest of the dome
Peripheral fibers
 Contains several openings mainly:
1. Caval opening in central tendon contain inferior
vena cava
2. Esophageal hiatus contains esophagus in
posterior part of diaphragm
3. Aortic hiatus: contains aorta and thoracic duct
in posterior part of diaphragm
 Nerve supply:
Central part phrenic nerve (c3-c5)
Peripheral part by intercostal nerves (T5-T11),
subcostal nerve T12
 Function:
Main muscle of respiration
 During inhalation:
Diaphragm contracts and moves inferior
direction led to increase volume of thoracic
cavity, decreasing intrathoracic pressure so air
moves in (with help of external intercostal
muscles)

 During exhalation:
Diaphragm relaxed so air moves move out by the
elastic recoil of diaphragm with assist of internal
intercostal muscles and abdominal muscles in
forced expiration.
Diaphragm movement during
respiration
 Diaphragmatic dysfunction can be categorized
into
Functional disorders
that lead to decreased muscle function, ranging from muscle
fatigue or weakness, to complete paralysis. As in COPD ,
mechanical ventilation patient or myopathies.

 Anatomical disorder
that are characterized by normal function of the diaphragm
but limited movement due to structural and anatomical
derangement. These disorders include herniation of the
diaphragm and diseases of the other related organs
obstructing its movement
 INTERCOSTAL MUSCLES
Function:
1. Helps to move chest wall
2. Involved in mechanical aspect of breathing
3. Helps to expand and shrink the size of chest
cavity
Nerve supply
is intercostal nerves mainly ventral rami of thoracic
spinal nerve
Supplied by intercostal arteries and drained by
intercostal veins.
 Intercostal muscles layering
1. External intercostal muscles:
Function: quiet and forced inhalation
Origin: ribs 1-11
Insertion: ribs 2-12
Direction downward, forward, medially
1. Internal intercostal muscles:
Function: forced expiration
Origin from rib 2-12
Insertion on ribs 1-11
Direction upward Forword laterally
1. Innermost intercostal muscles:
Deep layer of int intercostal muscles
Fibers direction: downward, forward, laterally
Separated from int intercostal muscles with
neurovascular bundle
Function: Depress ribs during forced expiration;
Support intercostal spaces and thoracic cage
Accessory muscles of respiration

 1-Scalene muscles:
 Group of muscles on
each side of neck
 Divided to (anterior,
middle, posterior)
 Innervated by spinal
nerves C3-C8
 Moves chest wall and
assist inhalation
 2-Sternocleidomastoid muscle:

Runs from head and neck to
sternum and first 2 ribs

This muscle elevates the
sternum thus increasing anterior
posterior diameter of chest
 3-Upper trapezius
 Assists in ventilation by helping elevation
thoracic cage
 4-Pectoralis muscles
 Pectoralis major increase anteroposterior
diameter of chest
 Pectoralis minor assist in raising the ribs
and increasing intrathoracic volume
Cont. accessory muscles of respiration

 5-Abdominal muscles
Including rectus abdominis,
transverse abdominis, internal
and external obliques.
*Theses muscles work to
increase intraabdominal
pressure when sudden
expulsion of air is required as
in huffing or coughing.
 HEART Size:
Approximately the size of man fist (250-350)
Is a muscular organ acts like a pump to gm
continuously send blood through the body.
Heart shape:
Location of heart: 1.Apex:
Directed downward and forward to left
Formed by left ventricle
Underneath the sternum in a thoracic
At level of 5th intercostal space, 3.5 inch
compartment called mediastinum which from midline directly under the nibbes
occupies space between the lung 2.Sternocostal surface (anterior surface)
Formed of right atrium, right ventricle
2/3, left ventricle 1/3
3.Diaphragmatic surface: (inferior surface)
Directed inferior and backward
Formed by two ventricles mainly 2/3 of
left ventricle
Slightly concave as it rests on diaphragm
4.Base of heart (posterior surface):
Formed by two atria mainly left atrium
Opposite to thoracic vertebrae (T5,6,7)
 Pericardium:

