Stadium Layout
The Respiratory Structures🏟️ The Respiratory System — Two Jobs, One System
The respiratory system has two related but distinct functions: ventilation (physically moving air in and out — like the stadium's ventilation fans) and gaseous exchange (the actual movement of O₂ into blood and CO₂ out — happening in the alveoli). Students often confuse these two processes — they are not the same thing.
Breathing = ventilation (mechanical movement). Gas exchange = diffusion of gases across membranes (passive, happens automatically). You breathe to create the conditions for gas exchange, not to exchange gases directly.
👃 Nasal Cavity
- Lined with ciliated mucous membrane
- Mucus traps dust, bacteria, and particles
- Cilia sweep trapped material toward throat
- Blood vessels warm incoming air to body temperature
- Moisture added to humidify dry air
🔩 Trachea & Bronchi
- Trachea — windpipe; supported by C-shaped cartilage rings (keeps it open)
- Lined with ciliated epithelium and goblet cells (produce mucus)
- Divides into left and right bronchi at the carina
- Bronchi divide into smaller bronchioles → alveoli
🫁 Lung Structure
- Two lungs in the thoracic cavity
- Surrounded by the pleural membranes (two layers with fluid between)
- Pleural fluid reduces friction during breathing
- Bronchioles — small airways with no cartilage; lined with smooth muscle
🔵 Alveoli — The Exchange Surfaces
- Microscopic air sacs at the end of bronchioles
- Clustered like bunches of grapes
- Surrounded by a dense capillary network
- Walls: one cell thick (squamous epithelium)
- Moist inner surface — gases dissolve before crossing
⬆️ Diaphragm
- Dome-shaped muscle forming the floor of the thorax
- Contracts (flattens) during inhalation — increases thorax volume
- Relaxes (returns to dome shape) during exhalation — decreases volume
- Innervated by the phrenic nerve from the spinal cord
🦴 Intercostal Muscles
- External intercostals — contract during inhalation → ribs up and out → volume increases
- Internal intercostals — contract during forced exhalation → ribs down and in → volume decreases
- Normal quiet breathing: diaphragm does most of the work
Ventilation
Breathing Mechanics💨 Inhalation vs Exhalation — The Fans Switching Direction
Ventilation is the mechanical process of moving air in and out of the lungs. It works entirely on pressure differences — muscles change the volume of the chest cavity, which changes air pressure, which moves air. No energy is needed to exhale during normal breathing — it is passive.
| Feature | Inhalation (Breathing In) | Exhalation (Breathing Out) |
|---|---|---|
| Diaphragm | Contracts → flattens | Relaxes → domes upward |
| External intercostals | Contract → ribs up and out | Relax |
| Thorax volume | Increases | Decreases |
| Air pressure in lungs | Decreases (below atmospheric) | Increases (above atmospheric) |
| Air movement | Into lungs (down pressure gradient) | Out of lungs (down pressure gradient) |
| Energy required? | Yes — active (muscles contract) | No for normal breathing — passive (elastic recoil) |
📊 Lung Volumes — What the Numbers Mean
📏 Key Volumes
- Tidal volume — air inhaled/exhaled in one normal breath (~500mL)
- Vital capacity — max air exhaled after deepest breath (~4.5L)
- Residual volume — air always remaining in lungs (~1.5L) — lungs never fully empty
- Total lung capacity — vital capacity + residual volume (~6L)
🏃 During Exercise
- Breathing rate increases (more breaths per minute)
- Tidal volume increases (deeper breaths)
- Both controlled by the medulla oblongata detecting rising CO₂ in blood
- CO₂ level — not O₂ level — is the main driver of breathing rate
Gas Exchange
In the Alveoli🔄 Gas Exchange — Diffusion Across the Alveolar Wall
Gas exchange is the passive diffusion of O₂ from alveolar air into the blood, and CO₂ from blood into the alveolar air. It is NOT breathing — it is a consequence of breathing. Gases always move from high concentration to low concentration — this is simple diffusion, requiring no energy.
| Gas | In Alveolar Air | In Blood Entering Alveolus | Direction of Diffusion | Result |
|---|---|---|---|---|
| Oxygen (O₂) | High concentration | Low concentration (used by tissues) | Alveolus → blood | Blood becomes oxygenated |
| Carbon dioxide (CO₂) | Low concentration | High concentration (waste from tissues) | Blood → alveolus | CO₂ exhaled |
🔬 Why Exchange is so Efficient — The 4 Adaptations
Adaptations & Diseases
Structure Meets Function🚬 Smoking and the Lungs
Immediate Effects
- Nicotine → increased heart rate, vasoconstriction
- CO in smoke binds haemoglobin → less O₂ carried
- Irritants → excess mucus production in airways
- Cilia damaged → mucus not cleared (smoker's cough)
Long-term Damage
- Chronic bronchitis — persistent inflammation of bronchi; excessive mucus; blocked airways
- Emphysema — alveolar walls break down → fewer, larger air sacs → drastically reduced surface area → severe breathlessness
- Lung cancer — carcinogens in smoke cause mutations in lung cells
🌬️ Asthma — The Narrowed Corridor
Asthma involves narrowing of the bronchioles due to smooth muscle contraction and inflammation triggered by allergens (pollen, dust, exercise). Narrowed airways increase resistance — more effort needed to move air → wheezing and breathlessness. Bronchodilators (inhalers) relax bronchiole smooth muscle to widen airways.
🌱 Gaseous Exchange in Plants — Stomata
Plants also need gaseous exchange — CO₂ in for photosynthesis, O₂ and CO₂ for respiration. Exchange happens through stomata (tiny pores mainly on leaf undersides), lenticels (on stems), and the spongy mesophyll layer inside leaves (large air spaces = large surface area). Guard cells control stomatal opening — open in the day (light) for photosynthesis; close at night or in drought to prevent water loss.
| Feature | Animal Lungs | Plant Leaf |
|---|---|---|
| Exchange surface | Alveoli | Spongy mesophyll / stomata |
| Ventilation mechanism | Diaphragm + intercostals | Diffusion only (no pumping) |
| Surface area adaptation | Millions of alveoli | Spongy mesophyll air spaces |
| Gas control | Breathing rate | Stomatal opening/closing |
🎯 Ventilation Crew Inspection
Eight questions. Is your system running smoothly?