Asthma

Host predisposition includes: Genetics, Atopy, Gender, Obesity ^[1]

Environmental risk factors include allergens (indoor, outdoor, occupational), environmental tobacco smoke, outdoor air pollution, infection, and other triggers (exercise, cold air) ^[1][2]

This is a proposed explanation for why atopy and asthma are increasing in developed countries ^[4]:

• Observation: Childhood microbial exposure (larger family size, older siblings, day care attendance, farm animal contact, drinking unpasteurized milk, pet keeping) is associated with ↓ allergy and asthma.
• Mechanism: Reduced childhood Th1 activation (from fewer infections) → poor Th1 development → hyperactive Th2 system → overreaction to allergens (Type I hypersensitivity).
  • Remember the Th1/Th2 balance: Th1 (IFN-γ, IL-12) fights intracellular pathogens; Th2 (IL-4, IL-5) drives IgE and eosinophil responses. They reciprocally inhibit each other. If Th1 is under-stimulated in childhood, Th2 dominates.

• Asthma is primarily a disease of the small airways (bronchi and bronchioles, typically airways < 2 mm diameter), though larger airways are also involved.
• Layers of the airway wall (from inside out):
  1. Mucosa: pseudostratified ciliated columnar epithelium with goblet cells → produces mucus; cilia beat in coordinated waves to clear mucus (mucociliary escalator)
  2. Basement membrane: in asthma, this undergoes sub-epithelial fibrosis (thickening due to collagen deposition — a key feature of airway remodelling)
  3. Lamina propria: contains inflammatory cells (eosinophils, mast cells, lymphocytes in asthma)
  4. Smooth muscle layer: in asthma, undergoes hypertrophy and hyperplasia → exaggerated bronchoconstriction
  5. Submucosa: contains mucous glands (undergo hyperplasia in asthma → mucus hypersecretion)
  6. Adventitia: connective tissue

• Small airways lack cartilaginous support → they rely on radial traction from surrounding alveolar attachments to stay open.
• When inflammation causes mucosal oedema, smooth muscle contraction, and mucus plugging, small airways collapse easily → this is where the obstruction predominantly occurs.
• Expiratory airflow limitation: during expiration, positive intrathoracic pressure compresses airways. In asthma, the narrowed airways close prematurely → air trapping → hyperinflation.

Understanding this explains why certain drugs work:

• Individuals with no evidence of atopy (normal IgE, negative skin prick tests) ^[2][6]
• Usually adult-onset
• Often triggered by respiratory infections and inhaled air pollutants ^[2]
• Mostly eosinophilic (i.e., still responds to ICS in many cases) ^[6]
• Pathogenesis less well understood — may involve:
  • Epithelial cell-derived alarmins (TSLP, IL-25, IL-33) activating ILC2s → eosinophilic inflammation without IgE
  • Viral infection-triggered inflammation
  • Autonomic nervous system dysregulation

• Responsible for 5–15% of adult-onset asthma ^[1][2]
• Two types:
  1. Sensitizer-induced: requires a latency period (weeks to years); involves immunological sensitization (IgE-mediated or cell-mediated). Examples: isocyanates, flour dust, animal proteins, latex.
  2. Irritant-induced (Reactive Airways Dysfunction Syndrome, RADS): occurs after a single, high-level exposure to an irritant; no latency period.
• Key clinical clue: symptoms improve on days away from work (weekends, holidays) and worsen on return.

Asthma is a heterogeneous disease ^[1] — multiple phenotypes exist:

Assessment of severity of exacerbation ^[3]:

• Episodes characterized by:
  • Progressive ↑ in symptoms of SOB, cough, wheezing or chest tightness (AND)
  • Progressive ↓ in lung function or expiratory flow (PEF or FEV₁)

Characteristic respiratory symptoms: wheeze, dry cough, SOB, decreased exercise tolerance, chest tightness ^[6]