Is a fibrous sac surround the heart
Function:
1. Fluid within the sac lubricate the
outer wall of the heart to decrease
friction
2. Hold heart in place
3. Prevent heart over expanding
4. Form a barrier against infections
 PERICARDIUM LAYERS

Formed of:
Fibrous pericardium (PARIETAL)
outer thick wall formed of dense irregular
connective tissue
Serous pericardium (VISCERAL)
inner wall formed of parietal and visceral
pericardium
Pericardial cavity: space between 2 walls
filled with (10-15) pericardial fluid
 LAYERS OF HEART WALL

1. Epicardium: covering the outer
layer of heart
2. Myocardium: thick middle
layer, during contraction it
pumps blood out through aorta
and pulmonary trunk
3. Endocardium: covering the
inner surface of heart, valves,
and tendons
 Champers &Valves of heart
1- Right atrium:
Formed of main cavity and upward
protrusion called auricle
Openings in right atrium:
superior vena cava and inferior vena cava
(which deliver poor oxygenated blood from
upper and lower body)
coronary sinus
blood leaves right atrium to right ventricle
through tricuspid valve
2- Right ventricle:
Pumps poor oxygenated blood to lung
Has thinner wall than left ventricle
Blood leaves right ventricle to pulmonary
trunk through pulmonary orifice
3- Left atrium:
Receives oxygenated blood from lung
through pulmonary veins
Forms the greater part of heart base
Receives 4 pulmonary veins
4- Left ventricle:
Has thicker wall than right ventricle
Receive blood from left atrium through
mitral valve (bicuspid valve)
Blood leaves left ventricle through
ascending aorta to deliver oxygenated
blood to the body
 Heart valves:

1. Atrioventricular valves:
*Tricuspid valve between right atrium and
right ventricle
*Mitral valve between left atrium and left
ventricle
1. Semilunar valves:
Open when blood flow out of ventricles
*Pulmonary valve: open when blood flow
from right ventricle blood to pulmonary
artery (the only artery carries
deoxygenated blood to lung)
*Aortic valve: opens when blood flow from
left ventricle to aorta
 HEART VALVE DISEASES

1.regurgitation (or leakage of the valve): The valve(s) does
not close completely, causing the blood to flow backward through
the valve. This results in leakage of blood back into the atria from
the ventricles (in the case of the mitral and tricuspid valves) or
leakage of blood back into the ventricles (in the case of the aortic
and pulmonary valves).
2.stenosis (or narrowing of the valve): The valve(s) opening
becomes narrowed or valves become damaged or scarred (stiff),
inhibiting the flow of blood out of the ventricles or atria. The heart
is forced to pump blood with increased force in order to move
blood through the narrowed or stiff (stenotic) valve(s)
How much blood does your heart pump?
Your heart pumps about 2,000 gallons of blood each day.
That’s enough to fill an 8-by-10-foot swimming pool.
It beats around 100,000 times daily. In an average life span of
almost 79 years, your heart beats nearly 2.9 billion times

Normal heart beat:
Children 5-6 years → 75-115 BPM
Children 7-9 years → 70-110 PBM
Children > 10 years, adults and seniors → 60-100 PBM
Athletes in top condition → 40-60 PBM
 CIRCULATION OF THE HEART
On the right side
1.Oxygen-poor blood from all over your body
enters your right atrium through two large veins,
your superior vena cava and inferior vena cava.
These veins drain blood from your upper body and
lower body, respectively, and directly empty it
into your right atrium.
2.Your tricuspid valve opens to let blood travel
from your right atrium to your right ventricle.
3.When your right ventricle is full it squeezes,
which closes your tricuspid valve and opens your
pulmonary valve.
4.Blood flows through your main pulmonary
artery and its branches to your lungs, where it gets
oxygen and releases carbon dioxide.
On the left side
1.Oxygen-rich blood travels from your lungs to your left
atrium through large veins called pulmonary veins.
These veins directly empty the blood into your left
atrium.
2.Your mitral valve opens to send blood from your left
atrium to your left ventricle.
3.When your left ventricle is full it squeezes, which
closes your mitral valve and opens your aortic valve.
4.Your heart sends blood through your aortic valve to
your aorta, where it flows to the rest of your body
 Coronary arteries
Supply nutrients to the heart & runs along its
surface

