WEEK 2: Physiological consequences of lung disease

Question 1

What are obstructive lung diseases?

Give examples.

Answer 1

Obstructive lung diseases are a group of respiratory conditions characterized by a persistent airflow limitation, making it difficult for individuals to exhale air from their lungs.

COPD, Asthma, Bronchiectasis

Question 2

Define restrictive lung diseases.

Give examples.

Answer 2

Restrictive lung diseases are a group of respiratory conditions characterized by a reduced expansion of the lung tissue, leading to decreased lung volume and impaired ability to inhale air.

EXAMPLES
1. Interstitial Lung Disease (ILD):
*ILD refers to a group of disorders that cause inflammation and scarring of the interstitium, which is the tissue that supports the air sacs in the lungs.

2. Pneumoconiosis:
   *This term refers to lung diseases caused by the inhalation of various types of dust, such as coal dust (coal worker’s pneumoconiosis), silica dust (silicosis), and asbestos fibers (asbestosis). These particles can lead to inflammation and fibrosis of the lung tissue over time.
3. Neuromuscular Disorders:
   *Conditions that affect the nerves and muscles involved in breathing can lead to restrictive lung disease. Examples include muscular dystrophy, amyotrophic lateral sclerosis (ALS), and myasthenia gravis.
4. Thoracic Cage Abnormalities:
   *Structural abnormalities of the chest wall, spine, or respiratory muscles can restrict lung expansion. Conditions like kyphosis, scoliosis, and ankylosing spondylitis can contribute to restrictive lung disease.
5. Obesity-Related Lung Disease:
   *Severe obesity can lead to reduced lung expansion due to the increased pressure on the diaphragm and chest wall.

Question 3

Outline Structural difference between obstructive and restrictive lung disease.

Answer 3

In obstructive lung disease
*Airways are affected
*Premature closure of the airways
*Air Trapping: Incomplete exhalation of air during breathing due to narrowed airways and loss of elastic recoil.
*Residual volume increased
*Lung parenchyma may/may not be affected

In restrictive lung disease
*Airways are not affected
*Lung parenchyma affected
*Reduced Lung Compliance:
*Decreased Total Lung Capacity:
*Reduced lung tissues (fibrosis)

General Differences:
1. Airflow vs. Lung Expansion:
Obstructive diseases primarily affect airflow and the ability to exhale.
Restrictive diseases primarily affect lung expansion and the ability to inhale.

2. Location of Pathology:
   Obstructive diseases often involve the large airways (bronchi).
   Restrictive diseases affect the lung parenchyma, interstitium, or chest wall.
3. Reversibility:
   Obstructive diseases may show partial reversibility with bronchodilators.
   Restrictive diseases are generally not reversible, as the primary issue lies in the lung tissue itself.

Question 4

Outline Features of obstructive lung disorder.

Answer 4

OBSTRUCTIVE

*FEV1 is less than normal predicted values
*FVC may be normal or slightly reduced.
*FEV1%FVC is less than 75
*Static lung volumes are elevated
*Increased work of breathing during expiration

Question 5

Outline the complications/ consequences of obstructive lung diseases.

Answer 5

Consequences:
1. DECREASED Air flow (DECREASED FEV1, PEF).
INCREASED work of breathing&raquo_space;»resp muscle fatigue&raquo_space;» respiratory failure.

2. DECREASED PaO2, INCREASED PaCO2&raquo_space;» PHT&raquo_space;» cor pulmonale (Right heart failure).

Question 6

Outline Features of Restrictive lung disorder.

Answer 6

RESTRICTIVE

Small lung due to:
*Fibrotic lung parenchyma, stiff lung
*Pleural diseases, effusion, tumors, emphysema
*Restricted chest movements
*Cosmetics

Lung volumes:
Static lung volumes reduced.
Dynamic lung volumes [FEV1) and FVC proportionately reduced.
FEV1%FVC =>75

Question 7

Describe Lung volumes in obstructive lung diseases.

Answer 7

1. Tidal Volume (TV):
   Normal or slightly increased.
2. Inspiratory Reserve Volume (IRV):
   Decreased due to difficulty inhaling deeply.
3. Expiratory Reserve Volume (ERV):
   Significantly reduced due to air trapping during expiration.
4. Residual Volume (RV):
   Increased because of difficulty expelling air completely.
5. Vital Capacity (VC):
   Reduced, primarily due to decreased expiratory reserve volume.
6. Total Lung Capacity (TLC):
   Increased due to elevated residual volume.
7. Functional Residual Capacity (FRC):
   Increased due to air trapping.
8. Forced Expiratory Volume in 1 second (FEV1):
   Decreased, indicating reduced expiratory flow rates.
9. Forced Vital Capacity (FVC):
   Decreased, contributing to a decreased vital capacity.
10. FEV1/FVC Ratio:
    Decreased, reflecting airflow limitation.

10.Air Trapping:
Hyperinflated state due to increased TLC and RV.

Question 8

Describe Lung volumes in restrictive lung diseases.

Answer 8

Everything is reduced, the curve is smaller.

Question 9

Define hypoxemia.

Answer 9

Reduction PaO2 below 60 mm Hg.

Question 10

Outline causes of hypoxemia.

Answer 10

Causes:
*Hypoventilation

*Diffusion impairment

*Shunts

*Ventilation/perfusion imbalance

Question 11

Define hypercapnia.

Answer 11

Elevated PaCO2 above 49 mm Hg.

Question 12

Outline causes of hypercapnia.

Answer 12

Causes
Hypoventilation
Ventilation perfusion imbalance

Question 13

Outline causes of hypoventilation.

Answer 13

Related to respiratory centre
Related to spinal cord injuries
Related to cranial nerves damage
Related to muscles of respiration (diaphragm)
Related to damaged lung tissues

Question 14

Describe features of hypoventilation

Answer 14

-Reduced PaO2
-Raised PaCO2 (respiratory acidosis)
-Hypoventilation
-Elevated plasma bicarbonate
-Hypoxemia that can be corrected by administration of enriched oxygen

*Beware of chronic hypoventilation as PaCO2 may be elevated more!

Question 15

Outline membrane factors that result in Diffusion impairment.

Answer 15

Membrane factors

1. Thickness
   Asbestosis, oedema
2. Solubility coefficient
   CO2 is readily soluble in the matrix than O2.
3. Partial pressure gradient
   Higher gradient enhances gas exchange.
4. Molecular weight
   Inverse relation to the square root of the molecular weight.

**Significance: Oxygen (O2) has a lower molecular weight than carbon dioxide (CO2), contributing to its faster diffusion across the alveolar-capillary membrane.

Question 16

Outline blood factors influencing diffusion.

Answer 16

Blood factors

Blood as carrier of the gases influenced by:

Amount of Gas = COHbsaturation1.39 ml/min

-Type of Hb e.g. adult Hb, sickle cell, methemoglobin

-Affinity of Hb for the gases

-Carrying capacity

-Cardiac Output (heart diseases, exercise)

Question 17

Outline circulation factors influencing diffusion.

Answer 17

Circulation factors
1. Perfusion
Emboli, PCO2, PO2

2. Arterio-venous pressure difference
   Arterial vs venous partial pressure
3. Cardiac Output
   HR, SV

Question 18

Describe features of diffusion impairment caused by circulation factors.

Answer 18

Features

*PAO2 is normal
*PaO2 and PvO2 are reduced
*PACO2 normal

*Breathing frequency is increased
*Enriched oxygen improves hypoxemia
*Exercise makes worse

Question 19

What is a shunt?

State the effect of a shunt on diffusion impairment.

Answer 19

Refers to a situation where blood bypasses the normal, oxygen-rich pathways in the lungs, resulting in a mismatch between ventilation (air reaching the alveoli) and perfusion (blood flow through the pulmonary capillaries).

This condition can lead to decreased oxygenation of the blood.

Results in deoxygenated blood being shunted to the systemic circulation without going through the lungs for oxygenation.

Question 20

Outline examples of shunts.

Answer 20

Examples:
Congenital heart diseases [ASD]
Arterio-venous fistula [anastomosis]
Passage of blood through collapsed lung

Question 21

Describe features of hypoxemia due to shunts.

Answer 21

-PaO2 is reduced

-PaCO2 is normal or reduced.

-PvO2 reduced

-Exercise may or may not affect

-Required highly enriched oxygen administration to improve hypoxemia

Question 22

What is Ventilation/perfusion?

State the normal value.

What does it mean?

Answer 22

Is a ratio of ventilation to perfusion.
Normal value is about 0.9.

Ventilation (V):

*Refers to the amount of air reaching the alveoli (small air sacs in the lungs) during each breath.

-It represents the process of breathing and the delivery of fresh air to the lungs.

Perfusion (Q):
*Refers to the blood flow through the pulmonary capillaries surrounding the alveoli.

-It represents the delivery of deoxygenated blood to the lungs for oxygenation and the removal of carbon dioxide.

Question 23

Ventilation/perfusion Vary at different lung segment.

State the range at the apex and base of the lung.

Answer 23

Range is 0.6 at base to 3.0 at apex.

Question 24

Discuss hypoxemia due to Ventilation – perfusion imbalance.

State the causes of reduced:
*Ventilation
*Perfusion

Answer 24

Reduced alveolar ventilation
-Hypoventilation
-Occlusion of airways: embolus? Arteriosclerosis?

Reduced perfusion
-Stagnation: Increased blood pressure
-Occlusion of blood vessels

Question 25

Describe low V/Q ratio.
What is the other name for Low V/Q ratio?

Answer 25

Caused by reduced ventilation or excess perfusion
Physiological shunt

Question 26

Describe high V/Q ratio.
What is the other name for high V/Q ratio?

Answer 26

Excessive ventilation
Wasted ventilation or physiological dead space

Question 27

Describe features of ventilation-perfusion imbalance in:
*Reduced perfusion
*Reduced ventilation

Answer 27

In reduced perfusion:
*Normal or increased ventilation
*PaO2 reduced
*Enriched oxygen does not improve hypoxemia

In reduced ventilation:
*Normal perfusion
*Normal or reduced PaCO2
*Reduced PaO2

Question 28

What is hyperpnea?

Compare hyperpnea and hyperventilation.

State the effects of elevated PaCO2.

Answer 28

Hyperpnea refers to an increased depth and rate of breathing that is in response to the body’s increased demand for oxygen.

Unlike hyperventilation, which is characterized by rapid and shallow breathing often associated with anxiety or a decrease in carbon dioxide levels, hyperpnea is a physiological response to meet the increased metabolic demands of the body, such as during exercise or in response to metabolic acidosis.

Effects of elevated PaCO2

-CNS [Inert gas narcosis, sympathetic]
-Endocrine [adrenal gland]
-Respiration [respiratory centers, peripheral chemoreceptors]
-Blood circulation redistribution [brain, git, muscles, skin]
-Heart [cardiac output
-Cellular level [mitochondrial size, enzymes]

Question 29

Define Respiratory Failure (RF).

Answer 29

RF is said to be present when:
*PaCO2 is more than 55 mm Hg; or
*PaO2 is less than 60 mm Hg or

The individual MUST be breathing room air.

Question 30

Describe the classification of respiratory failure.

Answer 30

Blood gases classification

1. PaCO2 (Type I) Acute hypoxemia, Common Low PaO2, Normal or low
   (Hypoxic, hypocapnia failure, due to diseases damaging lung).

**NOTE: There is low PaCO2 and low PaO2

2. Low PaO2, high PaCO2 – (Type II) Common
   (Hypoxic hypercapnic failure due to hypoventilation)

Question 31

Discuss compensatory mechanisms in respiratory failure.

Answer 31

Blood [hemoconcentration: more RBC and hemoglobin, blood pH]

Heart [Cor pulmonale: Right heart failure as the heart pumps more]

Respiratory systems [pulmonary hypertension: the amount of pressure is increased to increased blood flow in the heart]

Kidney [excretion of H+, absorption and
regeneration of HCO3-

Plasma [hyperkalemia/hypokalemia: Due to acid base changes]