Key Symptom Patterns

• Diurnal pattern: worse at night or on waking ^[6]
  • Why? Circadian variation: cortisol levels are lowest at ~4 AM → less endogenous anti-inflammatory effect; vagal tone is highest at night → more bronchoconstriction; supine position → pooling of secretions and reduced lung volumes; sleep-related reduction in minute ventilation.
• Triggers: URTI (rhinovirus), exercise, allergens (bed sheets, pets, dust/pollen), cold air, drugs (e.g., aspirin, beta-blockers), smoking ^[6]
• Seasonal variation: symptoms may worsen during pollen season (spring/autumn) or in cold/dry weather.
• Episodic: symptom-free intervals between attacks (unlike COPD which is persistent).
• Personal or family history of atopy: eczema, allergic rhinitis, food allergy — the "atopic march" (eczema → food allergy → allergic rhinitis → asthma, typically in childhood). ^[6]

Signs of Atopy (look for these in a clinical exam)

• Allergic shiners: dark discolouration under the eyes (venous congestion from chronic nasal congestion)
• Dennie-Morgan lines: extra skin folds below the lower eyelids (associated with atopy)
• Nasal crease: transverse crease across the nose from habitual rubbing ("allergic salute")
• Nasal polyps: especially in adults with aspirin-sensitive asthma (Samter's triad)
• Eczematous skin changes: flexural lichenification (if concomitant atopic dermatitis) ^[7]

• Chronic sinusitis (Samter's triad) — asthma + nasal polyps + aspirin sensitivity
• Obstructive sleep apnoea (OSA) — upper airway inflammation; obesity link
• Obesity — both a risk factor and comorbidity
• GERD — reflux of gastric acid can trigger vagal-mediated bronchoconstriction; also, microaspiration of acid damages airway epithelium
• Allergic rhinitis — "one airway, one disease" concept; treating allergic rhinitis improves asthma control
• Anxiety and depression — common in chronic disease; can worsen symptom perception and adherence

These are conditions that may present with similar symptoms (cough, dyspnoea, wheeze) but have different underlying mechanisms:

Before diving into specific criteria and tests, let's be clear on a crucial concept:

Asthma is a CLINICAL diagnosis from history and physical examination ± spirometry ^[6]

There is no single definitive test for asthma. You diagnose it by putting together a compatible history + evidence of variable expiratory airflow limitation + exclusion of alternative diagnoses. Spirometry supports the diagnosis but a normal spirometry does NOT exclude asthma (the patient may be asymptomatic between attacks).

The diagnosis of asthma requires: ^[1]

Step 1: Compatible History

Episodes of dyspnoea, cough and wheeze ^[1]:

• Episodes may be transient or prolonged ^[1]
• Worse at night or early hours of the morning ^[1]
• Some may present as persistent cough (cough-variant asthma) ^[1]
• Triggered by exercise, allergens, cold air, URTI, laughter
• Symptom-free intervals between episodes
• ± personal/family history of atopy (eczema, allergic rhinitis)

Step 2: Evidence of Variable Expiratory Airflow Limitation

Variable airflow obstruction demonstrated by: ^[1]

• Demonstrate presence of airflow obstruction
• Improvement in FEV₁ or PEF after bronchodilator
• Diurnal variation in PEF or variation in PEF over a period of time

Step 3 (if needed): Nonspecific Airway Hyperresponsiveness

• Bronchial challenge test (not essential for diagnosis) ^[1]
• Used when clinical suspicion is high but spirometry is normal

• What it is: A simple, portable device (peak flow meter) that measures the maximum speed of expiration.
• How it's used: Patient records PEF twice daily (morning and evening) for 1–2 weeks.
• Diagnostic threshold: > 10% diurnal variability ^[2][4][6]
  • Calculated as: daily amplitude % mean = (daily max − daily min) / mean of daily max and min × 100%
• Why diurnal variation matters: Asthma characteristically shows a morning dip (worst PEF in early morning due to circadian cortisol nadir, increased vagal tone, and supine position overnight). This variability is a hallmark of the disease.
• In acute exacerbation: PEF is used for severity assessment — compare to predicted or personal best ^[3][9]:
  • PEF > 50% predicted → mild-moderate ^[3]
  • PEF ≤ 50% predicted → severe ^[3]
  • PEF < 33% predicted → life-threatening ^[3]

The GC Wheezing Case 1 lecture slide shows: PEF 80 L/min in a patient with marked SOB and diffuse expiratory wheeze ^[11] — this is critically low and indicates a severe or life-threatening exacerbation.