1. Left coronary artery divided to:
Circumflex artery supply blood to left
atrium and side and back of left ventricle
Left anterior descending artery supply
blood to front and bottom of left
ventricle and front of septum
2. Right coronary artery:
Supply blood to right atrium and right
ventricle, back of septum
 Medical Conditions affecting the heart:
Arrhythmia: An irregular heartbeat like atrial fibrillation or
ventricular fibrillation.
Congestive heart failure: Damage or weakness in your heart muscle,
making it harder for your heart to pump blood to the rest of your
body.
Coronary artery disease (CAD): Hardening and narrowing of the
arteries that carry blood to your heart muscle due to plaque buildup.
Peripheral artery disease (PAD): Hardening and narrowing of the
arteries that carry blood to the rest of your body due to plaque
buildup.
Heart attack: A sudden blockage in your coronary artery that cuts off
oxygen to part of your heart muscle.
Heart valve disease: A heart valve that doesn’t work properly. For
example, it may be narrowed or leaky.
Structural congenital heart defects: Problems with your heart
structure that are present at birth, including bicuspid aortic valve
disease.( Fallot disease)
Sudden cardiac arrest: Sudden loss of heart function because of a
malfunction in your heart’s electrical system
 Electrical conduction system of the heart
1- Sinoatrial node (SA)
Send signals to make heart beat
2- Atrioventricular node (AV)
Carry signals from heart upper champers to lower champers
3- Left bundle branch:
Send impulses to left ventricle
4- Right bundle branch:
Send impulses to right ventricle
5- Bundel of Hiss:
Send impulses from AV node to Purkinje fibers
6- Purkinje fibers:
Make heart contract to pump blood
 RESPIRATORY SYSTEM
PRIMARY FUNCTION OF RESPIRATORY
SYSTEM:
1. exchange gases between atmosphere
and blood
2. homeostatic regulation of body PH
3. Protect against inhaled pathogens and
irritating substances
4. Vocalization
Process of external respiration

1.Exchange 1 (ventilation)
Exchange of gases between atmosphere
and lung through inhalation and
exhalation
2.Exchange 2
Exchange of O2 and CO2 between lung
and blood
3.Transport of O2 and CO2 BY BLOOD
4.Exchange 3:
Gas exchange between blood and body
cells
Respiratory airway
Leads from external environment to
exchange surface of lung

1- upper respiratory tract
(mouth, nasal cavity, larynx, pharynx)
2- lower respiratory tract
(trachea, 2 primary bronchi,
bronchioles, 2 lungs)
Role of airway:
1. Warming air
2. Adding water vapor
3. Filtering out foreign materials
Nose or mouth→ pharynx→
larynx→ trachea→ primary
bronchi→ secondary
bronchi→ bronchioles→
alveoli (exchange surface of
O2 &CO2 with blood)
 Alveoli
It is the exchange surface of O2 & CO2 between
blood and lungs
Formed of single layer of epithelium
Types:

1. Type 1 alveolar cells (95%)
Large, thin, allows rapid gas exchange
1. Type 2 alveolar cells (5%)
Small, thick, responsible for synthesis and
storage of pulmonary surfactant (↓ surface
tension and allows expansion of alveoli)

