Respiratory System 2

Question 1

Understand the physical law that governs the movement of air into and out of the lungs

Answer 1

Boyle’s Law

• Defines the relationship between gas pressure and volume
• Determines how air moves into and out of the lung

Decrease volume of container = collisions occur more often over time = increasing pressure of gas

Increase volume = free collisions = because it takes longer for gas molecule to travel from one wall to another = decrease gas pressure

Question 2

Describe Atmospheric pressure involved in pulmonary ventilation

Answer 2

Pressure of the air outside the body
~760 mmHg

Inhalation
- Air pressure within lungs is lower than atmospheric pressure

Exhalation
- Air pressure within lungs rises above atmospheric pressure

Question 3

Describe Intrapulmonary pressure involved in pulmonary ventilation

Answer 3

Pressure inside the alveoli of the lungs

• At rest, no change in the volume of the thoracic cavity
• ~760 mmHg
• Difference in pressure is 0 mmHg (at rest)

Inhalation
- Decreases intrapulmonary pressure relative to atmospheric pressure

Exhalation
- Volume decreases, intrapulmonary pressure increases → air flows out

Question 4

Describe Intrapleural pressure involved in pulmonary ventilation

Answer 4

Pressure within the pleural cavity

~756 mmHg
Lower than atmospheric and intrapulmonary pressure (subatmospheric) (Decrease pressure)
Due to elastic lung
Difference -4 mmHg

Question 5

Describe the processes of inhalation

Answer 5

During deep forceful inhalation accessory muscles of inhalation participate to increase size of thoracic cavity

  - Sternocleidomastoid – elevate sternum
  - Scalenes – elevate first two ribs

During quiet breathing contraction of diaphragm and external intercostals expands thoracic cavity (Air flows into lungs & Diaphragm contracts )

Decreases intrapulmonary pressure relative to atmospheric pressure

Air flows down pressure gradient

Pressure outside is greater = which means travel from outside to inside (Air pressure within lungs is lower than atmospheric pressure )

Question 6

Describe the processes of exhalation

Answer 6

Deep Exhalation
During forceful breathing is active process
- Muscles of exhalation increase pressure in abdomen and thorax
- Abdominals
- Internal intercostals

Passive process during quiet breathing

Relaxation of muscles (Diaphragm relax)

Thoracic volume decrease; lungs recoil

Elastic recoil of chest wall and lungs, due to:

• Recoil of elastic fibres
• Inward pull of surface tension of alveolar fluid

Volume decreases, intrapulmonary pressure increases → air flows out (Air pressure within lungs rises above atmospheric pressure)

Question 7

Describe the factors that affect pulmonary ventilation

Answer 7

1. Lung compliance
   
   • How much effort (force) required to deform a body e.g. stretch or distend lungs (i.e. ΔV/ ΔP)
   • Most work due to overcoming resistance of elastic lungs and thoracic cage to stretching
   • Less compliant → more work ( ↑ pressure) required to produce a given degree of inflation
2. Elastance (=Elasticity)
   
   • Inverse of compliance; how readily lungs rebound after being stretched; i.e. natural tendency to collapse
   • Due to elastic fibres and surface tension
   • If Compliance goes up, elastance goes down, If Elastance goes up, compliance goes down
   • Needs some surface tension to move lungs inwards
3. Surface tension of alveolar fluid
   
   • Surfactant reduces surface tension of water
   • Low surface tension increases compliance & decreases elastance
4. Airways resistance
   
   • Airflow inversely proportional to airway resistance
   • Primary determinant of resistance is radius of conducting airways

Question 8

Identify the various lung volumes

Answer 8

Tidal (~500 ml)
- Volume of air entering or leaving lungs during a single breath

Inspiratory reserve (~3100 ml)
- Extra volume of air that can be maximally inspired over and above the typical resting tidal volume

Expiratory reserve (~1200 ml)
- Extra volume of air that can be actively expired by maximal contraction beyond the normal volume of air after a resting tidal volume

Residual (~1200 ml)
- Minimum volume of air remaining in the lungs even after a maximal expiration

Question 9

Identify the various lung capacities

Answer 9

Inspiratory (~3600 ml)
- Maximum volume of air that can be inspired at the end of a normal quiet expiration (IC = IRV + TV)

Functional residual (~2400 ml)
- Volume of air in lungs at end of normal passive expiration (FRC = ERV + RV)

Vital (~4800 ml)
- Maximum volume of air that can be moved out during a single breath following a maximal inspiration (VC = IRV + TV + ERV)

Total lung (~6000 ml)
- Maximum volume of air that the lungs can hold (TLC = VC + RV)

Question 10

Understand the concepts respiratory minute volume, alveolar ventilation & anatomic dead space

Answer 10

Respiratory minute volume

• Amount of air moved into & out of lung per minute
• Respiratory rate x Tidal volume
• Also called Pulmonary Ventilation

Alveolar ventilation

• Relative rate & depth of breathing determine efficiency of alveolar ventilation
• Respiratory Rate x (Tidal Volume – Anatomical Dead Space)

Anatomic dead space

• Fresh air in conducting airways (trachea, bronchi & bronchioles) does not participate in gas exchange
• Known as anatomic dead space (physical limitation)

Question 11

What is the function of pleura

Answer 11

• Allow optimal expansion and contraction of the lungs during breathing
• The pleural fluid acts as a lubricant, allowing the parietal and visceral pleura to glide over each other friction free

Question 12

Lung compliance that affect pulmonary ventilation

Answer 12

Lung compliance

 - How much effort (force) required to deform a body e.g. stretch or distend lungs (i.e. ΔV/ ΔP)
 - Most work due to overcoming resistance of elastic lungs and thoracic cage to stretching
 - Less compliant → more work ( ↑ pressure) required to produce a given degree of inflation

Question 13

Elastance (=Elasticity) affect pulmonary ventilation

Answer 13

Elastance (=Elasticity)

 - Inverse of compliance; how readily lungs rebound after being stretched; i.e. natural tendency to collapse
 - Due to elastic fibres and surface tension
 - If Compliance goes up, elastance goes down, If Elastance goes up, compliance goes down
 - Needs some surface tension to move lungs inwards

Question 14

Surface tension affect pulmonary ventilation

Answer 14

Surface tension of alveolar fluid

 - Surfactant reduces surface tension of water
 - Low surface tension increases compliance & decreases elastance

Question 15

Airways resistance affect pulmonary ventilation

Answer 15

Airways resistance

 - Airflow inversely proportional to airway resistance
 - Primary determinant of resistance is radius of conducting airways

Question 16

The difference between obstructive & restrictive lung diseases

Answer 16

Obstructive lung diseases

• characterised by a difficulty to expire
• Emphysema
• Asthma
• Bronchitis

Restrictive lung diseases

• characterised by a difficulty to inspire
• Respiratory distress syndrome
• Lung fibrosis

Question 17

The relationship among lung volumes and capacities

Answer 17

Lung volumes

• Known as respiratory volumes.
• Refers to the volume of gas in the lungs at a given time during the respiratory cycle

Lung capacities
- Derived from a summation of different lung volumes.