Polymyositis

To understand why PM preferentially affects proximal muscles, you need to appreciate the concept of muscle fibre type distribution and functional loading:

• Proximal muscles (shoulder girdle: deltoid, supraspinatus; hip girdle: iliopsoas, glutei, quadriceps) are rich in Type I (slow-twitch, oxidative) fibres. These fibres have abundant mitochondria and are metabolically active.
• The autoimmune process in PM involves CD8+ T-cells directly invading and destroying non-necrotic muscle fibres expressing MHC class I on their sarcolemma. Type I fibres in proximal muscles appear particularly susceptible, possibly because their high metabolic activity and MHC I upregulation make them preferential targets.
• Distal muscles are relatively spared early on but may be involved in advanced disease.

PM is an autoimmune condition. The exact trigger remains unknown, but the pathogenesis involves a combination of:

1. Genetic predisposition — HLA associations (HLA-DRB103:01, HLA-B08:01)
2. Environmental triggers — Viral infections (molecular mimicry), UV light (more DM), drugs
3. Immune dysregulation — Loss of self-tolerance → autoreactive T-cells targeting skeletal muscle

PM: Endomysial infiltration, predominantly T-cell mediated ^[1][2][3]

Key Pathophysiological Points

1. MHC Class I Upregulation: Normal skeletal muscle fibres do not express MHC class I on their surface. In PM, an unknown trigger (possibly viral or cytokine-driven) causes aberrant MHC class I expression on the sarcolemma. This is the critical initiating event — it allows CD8+ T-cells to "see" the muscle fibre as a target.

2. CD8+ T-cell-Mediated Cytotoxicity: CD8+ T-cells infiltrate the endomysium (the connective tissue sheath surrounding individual muscle fibres) and directly invade non-necrotic muscle fibres. They release perforin (punches holes in the sarcolemma) and granzyme B (enters through perforin pores and activates apoptosis). This is a classic MHC class I–restricted, antigen-specific cytotoxic response.

3. Why Endomysial, Not Perimysial?: This is the key histological distinction from DM. In PM, the T-cells home to individual fibres (endomysium). In DM, complement-mediated damage targets the perimysial blood vessels (perifascicular microangiopathy). Different immune mechanisms → different anatomical compartments targeted.

4. Muscle Enzyme Release: As muscle fibres undergo necrosis, intracellular enzymes leak into the bloodstream:

   • Creatine kinase (CK): the most sensitive and specific muscle enzyme, markedly elevated with CK > 10× upper limit of normal (ULN) ^[1][3]
   • LDH, AST, ALT: also released from damaged muscle (remember AST/ALT are not liver-specific!)
   • Aldolase: another muscle enzyme, elevated but less commonly measured
   • Myoglobin: released from necrotic fibres → can cause myoglobinuria → risk of acute kidney injury (AKI)

5. Systemic Autoimmune Features: PM does not exist in isolation. The autoimmune milieu can drive:

   • Interstitial lung disease (ILD) — especially with anti-synthetase antibodies (e.g., anti-Jo-1) or anti-MDA5
   • Arthritis — non-erosive polyarthritis
   • Raynaud phenomenon — vasospasm from immune-mediated vascular dysfunction
   • Cardiac involvement — myocarditis, conduction defects
   • Association with other CTDs — SLE, SSc, Sjögren syndrome, MCTD

Autoantibody associations (e.g. anti-Jo-1, anti-Mi-2) define homogeneous clinical subsets of disease ^[4]

The classic approach groups IIM into five categories based on clinical features:

1. Primary idiopathic polymyositis
2. Primary idiopathic dermatomyositis
3. Dermatomyositis/polymyositis associated with malignancy
4. Childhood (juvenile) dermatomyositis/polymyositis
5. Dermatomyositis/polymyositis associated with other CTDs (overlap)

Current rheumatology practice increasingly classifies IIM based on autoantibody profile, which better predicts clinical phenotype, complications, and prognosis:

^[1][2][3]

This deserves special mention because it is commonly examined and cuts across PM/DM boundaries:

Anti-synthetase syndrome = myositis (PM or DM) + any combination of:

1. Interstitial lung disease (ILD) — the most important prognostic determinant
2. Mechanic's hands — hyperkeratosis and fissuring of fingers
3. Non-erosive arthritis — symmetric small joints
4. Raynaud phenomenon
5. Fever
6. Anti-synthetase antibodies (anti-Jo-1 is the most common; others: anti-PL-7, anti-PL-12, anti-EJ, anti-OJ)

Cancer types associated with IIM in this locality: lung, breast, gastric, NPC ^[2][3]

• Nasopharyngeal carcinoma (NPC) is particularly important in the Hong Kong/Southern Chinese population due to the high endemic rate of EBV-associated NPC
• Adult form of DM is associated with malignancy in up to 60% ^[1] — while PM carries a lower but still significant cancer risk (2× risk in PM vs 5× risk in DM) ^[3]
• Temporal relationship: malignancy can be diagnosed before, with, or after diagnosis of inflammatory myopathy ^[3]
• Always perform a comprehensive malignancy screen at diagnosis and at regular intervals

This is the most commonly tested comparison:

Why is this distinction important? Because DM has a much higher malignancy association (especially NPC in HK), and the treatment response and prognosis differ. DM also has a distinct amyopathic variant (CADM) that can present with devastating ILD without any muscle weakness.

IBM: very rare in HK, proximal + distal muscle weakness, failed response to treatment; diagnosed by inclusion bodies (rimmed vacuoles) on muscle biopsy ^[2]

Why does IBM not respond to immunosuppression? Because IBM has both an inflammatory and a degenerative component (amyloid deposition, mitochondrial dysfunction). The degenerative component is not immune-mediated and therefore does not respond to steroids or immunosuppressants. Many patients initially diagnosed with "treatment-resistant PM" actually have IBM — repeat biopsy reveals rimmed vacuoles.

A crucial differential because both MG and PM cause proximal weakness without sensory loss:

Why does MG cause fatigable weakness? Because the problem is at the NMJ — antibodies block or destroy acetylcholine receptors. With repeated stimulation, the available ACh is depleted and fewer functional receptors are available → progressive transmission failure → worsening weakness. Rest allows ACh to accumulate again → temporary improvement.

PMR and PM sound similar but are fundamentally different diseases:

Why is CK normal in PMR? Because PMR is NOT a muscle disease — it is a periarticular/synovial inflammatory condition affecting the shoulder and hip girdle bursae and synovium. There is no actual muscle fibre destruction, hence no CK leak. The "proximal pain" mimics weakness because patients are reluctant to move due to pain, but on careful examination, power is preserved against resistance.

Polymyositis is a clinical diagnosis supported by investigations. Because PM is now recognised as a "diagnosis of exclusion" ^[7], formal criteria serve two purposes: (1) standardising the diagnosis for research and clinical trials, and (2) reminding clinicians to systematically confirm the key features and exclude mimics. Two main sets of criteria are used.

These are the traditional and most widely cited criteria, still commonly examined in HKUMed assessments ^[2][8].

Bohan and Peter criteria (1975): PM requires all of 1–4; DM requires any 3 in 1–4 + 5 ^[2]

2017 EULAR/ACR classification criteria for IIM: include age of onset, antibodies (only anti-Jo-1 now), different scoring with/without muscle biopsy ^[2]

This is the current international standard. It uses a probability-based scoring system rather than a simple checklist.

