Development of the respiratory system

Question 1

What is the URT (conducting portion) made up of?

Answer 1

• Nasal cavities
• Nasopharynx
• Oropharynx
• Larynx

Question 2

What is the LRT (conducting portion) made up of?

Answer 2

• Trachea
• Bronchi
• Bronchioles
• Terminal bronchioles

Question 3

What is the LRT (respiratory portion) made up of?

Answer 3

• Respiratory bronchioles
• Alveolar ducts
• Alveolar sacs
• Alveoli

Question 4

What is the point of transition from upper to lower RT?

Answer 4

Larynx

Question 5

Where does the inner epithelial lining of the trachea/ bronchi come from?

Answer 5

Inner epithelial lining of the trachea/ brochi comes from the endoderm.

Question 6

Where does the connective tissue and C shaped cartilage come from?

Answer 6

C shaped cartilage rings and connective tissues come from the mesoderm.

Question 7

At week 4 what does the embryo look like?

Answer 7

Yolk sac visible, somites visible, CNS development, gut tube (foregut, midgut, hindgut). Respiratory diverticulum (lung bud) appears in ventral wall of foregut. Derived from endoderm.

Question 8

How is the gut tube divided?

Answer 8

Gut tube- split into foregut- goes from oropharyngeal membrane to septum transversum, midgut- yolk sac and the vitelline duct, hind gut- anything distal to the yolk sac.
Foregut- in it we have a R diverticulum (a growth)- gut tube where we develop out R system/ tract

Question 9

How does the lung bud from and at what day does it appear?

Answer 9

• Appears day 22
• Grows ventrocaudally
• Tracheoesophagul ridges separate the respiratory diverticulum from the foregut (except laryngeal inlet)
• Dorsally oesophagus
• Ventrally trachea and lung bud which has now divided to form two lung buds

Question 10

What is a fistula?

Answer 10

An abnormal connection

Question 11

What is a tracheoesophageal fistulas?

Answer 11

A fistula is an abnormal communication and results from incomplete division of the foregut into oesophagul and respiratory portions.

Abnormal connections between trachea and oesophagus

Question 12

What is atresia?

Answer 12

When oesophagus ends up a blind ended sac

Question 13

Tracheoesophageal fistula with oesphageal astresia- what is it?

Answer 13

distal part of oesphagus still connected to trachea-proximally oesphagus is a blind ended sac- narrowed so much it closes- oesophagus atresia

Question 14

What is an H type tracheoesophagul fistula?

Answer 14

Fistula between trachea and oesophagus

Question 15

What happens when tracheoesophageal fistula with oesphageal astresia occurs?

Answer 15

• Upper oesophagus ends abruptly; lower oesophagus forms fistula with trachea
• Abdomen rapidly distends as stomach fills with air- inspired air down trachea then down each of bronchi- abnormal connection between trachea and oesophagus- air can escape into oesophagus- into the stomach

Question 16

What congenital abnormalities are tracheoesophageal fistulas associated with?

Answer 16

Component of either the Vacterl or Vater associated abnormalities:

V vertebral defects
A Anal atresia
(C) Cardiac defects
T Tracheo-oesophageal fistulas
E Esophageal atresia 
R Renal abnormalities
(L) Limb defects

Question 17

How are the lungs formed?- week 5 and 6

Answer 17

• During partitioning of oesophagus and respiratory diverticulum right and left lung buds form
• Further growth and differentiation during week 5 results in formation of main bronchi from secondary bronchi (3 right, 2 left)
• During 6th week further branches result in the formation of tertiary bronchi – these will each supply a bronchopulmonary segment (sometimes known as a bronchial tree) (10 right, 8 left)

Question 18

How are the lungs formed?- week 16, 26 and 36

Answer 18

• Branching continues to form the terminal bronchioles by week 16 and respiratory bronchioles by week 26. First alveoli develop in week 36.
• Branching is regulated in part by the interaction of the epithelium (derived from the foregut) with the overlying visceral mesoderm

Question 19

What does the visceral mesoderm form?

Answer 19

Visceral mesoderm forms cartilage, smooth muscle, connective tissue and capillaries – branching is regulated by the epithelium interacting with the overlying visceral mesoderm

Question 20

How is the pleura formed?

Answer 20

Lateral plate mesoderm forms the pleura
Lateral walls come together can see lateral plate mesoderm is split into two- visceral and parietal mesoderm layer- these go and form the pleuras
3D embryo- visceral mesoderm surround gut tube, parietal mesoderm forming parietal pleura

Question 21

What mesoderm forms the parietal and visceral mesoderm?

Answer 21

Visceral mesoderm forms visceral pleura, parietal mesoderm forms parietal pleura.

Question 22

What is pulmonary agenesis?