• Primary role: Mainly to exclude alternative diagnoses ^[2][4][6] — it does NOT confirm asthma.
• Findings in asthma:
  • Normal (most common finding, especially between attacks)
  • Hyperinflated (during acute exacerbation or chronic severe asthma) — flattened diaphragm, increased AP diameter, > 6 anterior ribs visible above diaphragm
  • ± Lobar collapse (secondary to mucus obstruction plugging a bronchus) ^[2][4]
• Findings that EXCLUDE asthma and suggest alternatives: pneumothorax, consolidation (pneumonia), cardiomegaly + pulmonary congestion (CHF), lung mass, pleural effusion, tram-track opacities (bronchiectasis)

The GC Wheezing Case 1 slide requests: "CXR — Any other Ix in this case?" ^[11] — reinforcing that CXR is part of the initial workup to rule out alternative diagnoses.

These investigations are used for phenotyping — particularly to determine if the patient has T2-high inflammation, which guides selection of biologic therapies in severe asthma ^[6]:

• Pulse oximetry (SpO₂): SpO₂ 90% is the critical threshold (sigmoid oxyhaemoglobin dissociation curve — below 90%, PaO₂ drops precipitously) ^[10]

  • MOA: estimates arterial saturation by absorption of infrared lights (2 wavelengths) according to Beer-Lambert law ^[10]
  • Pitfalls: Errors from dark skin, nail varnish, poor peripheral perfusion, abnormal Hb (COHb → falsely high, metHb → falsely high or low) ^[10]
  • Normal oxygenation (SaO₂) ≠ normal ventilation ^[10] — a patient can have SpO₂ 95% but a rising PaCO₂ (Type 2 respiratory failure). You MUST check ABG if concerned.

• ABG: Reserved for SpO₂ < 92% or life-threatening features ^[9]

Once asthma is diagnosed, ongoing assessment of asthma control guides treatment stepping ^[3][6]:

Assessment of asthma control (ACT) — Symptom control over past 4 weeks (mnemonic: 日夜藥動): ^[3]

The GC Wheezing Case 1 physical findings: Marked SOB, audible wheeze, using accessory muscles of respiration, on 24% oxygen, respiratory rate 32/min, pulse rate 102/min, BP 137/80, chest — diffuse expiratory wheeze, occasional crackles ^[11]. SpO₂ 96% on 24% oxygen, PEF 80 L/min ^[11].

How to interpret this clinically:

• RR 32 ( > 30) + accessory muscle use + tachycardia 102 → at least severe exacerbation
• PEF 80 L/min — must compare to predicted or personal best. If predicted PEF ~400 L/min, then 80/400 = 20% → PEF < 33% predicted → life-threatening ^[3]
• SpO₂ 96% on supplemental O₂ — this may mask severity; ABG should be obtained
• Occasional crackles — may indicate mucus plugging or secondary infection

The GC lecture slide identifies three pillars of asthma management: ^[1]

1. Pharmacotherapy 2. Prevention 3. Patient education

This is the exam-ready framework. Every management plan must address all three — pharmacotherapy alone without trigger avoidance and patient education will fail.

Before any drug is prescribed, the following principles must be understood ^[2][4][13]:

1. Control-based management = continuous adjustment of treatment based on ongoing assessment of asthma control (the "assess–adjust–review" cycle) ^[3]
2. Start at the appropriate step: treatment-naïve patients should start at Step 2 (or Step 3 if severe symptoms) ^[5][14]
3. Step up if control is not achieved — but always assess inhaler technique and adherence before stepping up! ^[4]
4. Step down if control has been sustained for > 3 months + low risk of exacerbation ^[5][14]
5. Review treatment every 3–6 months, aiming for the lowest treatment step that controls both symptoms and exacerbations ^[5]
6. Severity classification is retrospective — assessed from the level of treatment required to achieve control after a few months on controller therapy ^[2][4]:
   • Mild asthma: well-controlled with Steps 1 or 2
   • Moderate asthma: well-controlled with Step 3 (or 4)
   • Severe asthma: well- or poorly controlled with Steps 4 or 5