No. of alveoli >400,000,000
 Bronchial Tree
Trachea divides in to 2 main bronchi (primary bronchi) at level of sternal
angle at T4 vertebra
Each main bronchi enters the lung inferior and lateral through the hila
Right main bronchus is wider than left main bronchi
The main (primary) bronchi subdivided to secondary lobber bronchi
Right lung has 3 lobber bronchi
Left lung has 2 lobber bronchi
Each lobber bronchi subdivided to segmental bronchi
There are ten bronchopulmonary segments in right lung and eight at left
lung
Segmental bronchi subdivide to bronchioles
Type of bronchioles:
1- Conductive (20-25) branch
2- Terminal
3- Respiratory which gives rise to alveolar duct and alveolar sac
 LUNGS
Light spongy organs with volume filled with air filled spaces
Formed of:
1. Apex: lies above first rib and covered with cervical pleura
2. Base: concave inferior surface resting on diaphragm
3. Surfaces:
Costal surface related to (sternum, ribs, costal pleura)
Mediastinal surface related to middle mediastinum which
means between
2 lungs
contain heart & pericardium
Diaphragmatic surface: concave resting on diaphragm
dome (right dome is higher than left dome due to liver)
1. Borders of lung:
Anterior border (having cardiac notch at left lung)
Inferior border (separate lung base from costal surface)
Posterior border (extends from lung apex to inferior
border)
1. Lobes of lung:
Right lung: upper, middle, lower
Left lung: upper, lower
1. Fissures of lung:
Right lung:
Transverse fissure at level of 4th rib
Oblique fissure extends from T2 to 6 costal spaces
Left lung:
Oblique fissure extends from T2 to 5 costal spaces
1. Segments of lung:
Right lung:
Upper lobe (apical, anterior, posterior)
Middle lobe (medial, lateral)
Lower lobe (superior, anterior, posterior, medial, lateral)
Left lung:
Upper lobe (anterior, inferior, apical posterior, superior lingula)
Lower lobe (lateral, posterior, superior, anteromedial)
LUNGS LOBES &
SEGMENTS
 PLEURAL SPACE
Pleural space:
Thin fluid filled cavity located between
the lung and chest wall inner surface
Formed of:
Visceral pleura covers the lung
Parietal pleura lines the inner surface of chest
wall Secrets pleural fluid that lubricates and
↓friction during breathing
Blood supply to lungs through brachial
arteries
 Nerve supply to lungs:

Pulmonary plexus:
-Parasympathetic
stimulation (vagal nerve) -
Sympathetic stimulation
Phrenic nerve
 Lung defenses
 Nasal mucosa and hairs
warm and humidify inhaled air and filter out particles
 Goblet cells and bronchial seromucous glands
produce mucus which contains immunoglobulin A to protect
underlying tissues and trap organisms and particles
Mucus production may be increased by inflammation ( asthma,
bronchitis)
 Alveolar macrophages
roam the surface of the terminal airways and engulf foreign matters
and bacteria, their activity may be impeded by cigarette smoke, air
pollution, corticosteroid therapy and alcohol
 Type II pneumocytes
produce surfactant which protect underlying tissues and repairs
damaged alveolar epithelium
 Respiratory tract is protected by different
mechanisms in different levels:
1.Upper airways (physical mechanisms
like coughing and sneezing)
2.Lower airways (mucociliary
clearance mechanisms)
3.Terminal bronchioles and alveoli
(surfactant and cellular defenders
and alveolar macrophages)
 Nasal irritation
 Afferent impulse through
Sneeze reflex
trigeminal and olfactory nerves
 Medulla triggering reflex
 Efferent impulses
 eye closing
 deep inspiration
 a forced expiration with initial
closing of the glottis, and increasing
intrapulmonary pressure
 The sudden dilatation of the glottis
and uvula depression
 an explosive exit of air through the
mouth and nose, washing out
mucosal debris and irritants
 Ventilation:

Air flows in and out due to pressure gradient, from area of high pressure to low
pressure
Flows in when pressure in < pressure out
Flows out when pressure in > pressure out
 Boyle’s law
Pressure inversely proportional to volume
Ex. To allow inhalation (flow in air) pressure must ↓so volume must ↑
Muscles of ventilation:
 During inspiration:
Diaphragm
External intercostal muscles, sternocleidomastoid, scaleni
 During expiration:
Rest: passive recoil of diaphragm
Forced expiration:
abdominal muscles push diaphragm up
Internal intercostal muscles pull ribs down
MECHANISM OF RESPIRATION
highest ventilation in the lower lung
 Respiratory Features

Ventilation
refers to the flow of air into and out of the alveoli
affected by gravity and difference in intra pleural pressure.
Ventilation is greatest in lower lung than upper lung region

Airway resistance:
upper airways provide 45% of total airway resistance
Lower airway may be narrowed due to: normal expiration, external pressure due to tumor or
pleural effusion, bronchoconstriction, mucosal congestion

Compliance:
how easily the lung inflates during inspiration
Decreased by fibrosis, edema, pleural effusion
Increased by age, emphysema
Diffusion:
the spontaneous movement of gases, without the use of any energy or effort by the body, between
the alveoli and the capillaries in the lungs
alveolar capillary interface Decreased by thickening, fibroids, edema

