Respiratory System

Ventilation • Respiration • Perfusion

Gas Laws & Gas Exchange

O₂ & CO₂ Transport

Control, PFTs & Airways (Asthma/COPD)

Respiratory Membrane

100

Define ventilation, external respiration, internal respiration, and perfusion—how do they link? [Slides: Lecture 3; Tutorial 3]

Ventilation = air in/out alveoli; external = lung gas exchange; internal = tissue gas exchange; perfusion = pulmonary blood flow. Oxygenation requires alignment (V/Q match)

100

Dalton’s law in one line and why it matters for diffusion. [Slides: Lecture 15–16; Tutorial 10–11]

Each gas has its own partial pressure; diffusion follows partial pressure gradients across the membrane.

100

Most O₂ is carried in blood how? [Slides: Lecture 25]

Bound to haemoglobin.

100

Primary brainstem site for basic respiratory rhythm + one key peripheral chemoreceptor location. [Slides: Lecture 32–34]

Medulla; carotid bodies (also aortic bodies).

100

List the three main layers and explain why thickness matters for gas exchange. [Slides: Lecture 18–19]

Alveolar epithelium (type I) → fused basement membrane → capillary endothelium; ↑thickness (oedema/fibrosis) ↓diffusion → hypoxaemia.

200

What does V/Q mismatch mean? Give one example. [Slides: Lecture 22]

V ≠ Q. Low V/Q (pneumonia); high V/Q (PE → dead space).

200

Henry’s law explains why ↑FiO₂ can ↑PaO₂. State how. [Slides: Lecture 13–14; Tutorial 12, 15–16]

Dissolved gas ∝ partial pressure → giving O₂ increases dissolved O₂ and drives diffusion.

200

Bohr effect—what shifts the O₂–Hb curve right, and what’s the tissue effect? [Slides: Lecture 25; Tutorial 13]

↑CO₂/↑H⁺(↓pH), ↑Temp, ↑2,3‑BPG → right shift → easier O₂ unloading at tissues.

200

In obstructive disease, what happens to FEV₁/FVC and why? [Slides: Lecture 10 & 35; Tutorial 18]

Ratio ↓ due to airway narrowing/air trapping → reduced rapid expiratory flow.

300

Name two physical factors that increase work of breathing and why. [Slides: Lecture 8]

↑Airway resistance (bronchoconstriction/mucus); ↓compliance (fibrosis/oedema) → larger pressure change needed for same VT.

300

Two structural features of the respiratory membrane that promote rapid diffusion. [Slides: Lecture 18–19; Tutorial 5]

Extremely thin barrier (type I alveolar cell + fused basement membrane + capillary endothelium), huge surface area, dense capillary network.

300

Most CO₂ travels as what, and where is it formed? [Slides: Lecture 28; Tutorial 14]

Bicarbonate (HCO₃⁻), formed in RBCs via carbonic anhydrase; Haldane effect supports CO₂ carriage

300

During an asthma attack, list two bedside manifestations you’d expect. [Slides: Lecture 43–44; Tutorial 20–21]

Wheeze, prolonged expiration, cough, chest tightness, accessory muscle use, tachypnoea; severe: silent chest/cyanosis/↓LOC.