• Stop smoking — active and passive exposure
• Weight loss if obese (BMI > 30) — improves lung function and reduces inflammation
• Self-monitoring: PEF monitoring, recognizing early signs of exacerbation
• Action plan: written plan for what to do when symptoms worsen (when to increase reliever, when to start oral steroids, when to seek emergency care)
• Inhaler technique: must be demonstrated, checked, and re-checked at every visit

Measures to ↓ house dust mites: ^[2]

• Encasement of mattresses, pillows and duvets with vinyl covers
• Wash all bedding with hot water > 55°C regularly every ≤ 2 weeks
• Remove carpets and stuffed toys

Additional measures:

• Avoid/control triggers: change bed sheets and wash ≥ 60°C, regular vacuuming of floors ^[3]
• Remove or reduce pet exposure (if sensitised)
• Avoid NSAIDs/aspirin if aspirin-sensitive asthma
• Avoid beta-blockers (including eye drops for glaucoma)
• Regular physical activity (with appropriate pre-exercise reliever if needed) ^[3]
• Seasonal influenza vaccination ^[3]
• Treat comorbidities: allergic rhinitis ("one airway, one disease"), GERD, OSA, obesity ^[2]

Acute/subacute worsening in symptoms and lung function from patient's usual status ^[3]

• Viral respiratory infection (most common — rhinovirus)
• Allergen exposure, food allergy
• Outdoor air pollution, seasonal changes
• Poor adherence with controller medication

Reassessment required in ALL patients after 1 hour of initial treatment:

• Assess clinical status + response to treatment
• Lung function measurement (PEF or FEV₁)
• If satisfactory: controlled O₂ weaning, continue steroids 5–7 days, continue SABA
• If unsatisfactory: escalate (↑ SABA dose, add SAMA, consider MgSO₄, ICU referral)

Features warranting ICU care:

• Life-threatening features: drowsiness, confusion, silent chest, cyanosis, hypotension ^[2]
• Deterioration in PEF/FEV₁ ^[2]
• Worsening or persistent hypoxia or hypercapnia ^[2]
• Respiratory failure requiring IPPV ^[2]
• Respiratory or cardiorespiratory arrest ^[2]

• Trial of NIV: increasingly used but NOT as well-studied as in AE-COPD and ADHF ^[2]
• NIV is a relative contraindication in acute severe asthma — listed as "less efficacious" ^[15]
• If NIV fails → do not delay intubation and mechanical ventilation

Consider discharge when:

• Symptoms have cleared
• PEF or FEV₁ > 60% predicted/best ^[5] (some sources use > 75% ^[9])

Discharge actions:

• Prednisolone tablets for 5–7 days ^[3]
• Identify and avoid triggering factors ^[5]
• Early OPD follow-up and review long-term treatment plan and inhaler technique ^[5]
  • Mild/moderate: F/U in 3–4 months
  • Severe: ward F/U in 1 week → asthma clinic in 1 month ^[4]

• Excessive air trapping → leakage from weak spots of the pleura ^[5][14]
• First-principles explanation: During a severe asthma attack, the narrowed airways create a ball-valve mechanism — air can enter the alveoli on inspiration (when negative intrathoracic pressure pulls airways open) but cannot escape on expiration (when positive pressure compresses already-narrowed airways) → progressive air trapping → hyperinflation → alveolar overdistension → rupture of overdistended alveoli (especially marginal alveoli near the visceral pleura or perivascular spaces)
  • If air tracks into the pleural space → pneumothorax
  • If air tracks along the perivascular sheaths centrally into the mediastinum → pneumomediastinum (air may then extend into the subcutaneous tissues → subcutaneous emphysema, felt as crepitus over the neck and chest wall)
• Clinical clue: Sudden deterioration during an acute exacerbation — patient becomes acutely more breathless, develops pleuritic chest pain, hypotension, tracheal deviation (if tension pneumothorax)
• Key point: Always suspect (tension) pneumothorax if sudden deterioration in haemodynamics during an acute asthma exacerbation ^[3]