Perfusion:
refers to the flow of blood to alveolar capillaries
Affected by body position & hydrostatic pressure
Lower lung has greater perfusion than upper lung

Ventilation- perfusion matching (V/Q)
perfusion increases more than ventilation at the base of the lung, resulting
in lower V/Q ratios in the base of the lung compared to the apex.
In a healthy individual, the V/Q ratio is 1 at the middle of the lung,
with a minimal spread of V/Q ratios from 0.3 to 2.1 from base to apex
abnormal ratio results from:
Uneven compliance due to fibrosis or emphysema
Uneven airway resistance due to bronchoconstriction or tumors
Obstruction of pulmonary circulation due to thrombosis, fat embolus
Compression of blood vessels due to over expanded alveoli
 Exercise physiology & ventilation:
During exercise the respiratory system must increase the
volume of air (Oxygen) that is ventilated by the lungs (i.e.,
minute ventilation, which is usually measured during
expiration and thus referred to as VE) and diffused into the
blood for delivery to the exercising muscles.

At rest, VE is usually 5 to 10 L/min and it often increases 15- to 20-
fold during maximal exercise.
At the onset of mild to moderate exercise, VE typically increases
via increasing tidal volume.
During more strenuous exercise, rising respiratory rates further
augment VE.
VE Increases in direct proportion to oxygen consumption (VO2) and
carbon dioxide production (VCO2) until exercise intensity exceeds
the ventilatory threshold (generally about 50% to 70% of V O2max,
when there are abrupt nonlinear increases in lactate and VCO2). At
this point VE also increases disproportionately with VO2.
 Respiratory rate & depth control:
Brainstem control

Medulla respiratory center:
1.Medullary rhythmicity area:
Maintains basic rhythm between
inspiration and expiration
Pons respiratory control:
1. Pneumotaxic area:
stimulate expiration
2.Apneustic area:
Activate and prolong inspiration
 Other controls of respiration rate & depth

1. higher brain centers (cerebral cortex) have
voluntary control over breathing
2. receptors in muscles and joints
(proprioceptors) when stimulated, it
increases breathing
3. pain: sudden pain can cause apnea
(cessation of breathing while prolonged
pain increase breathing
4. temperature: increase temperature leads
to increase respiratory rate and vice versa
5. blood pressure:
↓BP → Increase respiratory rate
↑BP→ Decrease respiratory rate
6-Hering Breur reflex:
Prevents over stretching of lung due to stretching
receptors throughout the lung
With stretching, vagus nerve stimulates to inhibit
apneustic area, and allow pneumotaxic area
to dominate allowing expiration
7-CO2 level:
Hypercapnia:
Increase in PCO2 stimulate apneustic area
Ex. Holding breath →build up CO2→↑Breathing to
equalize PCO2 in vessels
Increase CO2 =
Increase breathing =
Increase hyperventilation to decrease the
CO2 level
Hypocapnia:
Blown off CO2 leads to decrease PCO2 leads to
decrease respiration to stabilize CO2 level
Decrease Breathing =
Decrease Respiration to stabilize CO2
levels
 Lung volumes and capacities

Tidal Volume (TV)
It is the amount of air that can be inhaled or exhaled
during one respiratory cycle
Inspiratory Reserve Volume (IRV)
It is the amount of air that can be forcibly inhaled after
a normal tidal volume

Expiratory Reserve Volume (ERV)
It is the volume of air that can be exhaled forcibly after
exhalation of normal tidal volume.
Residual Volume (RV)
It is the volume of air remaining in the lungs after
maximal exhalation
 Inspiratory capacity (IC)
It is the maximum volume of air that can be
inhaled following a resting state
Total Lung Capacity (TLC)
It is the maximum volume of air the lungs can
accommodate or sum of all volume
compartments or volume of air in lungs after
maximum inspiration.
Vital Capacity (VC)
It is the total amount of air exhaled after maximal
inhalation
Function Residual Capacity (FRC)
It is the amount of air remaining in the lungs at
the end of a normal exhalation