• True incidence is difficult to estimate because many cases are subclinical or misdiagnosed. Autopsy series suggest myocarditis in 1–9% of routine post-mortem examinations.
• Estimated global incidence: ~10–22 cases per 100,000 persons per year.
• Accounts for approximately 10–20% of sudden cardiac death in young adults and athletes under 40 years old.
• It is an important cause of new-onset, unexplained heart failure — approximately 9% of dilated cardiomyopathy cases are attributed to prior myocarditis ^[4].

• In Hong Kong, as in other developed regions, viral myocarditis is the most common form.
• Most common causes in Northern America and Europe (and Hong Kong): Adenovirus, Echovirus, and Coxsackie virus ^[5].
• Rest of the World: Trypanosoma cruzi (Chagas disease) and Corynebacterium diphtheriae (Diphtheria) — very common in South America ^[5].
• COVID-19-associated myocarditis became a recognized entity during the pandemic, with cardiac MRI showing involvement in up to 78% of recovered patients with ongoing inflammation in 60% ^[6].
• Post-mRNA-vaccination myocarditis (particularly with BNT162b2/Comirnaty and mRNA-1273) was recognized as a rare adverse event, predominantly in young males after the second dose, presenting 2–5 days post-vaccination. This is typically self-limiting and mild.

The heart wall has three layers (from inside out):

1. Endocardium — thin inner lining (endothelial cells + subendocardial connective tissue)
2. Myocardium — the thick muscular layer, composed of:
   • Cardiomyocytes: contractile cells arranged in a spiral pattern, connected by intercalated discs containing gap junctions (allow electrical coupling) and desmosomes (mechanical coupling)
   • Conduction system cells: specialized cardiomyocytes (SA node, AV node, His bundle, bundle branches, Purkinje fibres)
   • Interstitium: fibroblasts, collagen, and capillary network
3. Epicardium (visceral pericardium) — outermost layer continuous with the pericardial sac

The myocardium is responsible for:

This explains why myocarditis can present as heart failure, arrhythmia, ACS-mimic, or sudden death — depending on which function is most disrupted.

1. Viral entry: Cardiotropic viruses (e.g., Coxsackie B, Adenovirus) bind to specific surface receptors on cardiomyocytes:

   • Coxsackievirus-Adenovirus Receptor (CAR): a transmembrane protein normally involved in cell-cell adhesion at intercalated discs
   • Decay-Accelerating Factor (DAF/CD55): a complement regulatory protein — used as co-receptor
   • Parvovirus B19 uniquely targets endothelial cells (not myocytes) via globoside (P antigen) → endothelial dysfunction and secondary ischaemia

2. Direct cytopathic effect: Viral replication within myocytes → disruption of cytoskeletal proteins (dystrophin is cleaved by enteroviral protease 2A) → myocyte necrosis and release of intracellular contents (troponin, CK).

3. Innate immune activation: Damage-associated molecular patterns (DAMPs) from necrotic myocytes + pathogen-associated molecular patterns (PAMPs) activate:

   • Toll-like receptors (TLRs) on resident macrophages and dendritic cells
   • NK cell killing of infected myocytes
   • Type I interferon response → antiviral state

1. T-cell mediated immunity:

   • Dendritic cells present viral antigens (and also exposed self-antigens like cardiac myosin, released from damaged myocytes) to CD4+ and CD8+ T cells
   • CD8+ cytotoxic T cells kill virus-infected myocytes (this is necessary to clear virus but also causes collateral damage — the classic "friendly fire" problem)
   • CD4+ helper T cells activate B cells to produce neutralizing antibodies

2. Molecular mimicry: This is the critical concept — viral antigens share structural homology with cardiac proteins:

   • Coxsackie B → shares epitopes with cardiac myosin heavy chain
   • Antibodies and T cells raised against viral antigens cross-react with host cardiac proteins
   • This is exactly the same mechanism as in acute rheumatic fever (where anti-M protein antibodies from GAS cross-react with cardiac proteins) ^[7]

3. Cytokine storm: Pro-inflammatory cytokines (TNF-α, IL-1β, IL-6, IFN-γ) amplify inflammation → further myocyte damage + interstitial oedema

1. If immune response is effective and proportionate:

   • Virus is cleared, inflammation resolves
   • Myocyte regeneration is limited (cardiomyocytes have very low proliferative capacity)
   • Fibrosis replaces necrotic areas → may be clinically silent or cause minor residual dysfunction
   • Most patients recover at this stage

2. If immune response is excessive or persistent:

   • Ongoing autoimmune attack (antibodies against cardiac myosin, β1-adrenergic receptors, etc.)
   • Persistent viral genome in myocardium (viral persistence without active replication)
   • Progressive myocyte loss → ventricular dilatation → neurohormonal activation (RAAS, SNS) → further remodelling
   • End result: dilated cardiomyopathy (DCM) — this is the myocarditis → DCM pathway that accounts for ~9% of DCM ^[4]