• Ventilatory failure (Type II respiratory failure) ^[5][14]
• Why Type II and not Type I?
  • Early in an asthma attack: V/Q mismatch → hypoxia with hypocapnia (hyperventilation compensates) = Type I respiratory failure
  • Late / severe: respiratory muscle fatigue from prolonged increased work of breathing → the patient can no longer maintain compensatory hyperventilation → CO₂ retention (rising PaCO₂) = Type II respiratory failure (hypoxia + hypercapnia)
  • The transition from Type I to Type II is the most dangerous phase — it signals impending cardiorespiratory arrest
• Clinical correlate: A "normal" PaCO₂ in a severely symptomatic asthmatic is a red flag (as discussed in prior sections) — it means the patient is transitioning from compensated to decompensated respiratory failure

• Predisposed by mucus accumulation and stasis airflow ^[5][14]
• Example: Pneumonia ^[5][14]
• Why? During severe asthma:
  • Mucus plugging creates stagnant pools of mucus in occluded airways → ideal culture medium for bacteria
  • Impaired mucociliary clearance — the normal mucociliary escalator is disrupted by epithelial damage from eosinophilic inflammation + mucus overproduction overwhelming clearance capacity
  • ICS use → local immunosuppression in the airways → may slightly increase risk of lower respiratory tract infections (particularly with high-dose ICS)
  • Systemic corticosteroids → generalised immunosuppression if used long-term
• Common organisms: Streptococcus pneumoniae, Haemophilus influenzae, viruses (rhinovirus triggering the original exacerbation may pave the way for secondary bacterial infection)

• The most feared complication — status asthmaticus (persistence of severe airway obstruction despite appropriate therapy) can lead to asphyxiation and death
• Mechanism: progressive air trapping → exhaustion of respiratory muscles → Type II respiratory failure → respiratory acidosis → cardiac arrhythmia → cardiorespiratory arrest
• Risk factors for fatal asthma: previous near-fatal attack (requiring intubation), hospitalisation in previous year, overuse of SABA (> 3 canisters/year), poor adherence to ICS, psychosocial factors (poor perception of dyspnoea, psychiatric comorbidity, non-compliance)

• Thick, tenacious mucus completely occludes a bronchus → air distal to the plug is absorbed → that lobe or segment collapses (atelectasis)
• Visible on CXR as lobar collapse ± volume loss on the affected side
• This was noted in the diagnosis section: CXR may show hyperinflation ± lobar collapse (secondary to mucus obstruction) ^[2]

• Can potentially lead to irreversible airway remodelling → progressive loss of lung function ^[3]
• Components (as detailed in the pathophysiology section):
  • Sub-epithelial fibrosis (collagen deposition below basement membrane)
  • Smooth muscle hypertrophy and hyperplasia
  • Goblet cell metaplasia and mucous gland hyperplasia
  • Angiogenesis
• Clinical consequence: Over time, asthma starts to behave like COPD — the airflow obstruction becomes fixed and no longer fully reversible with bronchodilators. This is the basis of Asthma-COPD Overlap (ACO) ^[2]
• Prevention: Early and adequate ICS therapy is the best strategy to prevent or slow remodelling

• Long-standing poorly controlled asthma with extensive remodelling → permanent reduction in lung function → chronic hypoxaemia ± hypercapnia
• Eventually may require supplemental oxygen (though this is far more common in COPD)

• Chronic airway inflammation and recurrent infections → transmural damage to bronchial walls → irreversible bronchial dilatation
• Seen on HRCT as tram-track opacities and signet ring sign
• Creates a vicious cycle: bronchiectasis → mucus stasis → infection → more inflammation → more bronchiectasis

• A specific complication in atopic asthmatics who become sensitized to Aspergillus fumigatus
• Results in a severe inflammatory reaction with mucoid impaction, eosinophilic infiltration, and proximal bronchiectasis
• Diagnosed by: total IgE typically > 1000 IU/mL, positive Aspergillus skin test or specific IgE, blood eosinophilia, radiographic opacities ^[5]
• Treatment: systemic corticosteroids ± itraconazole ^[5]

• Poorly controlled asthma itself can impair growth (chronic systemic inflammation, increased metabolic demands, recurrent exacerbations with oral steroid courses)
• Additionally, chronic hypoxia may impair growth hormone secretion and cellular growth