Key Features of the 2017 Criteria

• Total score ≥ 5.5 (without biopsy) or ≥ 6.7 (with biopsy) = probable IIM
• Total score ≥ 7.5 (without biopsy) or ≥ 8.7 (with biopsy) = definite IIM
• Once classified as IIM, a classification tree further subclassifies into PM, DM, IBM, juvenile DM/PM, or amyopathic DM

Anti-synthetase syndrome diagnostic criteria: Presence of anti-synthetase antibodies (Jo-1, PL-7, PL-12, EJ, OJ) + 2 major OR 1 major + 1 minor ^[2][8]

The mnemonic "ARM" helps remember the minor criteria ^[2].

General: CBC, L/RFT, TFT (r/o thyroid myopathy), ESR/CRP (↑↑) ^[1][3]

Muscle enzymes (CK, LDH, AST): markedly elevated with CK > 10× ULN ^[1][3]

Why is CK the best marker? CK (creatine kinase) catalyses the transfer of a phosphate group from phosphocreatine to ADP → regenerates ATP in muscle. It is highly concentrated in skeletal muscle (CK-MM isoform). When the sarcolemma is disrupted by T-cell-mediated cytotoxicity, CK leaks into the bloodstream. Because skeletal muscle CK concentration is orders of magnitude higher than in other tissues, even modest muscle damage produces a large serum CK rise.

CK as a monitoring tool: CK levels typically fall with successful immunosuppressive treatment. A rising CK may indicate disease flare — but remember, CK is normal in steroid myopathy, so a patient with worsening weakness on treatment who has a normal CK likely has steroid myopathy rather than a PM flare.

Auto-Ab: myositis-specific and myositis-associated antibodies ^[1][3][4] "Autoantibody associations (e.g. anti-Jo-1, anti-Mi-2) define homogeneous clinical subsets of disease" ^[4] The significance of a positive anti-nuclear antibodies test; Diagnostic role of the various autoantibodies in autoimmune rheumatic disease ^[11]

EMG: myopathic potentials with fibrillations ^[1][3]

EMG is the electrodiagnostic study that differentiates myopathic from neuropathic causes of weakness. It involves inserting a needle electrode into the muscle and recording electrical activity at rest and during voluntary contraction.

The Classic Triad of EMG Findings in Inflammatory Myopathy [2][6][8]

"EMG is most useful in distinguishing myopathic causes of weakness from neuropathic causes" ^[8]

Why does PM show fibrillation potentials? Fibrillations are classically associated with denervation (e.g., after nerve injury), but they also occur in inflammatory myopathy. This is because T-cell-mediated muscle fibre destruction segments muscle fibres — the surviving portions of damaged fibres lose their connection to the motor end plate and behave like denervated fibres, generating spontaneous discharges.

Why are MUAPs small, short, and polyphasic in myopathy? A motor unit normally consists of one motor neuron innervating hundreds of muscle fibres. In myopathy, many of these fibres are destroyed or non-functional. The surviving fibres fire asynchronously (polyphasic), and because fewer fibres contribute, the overall potential is smaller (low amplitude) and shorter (short duration). This is the opposite of the neuropathic pattern, where reinnervation produces large, long-duration, high-amplitude MUAPs.

Nerve conduction studies (NCS): Typically normal unless severe muscle necrosis and atrophy are present ^[6]. This is important — normal NCS helps exclude neuropathy as the cause of weakness.

± MRI: muscle inflammation, oedema, fibrosis, calcification ^[1][3] "Detects areas of muscle inflammation and oedema with active myositis, fibrosis and calcification. Assess large areas of muscle and thus avoid problems with sampling error in muscle biopsy" ^[8]

Clinical utility of MRI:

• Guides biopsy: identifies areas of active inflammation → improves biopsy yield, avoids sampling error
• Assessment of disease extent: shows distribution and symmetry of involvement
• Monitoring treatment response: serial MRI can track resolution of oedema
• Sensitive but non-specific: D/dx: muscular dystrophy, metabolic myopathy, rhabdomyolysis ^[3] — MRI cannot distinguish PM from other causes of muscle oedema on imaging alone