3. Fibrosis and electrical remodelling:

   • Patchy fibrosis disrupts the normal electrical syncytium → creates re-entry circuits → ventricular arrhythmias
   • Inflammatory oedema/granulomas in the conduction system → AV block (especially in Lyme disease, sarcoidosis, giant cell myocarditis)

The Dallas criteria remain the standard for histological classification of endomyocardial biopsy (EMB):

In neonates and infants, the presentation differs:

The variability in presentation is explained by:

1. Amount of myocardium affected: Focal inflammation → subclinical; diffuse → fulminant
2. Location of inflammation: Conduction system → heart block; free wall → pump failure; subepicardial → pericarditis
3. Vigour of immune response: Brisk immune response → fulminant but may recover; smouldering → chronic DCM
4. Patient's baseline cardiac reserve: Young athlete → may tolerate ↓EF initially; elderly with comorbidities → decompensates early

This is the most common diagnostic dilemma. A young patient with chest pain, troponin elevation, and ST-segment changes — is it MI or myocarditis?

When myocarditis presents as unexplained new heart failure — especially in a young patient — the differential includes all causes of dilated cardiomyopathy (DCM) and acute heart failure.

Both cause conduction defects (especially AV block), ventricular arrhythmias, and LV dysfunction. Sarcoidosis has non-caseating granulomas on biopsy, often with bilateral hilar lymphadenopathy on CXR, ↑ACE levels, and characteristic MRI pattern (patchy mid-wall or epicardial LGE, often basal septum). The conduction disease in sarcoidosis is often out of proportion to the degree of LV dysfunction.

Both are "myocarditis" but giant cell myocarditis is rapidly fatal without immunosuppression (median survival 5.5 months). Suspect if: new-onset HF of 2 weeks – 3 months with dilated LV and new ventricular arrhythmia, 2nd or 3rd degree heart block, or failure to respond to usual care within 1–2 weeks ^[1][2]. This is an indication for EMB.

When myocarditis is part of a systemic condition, the other system manifestations provide the diagnostic clue:

Clinically suspected myocarditis requires ≥1 clinical presentation + ≥1 diagnostic criterion from investigations, in the absence of obstructive CAD and other conditions that could explain the presentation.

Clinical presentations (at least one):

• Acute chest pain (pericarditic or pseudo-ischaemic)
• New-onset (days to 3 months) or worsening dyspnoea at rest or on exertion ± signs of LHF/RHF
• Subacute/chronic (> 3 months) dyspnoea ± signs of LHF/RHF
• Palpitations ± arrhythmia symptoms ± syncope ± aborted SCD
• Unexplained cardiogenic shock

Diagnostic criteria from investigations (at least one):

• ECG/Holter/stress test abnormalities (new ST/T changes, AV block, arrhythmias)
• Elevated myocardial biomarkers (cTnT/cTnI, CK-MB)
• Functional/structural abnormalities on echo or CMR (new or unexplained LV/RV dysfunction, regional/global wall motion abnormalities)
• CMR tissue characterisation consistent with myocarditis (Lake Louise criteria — see below)

Plus: exclusion of obstructive CAD (by angiography or CT coronary angiogram), valvular disease, and other known causes that could fully account for the presentation.

The Dallas criteria are the histological standard applied to endomyocardial biopsy (EMB) specimens ^[1][2][4]:

On follow-up biopsy (if performed):

• Ongoing/persistent: continued active or borderline myocarditis
• Resolving/healing: reduction in inflammatory infiltrate ± fibrosis
• Resolved/healed: no inflammatory infiltrate; interstitial fibrosis may remain

The Dallas criteria alone have poor sensitivity (sampling error) and poor inter-observer agreement. The immunohistochemical criteria provide a more objective quantification ^[1][2]:

• Abnormal inflammatory infiltrate defined as ≥ 14 leucocytes/mm² including up to 4 monocytes/mm² with presence of CD3-positive T-lymphocytes ≥ 7 cells/mm² ^[1][2]
• Myocarditis can be classified based on the type of inflammatory cell infiltrate: lymphocytic, eosinophilic, polymorphic, and giant cell myocarditis ^[1][2]

Why IHC matters: it uses specific antibodies (anti-CD3 for T cells, anti-CD68 for macrophages) to precisely identify and count inflammatory cells, reducing inter-observer variability and improving sensitivity over H&E-stained Dallas criteria alone.

The Lake Louise criteria are the non-invasive diagnostic standard for myocarditis on cardiac MRI. The 2018 update introduced parametric mapping (T1 and T2 mapping) alongside the original criteria, significantly improving diagnostic accuracy.

Diagnosis requires at least one criterion from each of two categories:

Supportive criteria:

• Changes in ventricular size and geometry ^[1][2][16]
• Regional or global wall motion abnormalities ^[1][2][16]
• Pericardial effusion

ECG is NOT diagnostic — it can be normal and shows non-specific abnormalities ^[1][2][16]. However, it is the first-line test obtained in all patients with cardiac symptoms and provides important clues.

Echocardiography is indicated to detect impaired ventricular function and left ventricular dilatation ^[1][2]. It is the first-line imaging modality because it is bedside, non-invasive, and rapidly available.

Cardiac MRI enables detection of features of myocarditis ^[1][2] and is considered the best non-invasive test for confirming the diagnosis. The Updated Lake Louise Criteria (2018) are applied.

How to interpret the LGE pattern — the most discriminating feature:

CT coronary angiogram / cardiac catheterization: to R/O clinically significant CAD ^[3][8][11]

Why is this step essential? Diagnosis of viral myocarditis presenting as dilated cardiomyopathy requires excluding coronary artery disease via catheterization ^[8]. You cannot diagnose myocarditis without first ruling out the most common cause of troponin elevation + LV dysfunction — which is ischaemic heart disease.

Heart transplantation is the final option for patients with:

• Intractable ventricular arrhythmias / heart failure: LVAD / heart transplant ^[18]
• Refractory cardiogenic shock despite MCS
• Progressive DCM with NYHA class III–IV symptoms despite maximal therapy
• Giant cell myocarditis refractory to immunosuppression (recurrence in transplanted heart occurs in ~20–25%, but can be managed with immunosuppression)

Indications (general for HF, applicable to myocarditis-related DCM) ^[16]:

• ICD indicated in patients with life expectancy > 1 year with good functional status who have haemodynamically not tolerated VT/VF, or NYHA Class II–III HF symptoms and LVEF ≤35% despite optimal GDMT for ≥3 months ^[16]
• CRT indicated in patients with symptomatic HF with LVEF ≤35% and widened QRS particularly with LBBB configuration ^[16]

The transition from myocarditis to DCM represents a failure to heal:

1. Phase 3 failure (as discussed in pathophysiology): If the immune response does not resolve — either because of viral persistence, ongoing autoimmunity (molecular mimicry), or inadequate viral clearance — there is continued myocyte loss over weeks to months.
2. Myocyte replacement by fibrosis: Dead cardiomyocytes cannot regenerate (cardiomyocytes have negligible proliferative capacity in adults). They are replaced by collagen scar tissue laid down by fibroblasts.
3. Neurohormonal activation: ↓CO from myocyte loss → activation of RAAS (angiotensin II, aldosterone) and SNS (noradrenaline). These systems initially compensate (↑HR, ↑contractility, ↑preload, ↑afterload) but are maladaptive chronically → further myocyte death, hypertrophy, fibrosis, and apoptosis.
4. Ventricular remodelling: Progressive loss of contractile tissue + fibrosis + neurohormonal stimulation → the ventricle dilates and becomes spherical → wall stress increases (Laplace's law: wall stress = pressure × radius / 2 × wall thickness) → further dilatation → vicious cycle.
5. End-stage: A thin-walled, dilated, poorly contractile ventricle — the hallmark of DCM.

• ~9% of all DCM cases are attributable to prior myocarditis ^[4] — making it the third most common cause after idiopathic/familial (~50%) and ischaemic (~7%)
• Chronic myocarditis (both "chronic active" and "chronic persistent" forms) leads to chronic HF ^[11]
• The chronic phase: dilated heart with evidence of fibrosis — not everyone goes through all phases ^[19]
• Risk factors for progression to DCM: persistent LGE on cardiac MRI (scar), persistent LV dysfunction at 3–6 months, giant cell histology, viral persistence on EMB PCR
• Prognosis: once DCM is established, 5-year mortality is ~20%. Management follows standard HFrEF guidelines

Fulminant myocarditis: Shock, HF, dyspnea, severe rhythm disturbances, SCD from HF or recovery ^[11].

• VT/VF: The most common mechanism. Inflamed myocardium → electrical instability → VT degenerating to VF → cardiac arrest → death within minutes if not defibrillated
• Complete heart block with asystole: If the conduction system is severely affected → no ventricular escape rhythm → asystole
• Electromechanical dissociation (PEA): Massive myocardial inflammation → coordinated electrical activity but no effective contraction

• Young athletes (exercise + catecholamines + inflamed myocardium = perfect storm for VT/VF) — this is why no exercise for 3–6 months after myocarditis ^[18]
• Patients with fulminant presentation
• Giant cell myocarditis (median survival 5.5 months without immunosuppression)
• Patients with persistent ventricular arrhythmias
• Those who ignore activity restrictions during the acute phase