Answer 22

• Occurs when lung bud fails to split
• Complete absence of bronchi and vasculature
• Can be unilateral or bilateral
• Bilateral agenesis is incompatible with life

Question 23

What are unilateral pulmonary agenesis clinical presentations?

Answer 23

• child usually develops respiratory distress
• remaining lung is compromised, usually by a lower respiratory tract infection
• 60% have other congenital anomalies including cardiac lesions, diaphragmatic hernias, and skeletal anomalies (commonly vertebral or rib anomalies)
• Agenesis of the right lung is associated with a higher frequency of anomalies

Question 24

What is pulmonary hypoplasia?

Answer 24

• All components are present, but incompletely developed
• Severity of hypoplasia determines the degree of respiratory compromise
• May be found in association with congenital diaphragmatic hernia (CDH)

Question 25

What is hypoplasia?

Answer 25

Hypoplasia= fails to form fully

Question 26

Branching morphogenesis

Answer 26

Result? supernumerary lobes or segments
Little functional significance

Branching pattern can go wrong- can have an extra lobe- R has 4 lobes- accessory lobe forms called a azygos lobe
Extra lobe doesn’t do much- little functional significance

Question 27

If diaphragm fails to form properly what happens?

Answer 27

Diaphragm- can develop an opening- intestinal contents can project into this space and form a hernia- lung can’t develop fully

Question 28

What is histogenesis of the lungs?

Answer 28

Maturation of the lungs

Question 29

Maturation of the lungs is divided into four periods- what ate they?

Answer 29

1. Pseduoglandular
2. Canalicular
3. Terminal sac
4. Alveolar

Question 30

Pseudoglandular period- 5-17 weeks- what happens?

Answer 30

Branching of the respiratory tree has occurred to form terminal bronchioles- endodermal, mesodermal signalling stimulate the branching
bronchioles but respiration not possible so foetus could not survive.

Question 31

Canalicular period -16-25 weeks- what happens?

Answer 31

• Terminal bronchioles give rise to respiratory bronchioles, which give rise to alveolar ducts- start to develop functional area of R system
• Mesodermal tissue becomes highly vascularised- develops more capillaries
• Respiration is possible towards end of canalicular period as some terminal sacs have developed at the ends of the respiratory bronchioles (and remember highly vascularised)

Question 32

Terminal Sac Period- 26 – birth- what happens?

Answer 32

• Further terminal sacs (primitive alveoli- specialised air sacs) develop
• Epithelium thins and capillaries come into ‘contact’ with epithelium
• Blood-air barrier formed
-Epithelium differentiates to give rise to:
-Type I pneumocytes (across which gaseous exchange takes place)
-Type II pneumocytes which secrete surfactant

Question 33

What does surfactant do?

Answer 33

• Surfactant forms a film over the internal walls of terminal sacs- prevents alveoli from collapsing when there is a low P
• Decreases surface tension thus facilitating inflation

High surface tension- alveoli collapse- thus need surfactant

Question 34

Alveolar Period-36 weeks to 8 years- what happens?

Answer 34

• Development of the lungs after birth is due mainly to an increase in the number of respiratory bronchioles and alveoli
• 95% of mature alveoli do not develop until after birth

Question 35

What happens at birth?

Answer 35

• Breathing movements start in utero and serve to remove amniotic fluid
• Also kicks starts muscles of respiration into action
• At birth any remaining lung fluid rapidly reabsorbed by capillaries
• Baby’s first breath, air into lungs, surfactant present in sufficient amounts respiration possible
• Circulatory changes- changes in pressure lead to this

Question 36

Respiratory distress syndrome- what is it?

Answer 36

• If a child is born prematurely, the state of development of the lungs is usually the prime factor in determining prognosis
• Born between 26 weeks and birth good (terminal sac and alveolar periods) chance of survival as surfactant is produced in sufficient quantities
• Prior to this time point chances of survival poor e.g. in canalicular period

Question 37

At 23 weeks what would happen to a baby if it was born prematurely?

Answer 37

• No surfactant produced
• Laboured breathing (if possible) as threatens the infant with immediate asphyxiation- more effort is needed by the baby
• Increased rate of breathing
• Mechanical ventilation needed to support baby’s breathing
• Damage to alveolar lining; fluid and serum proteins leak into alveolus
• Continued injury may lead to detachment of alveolar lining
• Chronic lung injury in preterm infants may cause bronchopulmonary dysplasia (Dysplasia means ‘abnormal formation’ so that a part/cell is abnormal )

Question 38

What are the treatments for premature babies?

Answer 38

• Glucocorticoid treatment accelerates fetal lung development and surfactant production
• Surfactant therapy - natural or artificial surfactant (more effective with surfactant A and B proteins)

Question 39

What is Surfactant Protein B Deficiency Disease?

Answer 39

• Genetic condition - autosomal recessive.

* Fatal disease even with surfactant replacement therapy