Thorough search for malignancies is mandatory especially in the elderly ^[4] Potential association between cancer and dermatomyositis and the rationale of cancer screening ^[11] Systemic malignancy screen: CBC, LFT, urinalysis, CXR, FOBT, Pap test, mammography, testicular self-exam, colonoscopy ± PET-CT ^[1][3]

Myositis: defined as 2 out of 3 of: ↑ muscle enzymes, EMG abnormalities, +ve muscle biopsy ^[1][3][4]

Systemic glucocorticoids: typically start prednisolone 1 mg/kg/d ^[1][3][5]

Why glucocorticoids work: Glucocorticoids broadly suppress both innate and adaptive immunity by:

• Inhibiting NF-κB → ↓ pro-inflammatory cytokines (IL-1, IL-6, TNF-α)
• Inducing lymphocyte apoptosis → ↓ autoreactive T-cells
• Stabilising lysosomal membranes → ↓ tissue damage
• Inhibiting MHC class II expression on antigen-presenting cells → ↓ T-cell activation

In PM, this dampens the CD8+ T-cell-mediated endomysial attack on muscle fibres, allowing regeneration.

Why we must taper and add steroid-sparing agents: Chronic high-dose steroids cause devastating side effects:

Search for and treat any malignancy ^[3]

• If malignancy is identified, treating the underlying cancer may lead to remission of the myositis (paraneoplastic mechanism)
• Cancer treatment takes priority; immunosuppression for myositis must be carefully balanced against cancer therapy
• Even if no malignancy is found at initial screening, continue surveillance annually for ≥ 3 years

ILD in PM is an autoimmune-driven parenchymal lung disease where the same immune dysregulation that targets skeletal muscle also targets the pulmonary interstitium. The most common histological pattern is non-specific interstitial pneumonia (NSIP) ^[13], characterised by diffuse alveolar wall inflammation and fibrosis, rather than the honeycombing pattern of UIP/IPF.

• Why anti-synthetase antibodies predispose to ILD: Anti-aminoacyl-tRNA synthetase antibodies (e.g. anti-Jo-1) target enzymes involved in protein synthesis. There is a hypothesis that these enzymes, when exposed on the surface of damaged alveolar epithelial cells or released into the extracellular space during lung injury, trigger an autoimmune response specifically directed at the lung parenchyma. Additionally, cleaved fragments of synthetases can act as chemokines, recruiting T-cells and monocytes into the lung.
• Anti-MDA5: MDA5 is a cytoplasmic RNA helicase involved in innate antiviral immunity. Anti-MDA5 antibodies are associated with clinically amyopathic DM (CADM) with very aggressive, rapidly progressive ILD ^[1][8] — this can progress to respiratory failure within weeks and has mortality rates of up to 50%.

• Dry cough, progressive dyspnoea on exertion
• Bibasal fine inspiratory crackles ("velcro" crackles) on auscultation
• Reduced FVC (restrictive pattern) and reduced DLCO on pulmonary function testing ^[16]
• HRCT: ground-glass opacities predominantly over the lower lobes; no honeycombing (consistent with NSIP pattern) ^[13][16]

Pulmonary function test shows a reduced forced vital capacity of 70% predicted and diffusion capacity of the lungs for carbon monoxide of 64% predicted. High-resolution computer tomography scan of the thorax reveals ground glass opacities predominantly over the lower lobes. There was no honeycombing. ^[16]

• Initial therapy: oral steroid or IV pulse steroid ± azathioprine, MMF ^[13]
• 2nd line: cyclophosphamide, rituximab, calcineurin inhibitor ^[13]
• Nintedanib (antifibrotic) for progressive pulmonary fibrosis
• Long-term O2 if PaO2 < 55 mmHg or SaO2 < 88% ^[13]
• Lung transplant referral for end-stage disease

The upper one-third of the oesophagus and the entire pharynx are composed of striated muscle, which is the same muscle type targeted by the autoimmune process in PM. When these muscles are weakened:

1. Impaired pharyngeal contraction → food bolus is not propelled efficiently through the pharynx → pooling in piriform sinuses
2. Impaired epiglottic closure → food/liquid enters the airway → aspiration
3. Impaired upper oesophageal sphincter opening → food sticks in the upper oesophagus → regurgitation

She has mild to moderate dysphagia upon speech therapist assessment ^[16]

The exact mechanism linking IIM and malignancy is incompletely understood, but the leading hypothesis is a paraneoplastic mechanism:

1. Tumour cells express muscle antigens (or antigens that cross-react with muscle proteins) on their surface
2. The immune system mounts a response against the tumour antigens
3. Due to molecular mimicry, the immune response cross-reacts with normal skeletal muscle → myositis
4. This explains why treating the underlying malignancy can sometimes lead to remission of the myositis

• Temporal relationship: malignancy can be diagnosed before, with, or after diagnosis of inflammatory myopathy ^[5]
• Risk is highest in the first 1–3 years after IIM diagnosis, but cancer can present years later
• Cancer risk: DM > PM (5× vs 2× general population) ^[3]
• Cancer-associated autoantibodies: anti-TIF1-γ (anti-p155/140) and anti-NXP-2 (confers a higher risk of malignancy in patients with DM and PM) ^[6][8]
• Higher risk with: older age at onset, male sex, refractory myositis, absence of myositis-specific antibodies, anti-TIF1-γ or anti-NXP-2 positivity

In Hong Kong / Southern China, NPC is an important associated malignancy because of the high endemic rate of EBV-associated NPC. Always include NPC screening (EBV VCA IgA, EA IgA, nasopharyngoscopy) in the malignancy workup for PM/DM patients in this population ^[5].

When extensive muscle fibre necrosis occurs (whether from severe active PM, rhabdomyolysis, or a disease flare), myoglobin is released from destroyed muscle fibres into the bloodstream:

1. Myoglobin is freely filtered by the glomerulus (small molecular weight, ~17 kDa)
2. In the renal tubules, myoglobin precipitates — especially in acidic urine — forming myoglobin casts that obstruct tubular flow
3. Myoglobin is also directly nephrotoxic: it releases free iron (Fe²⁺), which generates reactive oxygen species (ROS) via the Fenton reaction → oxidative damage to tubular epithelial cells
4. Result: acute tubular necrosis (ATN) → oliguric AKI

• Dark brown/cola-coloured urine
• Urine dipstick positive for "blood" but no RBCs on microscopy (because the dipstick reagent detects haem, and myoglobin contains haem)
• Massively elevated CK (usually > 10,000 U/L, sometimes > 100,000 U/L)
• Rising creatinine, hyperkalaemia (from both AKI and muscle necrosis)

• Aggressive IV hydration (normal saline) to maintain renal perfusion and urine output
• Urine alkalinisation (IV sodium bicarbonate) — raising urine pH reduces myoglobin precipitation
• Correct hyperkalaemia (cardiac monitoring, insulin-dextrose, calcium gluconate for cardioprotection)
• Renal replacement therapy (dialysis) if refractory AKI
• Treat the underlying PM flare aggressively

PM patients have an increased risk of DVT and PE due to:

1. Immobility — severe proximal weakness → bedbound → venous stasis (Virchow's triad)
2. Chronic inflammation — systemic inflammatory state activates the coagulation cascade (elevated fibrinogen, Factor VIII, von Willebrand factor) → hypercoagulability
3. Malignancy association — cancers are independent risk factors for VTE (Trousseau syndrome)
4. Endothelial dysfunction — autoimmune vasculopathy

• Thromboprophylaxis for hospitalised, immobile PM patients (LMWH, compression stockings)
• Therapeutic anticoagulation if DVT/PE diagnosed
• Maintain mobility with physiotherapy

Any patient on chronic immunosuppression (steroids, MTX, AZA, MMF, rituximab, cyclophosphamide) is at increased risk of: