Cardiomyopathy pathophysiology
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2020 AHA/ACC Guideline for the Diagnosis and Treatment of Patients With Hypertrophic Cardiomyopathy |
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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]
Overview
There are myriad different etiologies of cardiomyopathy (CM) which result in abnormal heart structure and function. Historically, CM has been grouped in three different categories grouped by phenotype or symptomatic presentation (later confirmed through echocardiographic and autopsy studies) ranging from dilated to restrictive to hypertrophic forms of CM. Emerging additional categories include arrhythmogenic right ventricular dysplasia/cardiomyopathy (ARVD/C) and Unspecified CM. Dilated and Hypertrophic CM which share symptoms of left heart failure can be distinguished by a patient's ejection fraction (EF), Left Ventricular (LV) wall thicknes,s and LV end diastolic volume (LVEDV). Restrictive CM is relatively uncommon and presents largely with Right HF symptoms and diastolic dysfunction. Some etiologies (e.g. inherited metabolic disorders, sarcoidosis, hemachromatosis, etc.) may cause more than one CM. This overlap in classification underscore the limitations of phenotypic classification system.
For this reason, and with improving technology, the American Heart Association proposed a classification of CM emphasizing primary and secondary (to other systemic diseases) etiologies. Primary CM is subdivided into genetic, acquired, and mixed causes. Genetic cause include HCM, ARVD/C, ion channel disorders, storage and infiltrative diseases. Genetics play an important and increasing role in the pathophysiology of CM. The genetic basis of Hypertrophic Cardiomyopathy (HCM) is well established. Approximately 30% of Dilated CM cases are familial. Mutations in over 40 different genes have been described (locus heterogeneity). Various mutations within those genes have produced CM (allelic heterogeneity), and the same mutation can manifest differently within different family members (incomplete penetrance). The clinical presentation of patients with cardiomyopathy can vary widely, depending on the underlying mechanism of disease. Symptoms range from exercise intolerance and progressive hearth failure to fatal arrhythmias and sudden cardiac death.
At present, treatment of CM is driven primarily by phenotype. Therefore, the discussion below will focus on this classification.
Cardiomyopathy Pathophysiology
(f)
In 2006, the American Heart Association defined Cardiomyopathies as:
"...a heterogeneous group of diseases of the myocardium associated with mechanical and/or electrical dysfunction that usually (but not invariably) exhibit inappropriate ventricular hypertrophy or dilatation and are due to a variety of causes that frequently are genetic. Cardiomyopathies either are confined to the heart or are part of generalized systemic disorders, which may lead to cardiovascular death or progressive heart failure-related disability."
Table 1 below lists the various gene products implicated in cardiomyopathy.
Genes impacting cardiomyopathy | Normal function/Consequence of abnormal gene product |
---|---|
Sarcomeric proteins | Encodes Myosin (thick filament 15nm), Actin (thin filament 7nm),Titin (elastic elements 1nm), associated regulatory proteins |
Dystrophin complex | Stabilizing and connecting the cell membrane to intracellular structures
Dystrophin supports muscle fiber strength.
Mutations → DCM c arrythmias/conduction disease |
Desmosome complexes
(Desmos - "bond", Soma - "body") |
Cell-cell connections and stability |
Remaining cytoskeletal proteins
|
Integrate & stabilize myocyte
|
Enzyme Deficiency | Fabry's disease (alpha-galactosidace A deficiency) |
Mitochondrial deficiency | Defects impair energy production causing symptoms ranging from impaired cognitive function to skeletal myopathy.
Phenotype depends on the distribution of maternal mitochondria during embryonic development |
Heritable systemic diseases with (no mutation of heart genes) | Hemochromatosis, Familial amyloidosis |
The most common modes of transmission are Autosomal Dominant, followed by X-linked inheritance. Most known inherited genetic defects to date are associated with hypertrophic CM. However, research is uncovering more and more genetic associations with dilated CM. Missense mutations are most common among all forms of CM; nonsense and frameshift mutations also contribute to dysfunctional structural and cellular metabolism proteins (see Table 1 above) causing CM.
The mutations in Sarcomere genes (coding for actin, myosin, titin, etc.) are the best characterized to date. Mutations in Titin, a large sarcomeric protein that maintains structure & participates in signaling, are the most common cause of dilated CM (approximately 20% of known cases). Severity of clinical disease is usually commensurate with an increasing number of mutations. Deletions are rare, exception for dystrophinopathies. Genetics will continue to play an increasing role in diagnosis and management of CM.
DILATED CARDIOMYOPATHY
Dilated CM is the most common CM, comprising approximately 90% of all cardiomyopathies. The many causes of Dilated CM all share the following phenotype: Enlarged heart, decreased systolic function. This results from a failed attempt to ration increasingly insufficient resources following myocyte injury below:
(f) Myocyte injury → 3 possible outcomes:
1) immediate myocyte cell death.
2) Delayed myocyte cell death by apoptosis
3) hypertrophy of the remaining myocytes to increased wall stress → hyperadrenergic response → dynamic remodeling of interstitial myocardial skeleton (including fibrosis) → decreased diastolic function, increased ventricular dilation → distortion of valvular apparatus → elevated afterload → beginning stages of CHF (Left > Right) → Repeat
Only one-third of all etiologies of dilated CM have been fully characterized, many of which have a genetic etiology. Two-thirds of dilated CM \remain classified as idiopathic, reflecting the need for further investigation. Many postulate a yet undiscovered genetic basis for many of these CM.
Important etiologies of Dilated CM are listed below in Table 1.
Subtype | Example | Notes |
---|---|---|
Inflammatory Myocarditis | (Mech of injury: Direct invasion, production of cardiotoxic substances, chronic inflammation without persistent infection) | |
Infective | Viral/Parasitic/Bacterial/Fungal/Spirochetal/Ricketsial/Fungal | |
Non-infective | Granulomatous inflammatory diseases/Eosinophilic myocarditis/Hypersensitivity myocarditis/Polymyositis-Dermatomyositis/Collagen Vascular Disease/Pregnancy/Transplant Rejection | |
Toxic | ||
Alcohol | Most common etiology, comprising >10% of cases of DM | |
Catecholamine | Amphetamines, Cocaine, Pheochromocytoma, Stress-induced CM (Takotsubo's) | |
Chemotherapeutic agents | Adramycins, Tyrosine Kinase Inhibitors | |
IFN | ||
Other therapeutic agents | hydroxychloroquine, Chloroquine, Lithium, Phenothiazine antipsychotics, antiretroviral therapies | |
Drugs of misuse | emetine AKA Ipecac, anabolic steroids | |
Heavy metals | Lead, Mercury, Cobalt (tainted beer production | |
Occupational exposure | hydrocarbons, arsenicals | |
Metabolic | ||
Nutritional deficiencies | ||
Electrolyte deficiencies | ||
Endocrinopathy | ||
Obesity | ||
Hemochromatosis | ||
Inherited Metabolic Pathway Defects | ||
Familial (30%) | Skeletal & Cardiac myopathy/Dystrophin-related dystrophy (Duchenne's, Becker's) - X-linked/Mitochondrial myopathies (e.g. Kearns-Sayre syndrome)/Arrhythmogenic ventricular dysplasia/Hemochromatosis/Associated with other systemic disease/Susceptibility to immune-mediate myocarditis | |
Overlap with Nondilated Cardiomyopathy | "Minimally dilated CM"/Hemochromatosis/Amyloidosis/Hypertrophic CM | |
Miscellaneous (Shared Elements of Above Etiologies) | ||
Arrhythmogenic Ventricular (RV>LV) dysplasia | ||
LV Noncompaction | ||
Peripartum | ||
Tachycardia-related cardiomyopathy | ||
LBBB |
- Inflammatory Myocarditis
- Infective - Mechanism of action (MOA): Direct invasion, production of cardiotoxic substances, chronic inflammation without persistent infection)
- Viral (coxsackie, adenovirus, HIV, hepatitis C. Less common: Mumps, RSV, dengue & yellow fever, Lassa fever)
- (image) Viral pathogen enters through respiratory or GI tract → Degree of Innate immune response → viruses trophic for certain organs bind specific receptors (e.g. Coxsackie to heart) → Viral replication, causing organ injury, disrupting normal function (e.g. Coxsackie cleaves dystrophin during viral myocarditis) → Host immune response (particularly adaptive) & chronic inflammation can further damage target tissue (myocardium)
- Fulminant viral myocarditis often improves with appropriate supportive care. Will show an increase in circulating viral titers between acute & recovery blood draws
- Possible subclinical acute myocarditis : labs & imaging :: Probable acute myocarditis : + in Sx (CP, Tachyarrhythmia, embolic stroke) :: Definite acute myocarditis : Biopsy positive
- Parasitic (T. cruzi -- Chagas' disease - most common. Trypanosomiasis & Toxoplasmosis.)
- Chagas' disease (autonomic dysfcn, microvascular damage → CV (SA/AV node dysfcn & RBBB, Thrombogenic small ventricular aneurysm esp at apex) & GI disease.
- Transmitted most commonly by Reduvid bug in South & Central America > Also Organ donation, Vertical transmission from mother to baby, oral.
- MOA: Direct - Parasite → myocyte lysis & neuronal damage, Indirect Chronic immune system activation
- 2 phases:
- Acute phase - Parisitemia, 95% Asx. Others nonspecific, acute myocarditis, meningoencephalits)
- Silent phase - Progress slowly in over 10-30yrs, end in CV/GI Sx. 5 yr survival <30% once CHF symptoms begin.
- Trypanosomiasis
- Transmitted by Tsetse fly
- 2 forms:
- West African form due to Trypanosoma brucei gambiense
- East African form - Trypanosoma brucei rhodensiense
- MOA: Perivascular infiltration → Myocarditis & heart failure with frequent arrhythmias.
- Toxoplasmosis
- Transmitted by undercooked pork, Cat feces, organ transplant, transfusion, Vertical Transmission (~T. cruzi)
- Immunocompromised, more likely to have reactivation of latent infection from cysts
- Myocarditis, pericardial effusion, constrictive pericarditis, CHF + chorioretinitis + encephalitis
- Dx in Immunocompetent patients : IgM positive now, IgG positive later :: Dx in Immunosuppressed patients: Positive IgG, Myocarditis
- Trichinellosis
- Trichinella larvae migrate into skeletal Mm → myalgias, weakness, fever
- Trichinellosis : Trichinella spiralis larva found in uncooked meat :: Toxoplasmosis : found in undercooked meat, Cat litter
- CHF 2/2 eosinophilic inflammatory response
- Chagas' disease (autonomic dysfcn, microvascular damage → CV (SA/AV node dysfcn & RBBB, Thrombogenic small ventricular aneurysm esp at apex) & GI disease.
- Bacterial (Diphtheria 1/2 of all cases of bacterial myocarditis. B-hemolytic strept, Tuberculosis, T. whippeli)
- Diphtheria releases a toxin that impairs protein synthesis & disrupts the conduction system.
- Rx c Antitoxin
- ß-hemolytic strept associated with Rheumatic Fever → inflammation & fibrosis of cardiac valves and systemic tissue.
- Diphtheria releases a toxin that impairs protein synthesis & disrupts the conduction system.
- Spirochetal (Borrelia burgdoferi -- Lyme disease)
- Conduction disease lasting 1-2 weeks after Abx
- Rickettsial (Q fever)
- Fungal (Candida. Hamatogenous spread or direct invasion. Rare.)
- Viral (coxsackie, adenovirus, HIV, hepatitis C. Less common: Mumps, RSV, dengue & yellow fever, Lassa fever)
- Noninfective
- MOA: secondary to Antibodies & Cytokines from prior physical injury & viral infection
- Granulomatous inflammatory disease - Ventricular arrhythmias & conduction blocks in a patient with concurrent CHF & chest pain syndrome. Idiopathic.
- Sarcoidosis
- Patients with Pulmonary Sarcoidosis at higher risk for cardiac involvement
- Thought to have an infectious or environmental trigger, as regional clustering of cases
- Inflammation resolves into areas of fibrosis that can serve as nidus for reentrant circuits.
- Fewer granulomas associated with better prognosis.
- Giant Cell myocarditis
- Rapidly progressive HF and tachyarrhythmias
- Comprise 10 - 20% of cases of biopsy positive myocarditis
- Path on endomyocardial biopsy: extensive eosinophilic infiltration
- A/w thyomomas, thyroiditis, pernicious anemia, other AID
- Rapid deterioration, urgent transplantation
- Sarcoidosis
- Infective - Mechanism of action (MOA): Direct invasion, production of cardiotoxic substances, chronic inflammation without persistent infection)
- Eosinophilic myocarditis
- E.g. Eosinophilic granulomatosis with polyangiitis (EGP, formerly Churg-Strauss), antecedent infection (Mediterranean & African countries), malignancies.
- Hypersensitivity myocarditis
- Path on endomyocardial biopsy: infiltration with lymphocytes ad mononuclear cells with a high proportion of eosinophils.
- Chronic Antibiotics, most common etiology. Others, Thiazides, Anticonvulsants, Indomethacin, Methyldopa.
- Polymyositis, dermatomyositis
- Skeletal & Cardiac Muscle affected
- Collagen vascular disease
- associated with Pericarditis, Vasculitis, Pulmonary hypertension, accelerated CAD
- Pregnancy
- Genetic predisposition: A/w some known sarcomeric protein mutations and FH of dilated CM
- Peripartum cardiomyopathy (3rd trimester through 6 months postpartum, with no prior cardiac disease)
- 1:15,000 - 1:2000 deliveries
- RF: increase maternal age, increase parity, twin pregnancy, malnutrition, Tocolytics for premature labor, Preeclampsia
- Known association with anti-angiogenic signaling (a process exacerbated by preeclampsia)
- Studies investigating proangiogenic agents as potential therapies.
- 4 additional proposed MOA given Path findings (Lymphocytic myocarditis on endomyocardial biopsy):
- increased susceptibility to viral myocarditis OR
- cross-reactivity of anti-uterine antibodies vs. cardiac muscle causing an autoimmune myocarditis
- microvascular angiogenic imbalance within myocardium
- Abnormal prolactin cleavage fragment, induced by oxidative stress, triggering myocardial apoptosis
- Dietary-induced fluid retention (e.g. salt loading after delivery in Nigeria)
- Lymphocytic myocarditis
- Cross reactivity anti-uterine & anti-cardiac Ab OR
- Abnormal prolactin cleavage fragment, induced by oxidative stress → Myocardial apoptosis
- Pregnancy-associated CM (CM occurring in 1st & 2nd trimesters)
- Transplant rejection
- Myocardial depression can quickly develop and reverse with appropriate treatment
- Largely secondary to Lymphocytes, cytokines, and antibodies
- Toxic
- Alcohol (>10% cases)
- Eti: 5-6 drinks (4 oz of pure EtOH) QS for 5-10years
- MOA: Direct toxicity of both Alcohol & its metabolite, acetaldehyde
- Genetic polymorphisms of genes encoding alcohol dehydrogenase & ACE make individuals at an increased risk of developing CM with prolonged alcohol exposure
- Complications:
- Early: Paroxysmal AFib "Holiday heart"
- Late: Persistent Afib, Withdrawal can worsen HF or arrhythmias Improvement can happen after 3-6months of abstinence
- Catecholamines: (Amphetamines, Cocaine, Pheochromocytoma, Stress-induced CM (Takotsubo's)
- MOA:
- Excess catecholamines can cause multifocal contraction band necrosis, likely secondary to calcium overload causing direct myocyte toxicity OR
- focal vasoconstriction in coronary artery in the setting of tachycardia, akin to ischemia-reperfusion with subsequent inflammation.
- often displays microinfarcts secondary to small vessel ischemia.
- Takotsubo's = older women after sudden intense emotional or physical stress + Global Ventricular dilatation with basal contraction
- Early Animal studies suggest MOA: Intense sympathetic activation with heterogeneity of myocardial autonomic innervation, diffuse microvascular spasm, &/or direct catecholamine toxicity
- MOA:
- Chemotherapeutic agents - most common drugs causing Toxic CM
- Classical: Anthracyclines, Trastuzumab
- Anthracyclines
- RF for CM: Dose dependent (cumulative life-time dose >500mg/m2), Underlying cardiac disease, concomitant chest irradiation
- (f) Anthracycline MOA: Peroxidation of lipids in myocyte membranes → Generation of ROS involving heme compounds → injury & fibrosis → vaculoar degeneration & myofibrillar loss on histology (pic) → disruption of large titin protein → loss of sarcomere organization → (repeat over time) → relatively nondilated ventricle 2/2 underlying fibrosis → reduced EF (30-40%), unable to compensate by myocyte hypertrophy 2/2 underlying fibrosis
- 3 different presentations of Anthracycline toxicity:
- Acute-onset HF after single dose
- Early-onset, dose-dependent anthracycline cardiotoxicity with resultant HF during or shortly after a chronic course (3% of patients)
- A. Rapidly progressive
- B. Partial recovery of EF
- Chronic HF
- A. Dose received before puberty: impaired development of the heart → clinical HF around age 20
- B. Dose received after puberty: gradual onset of HF Sx OR acute onset of HF following reversible 2nd hit/insult (e.g. influenza, Afib)
- If managed appropriately, patient can live for years with compensated cardiac function
- Tyrosine kinase inhibitors (e.g. Traztuzumab, Imatinib)
- RF for CM: Concurrent use with anthracyclines
- MOA: Mab that interferes with cell surface receptors important for cardiac adaptation
- Usually CM is reversible, but not always. Some patients advance to HF and death
- Anthracyclines
- Less common:
- Cyclophosphamide & Ifosfamide cardiotoxic in high doses.
- 5-FU, Cisplastin, & other Alkylating agents → coronary spasm → depressed contractility in some patients
- Classical: Anthracyclines, Trastuzumab
- IFN - can cause hypotension and arrhythmias.
- Other therapeutic agents (hydroxychloroquine, Chloroquine, Lithium, Phenothiazine antipsychotics, antiretroviral therapies)
- Drugs of misuse (emetine AKA Ipecac, anabolic steroids)
- Heavy metals: Lead, Mercury, Cobalt (tainted beer production)
- Occupational exposure: hydrocarbons, arsenicals
- Alcohol (>10% cases)
- Metabolic
- Nutritional deficiencies: thiamine, selenium, carnitine. Respond to Rx
- Beri-Beri (B1 deficiency Developing countries, EtOH, +/- teenagers c highly processed foods)
- High-output → time → low output
- Selenium -- Keshan's disease
- Post bariatric surgery
- Beri-Beri (B1 deficiency Developing countries, EtOH, +/- teenagers c highly processed foods)
- Electrolyte deficiencies: calcium, phosphate, magnesium
- Calcium:
- Hypoparathyroidism (esp postsurgical)
- Intestinal dysfcn (diarrhea, s/p resection)
- Phosphorous
- Starvation
- Refeeding
- Magnesium = cofactor for B1-dep reactions & for ATP
- Calcium:
- Endocrinopathy
- Thyroid disease
- Most common reason for thyroid abnormalities in patient with cardiac dyscrasias are treatment of tachyarrhythmias with amiodarone
- Hyperthyroidism and heart failure warrants very close inpatient monitoring, as decompensation may occur rapidly and have fatal consequences.
- Pheochromocytoma
- Heart failure with labile &/or orthostatic BP and episodic HTN
- DM
- Thyroid disease
- Obesity
- DM, HTN, Metabolic syndrome
- Independent fluid retention in obese people c impaired excretion (Rapid clearance of BNP by adipose tissue) → increase wall stress & secondary adaptive neurohormonal responsive.
- Hemochromatosis
- Primary/Hereditary
- 1 in 500 people
- AR form of HFE gene
- Low penetrance
- Secondary/Acquired
- Hemolytic anemia & transfusions
- MOA: excess iron deposited in the perinuclear compartment of cardiomyocytes, disrupting intracellular architecture and mitochondrial function
- Transferrin >60% : men :: Transferrin 45-50% : women
- Primary/Hereditary
- Nutritional deficiencies: thiamine, selenium, carnitine. Respond to Rx
- Inherited Metabolic Pathway Defects
- Familial (30%)
- MC mutation = TTN encoding titin (25% of familial disease)
- Men develop disease 1 decade b4 women.
- 8% Thick & thin filaments
- Ventricular Tachycardia & SCD a/w DESMOSOMAL proteins
- Atrial Arrhythmias, conduction disease, & CM : LAMIN mutation :: Prominent FH of SCD or Vtach before clinical CM : Desmosomal proteins
- Skeletal & Cardiac myopathy
- Dystrophin-related dystrophy (Duchenne's, Becker's) - X-linked
- Mitochondrial myopathies (e.g. Kearns-Sayre syndrome)
- Arrhythmogenic ventricular dysplasia
- RV >>> LV
- Highly arrhythmogenic
- Genetic defects in Desmosomal proteins disrupt myocyte junctions and adhesions → Areas of ventricle die and turn to fat → thinned ventricle with fibrosis
- Desmosomal mutation → Hair & skinless elastic → striking wolly hair & thickened skin on palms & soles
- Naxos syndrome = ARVC + hyperkeratosis of plantar palmar skin surfaces
- Hemochromatosis
- Associated with other systemic disease
- Susceptibility to immune-mediate myocarditis
- Overlap with Nondilated Cardiomyopathy
- "Minimally dilated CM"
- Hemochromatosis
- Amyloidosis
- Hypertrophic CM
- Familial (30%)
- Miscellaneous (Shared Elements of Above Etiologies)
- Arrhythmogenic Ventricular (RV>LV) dysplasia
- LV Noncompaction - most commonly identified on imaging
- Multiple trabeculations in L ventrical distal to papillary MM → spongy appearance of the apex + mutations in Sarcomeric gens
- Three cardinal features = Ventricular arrhythmias + embolic events + HF
- Peripartum
- Tachycardia-related cardiomyopathy
- SVT arrhythmias with uncontrolled rate
- Very frequent nonsustained Ventricular tachycardia or High PVC burden
- LBBB
HYPERTROPHIC CARDIOMYOPATHY
Hypertrophic Cardiomyopathy with or without obstruction is characterized by a thickened, hypertrophic left ventricular wall, with hyperdynamic cardiac function, and no associated hemodynamic factors (HTN, Aortic valve disease, Systemic infiltrative/storage disease).
Epidemiology and Genetics
- Disease first described in 1957.
- Prevalence 1:500 (~Hereditary hemochromatosis)
- Risk of Sudden Cardiac Death in patients with HCM is 0.5%
- Transmitted in an Autosomal Dominant pattern
- HCM is age dependent, with incomplete penetrance
- Patients developing disease later in life have fare better than those with disease in adolescence/young adulthood.
- Same mutation in related individuals can produce different phenotype
- Various patterns of pattern of hypertrophy concentric vs. asymmetric, presence or absence of outflow obstruction, development of Afib or malignant arrhythmia, SCD)
- A majority of the work on the genetics of cardiomyopathy was initially completed in this population
- With advances in genetics, linkage analyses identified sarcomeric mutations in 60% of patients with HCM.
- >1400 mostly missense mutations in 9 different genes
- Rates of sarcomeric mutations exceed 60% in patients with familial disease & asymmetric septal hypertrophy.
- 80% of HCM patients have a mutation in either ß-myosin heavy chain (MHY7) & Myosin-binding protein C (MYBPC3) gene loci encoding sarcomeric proteins
- MHY7 & MYBPC3 : Most common mutations in HCM (sarcomeric) :: V122I : Most common mutation in Amyloidosis, especially African Americans
- With advances in genetics, linkage analyses identified sarcomeric mutations in 60% of patients with HCM.
Microscopic pathophysiology
- Pathophysiology of HCM can be summarized in three aspects:
- 1) Fibrosis
- secondary to early activation of profibrotic pathways
- Interstitial fibrosis detectable before overt hypertrophy
- Focal areas of 'replacement fibrosis' detectable on MRI before hypertrophy present
- Myocardial fibroblast exaggerated response to primary myocardial dysfunction
- Areas of scarring may represent substrate for malignant ventricular arrhythmias (MCC of death in this population)
- Focal areas of 'replacement fibrosis' detectable on MRI before hypertrophy present
- Over time, fibrosis → diastolic dysfunction
- 2) Disorganized hypertrophy (predominant)
- 3) Microvascular disease
- Increased thickness + decreased luminal area of intramural vessels in thickened myocardium --> relative ischemia
- Microinfarction of hypertrophied myocardium proposed mechanism for replacement scar formation
- 1) Fibrosis
- On the individual sarcomere level, HCM mutations produce modification in regulatory proteins leading to:
- Enhanced calcium sensitivity
- Maximal force generation
- Increased ATPase activity
- This changes on a microscopic level lead to disorganized hypertrophy, causing a cycle of:
- Abnormal energetics
- Impaired relaxation
Macroscopic pathophysiology
- Nonuniform ventricular thickening
- Location of maximal hypertrophy may vary:
- IV Septum (MC)
- IV Septum : LV free wall thickness ratio of 3:1
- Concentric
- Midventricular
- Apex (Yamaguchi's syndrome)
- Less commonly familial
- Only 15% derived from sarcomeric mutations
- IV Septum (MC)
- Fibrosis, disorganized hypertrophy, and microvascular disease contribute to diastolic & contractile dysfunction along with elevated intracardiac pressures → higher wall stress & Myocardial O2 demand
- LV outflow tract (LVOT) Obstruction is present in 30% of patients at rest, 30% inducible by exercise
- (Figure) Drag forces push the anteriorly displaced & thickened anterior mitral leaflet (from fibrous endocardial plaque) in contact with hypertrophied ventricular septum → varying degrees of LVOT obstruction (Primary mechanism) PLUS
- Functional Mitral Regurgitation
- Anterior displaced MV may cause posteriorly directed regurgitant jet • PLUS
- Any cause of decreased preload (e.g. dehydration, AFib with RVR) • EQUALS
- Decreased LVEDV & Smaller chamber size
- To maintain SV across LVOT obstruction :
- Ventricle generates higher pressures → higher wall stress & myocardial O2 demand → progressive (disorganized) hypertrophy → Smaller chamber size & increased contractility → exacerbate degree of LVOT obstruction
- Presyncope & hypotension can result from decreased preload (e.g. diuretics) or decreased afterload (e.g. arterial dilators)
- Risk of Sudden Cardiac Death in patients with HCM is 0.5%
- Factors increasing risk of SCD in HCM - PS FELA:
- Prior Cardiac arrest or Spontaneous sustained VTach
- Spontaneous NSVT
- FH of SCD
- Exertional or nonvagal syncope
- LV thickness >30mm
- Abnormal BP response to exercise (failure to increase SBP to ≥120mmHg OR decline in SBP during exercise)
- Factors increasing risk of SCD in HCM - PS FELA:
- Afib is common in patients with HCM. RVR is poorly tolerated (decreased preload, decreased filling, increased myocardial O2 demand). Following AVN agents tolerated:
- Beta-blockers, Non-dihydropyridine-CCB (verapamil, diltiazem)
- Rate control may be necessary to sustain atrial kick - Amiodarone, Disopyramide
- If refractory to medical therapy: Ablation
- HCM vs. Athlete's heart: Athlete's heart ventricular hypertrophy regresses with cessation of training.
- Also, patient's have supranormal exercise capacity, mild ventricular dilation, and normal diastolic function
RESTRICTIVE CARDIOMYOPATHY
Restrictive CM is the least common CM phenotype. Characterized by the following 6 characteristics:
- Abnormal diastolic function +
- Mildly decreased contractility & EF (usually >30-50%) +
- (often massive) Biatrial enlargement +
- Modest LV dilation (LVEDV <6cm) +
- RVEDP & LVEDP both increased +
- Preservation of CO until late in the disease.
Restrictive CM MC pathophysiologies: Infiltration of abnormal substances BETWEEN myocytes + Storage of abnormal substances WITHIN myocyte + Fibrotic injury
Table 2. Major Causes of Restrictive Etiology
Subtype | Examples |
---|---|
Infiltrative (between myocytes) | Amyloidosis, Inherited metabolic defects |
Storage (within myocytes) | Hemochromatosis, Inherited metabolic defects (Fabry's, Gaucher's) |
Fibrotic | Radiation (breast/lung CA, Mediastinal lymphoma)
Scleroderma Anthracyclines |
Endomyocardial | Possibly related fibrotic disease (Tropical endomyocardial fibrosis, Hypereosinophilic syndrome (Löffler's endocarditis))
Carcinoid syndrome Radiation Medication |
Overlap with Other Cardiomyopathies | Hypertrophic cardiomyopathy/"pseudohypertrophic"
"Minimally dilated" cardiomyopathy Sarcoidosis |
Idiopathic | ----- |
Detailed Causes of Restrictive CM
- Infiltrative (between myocytes)
- Amyloidosis
- several proteins can fold into Beta-pleated sheets, causing phenotypic variability.
- >100 identified mutations in Transthyretin on chromosome 13 (locus heterogeneity).
- MOA of organ dysfunction twofold:
- physical disruption from infiltrating amyloid fibrils
- direct toxicity from immunoglobulin light chain & abnormal transthyretin protein aggregates.
- Subtypes listed below in order of decreasing severity.
- Primary (light chain amyloid)
- Cardiac Sx
- Neuro Sx
- Familial (abnormal transthyretin)
- Cardiac Sx
- Neuro Sx
- V122I transthyretin mutation is present in 10% of African Americans with heart failure and approximately ~4% of the African Americans population.
- V122I gene mutation : Amyloidosis & Heart Failure :: BRCA1/2 gene mutation : Breast CA
- Senile (abnormal accumulation (quantity) of normal transthyretin or atrial peptides)
- 10% of people >80yo & 50% of people >90yo
- Increasing number
- Often asymptomatic. Men more likely to display symptoms as they have a higher burden disease.
- Primary (light chain amyloid)
- Inherited metabolic defects
- Amyloidosis
- Storage (within myocytes)
- Hemochromatosis (iron)
- Inherited metabolic defects - Enzyme replacement may help
- Fabry's disease (Alpha-galactosidase A deficiency)
- Lysosomal enzyme
- X-linked. Caused by one of >160 mutations (Allelic heterogeneity)
- Lamellar inclusions of glycosphingolipids
- Glycogen storage disease (II, III)
- Most are diagnosed early in childhood & die before adulthood
- Fabry's disease (Alpha-galactosidase A deficiency)
- Fibrotic - Restrictive myocardial disease without ventricular dilation
- Radiation (breast/lung CA, Mediastinal lymphoma)
- Fibrotic restrictive CM can coexist with constrictive pericarditis
- Pericardiectomy does not work well in this setting.
- Scleroderma
- Small vessel spasm and ischemia → small, stiff heart with rEF without dilation
- Concomitant Pulmonary HTN accentuates Right HF present in most restrictive diseases
- Anthracyclines
- Primarily a dilated CM with restrictive component
- Fibrosis limits the degree of dilation possible
- Radiation (breast/lung CA, Mediastinal lymphoma)
- Endomyocardial
- Common mechanism: elevated filling pressures + atrial enlargement + preserved ventricular contractility + normal or reduced ventricular volumes = extensive endocardial fibrosis WITHOUT transmural myocardial disease
- Possibly related fibrotic disease
- Tropical endomyocardial fibrosis
- Most common cause of Endomyocardial fibrosis near the equator
- Found in areas
- May comprise up to 25% of CHF in these regions
- More common in African Americans
- MOA:
- Unclear. Leading theories include:
- End stage of prior hypereosinophilic disease triggered by endemic parasites
- Regional nutritional deficiencies
- Unclear. Leading theories include:
- Fibrosis obliterating the ventricular apex, extending to valvular apparatus, like Löffler's endocarditis
- Associated with pericardial effusions, unlike Löffler's endocarditis
- Fibrosis obliterating the ventricular apex, extending to valvular apparatus : Tropical endomyocardial fibrosis AND Löffler's endocarditis :: Associated with pericardial effusions : Tropical endomyocardial fibrosis NOT Löffler's endocarditis
- Hypereosinophilic syndrome (Löffler's endocarditis)
- Most common cause of Endomyocardial fibrosis outside of equatorial regions
- Men > Women
- Hypereosinophilia >1500eos/mm3 for ≥6mo
- Hypereosinophilia >1500eos/mm3 for ≥6mo : Hypereosinophilic syndrome (Löffler's endocarditis) :: WBC 15, Cr 1.5 : Severe C. Diff
- Etiology often unclear (idiopathic)
- CHINA is a mnemonic for chronic causes of eosinophilia. Helminth, Allergic, Neoplastic MC identifiable causes
- Connective Tissue disease (e.g. Eosinophilic granulomatosis with Polyangiitis EGP)
- Helminthic/Parasitic (esp. Strongyloides)
- Idiopathic hypereosinophilic syndrome
- Neoplastic - (lymphomas, esp Hodgkin's, CML)
- Hypereosinophilic syndrome associated with myeloproliferative disorders are often secondary to chromosomal rearrangements involving platelet-derived growth factor receptor (PDGFR), creating a fusion gene yielding a constitutively active PDGFR tyrosine kinase
- Treatment with Imatinib (TKI) has produced hematologic remissions and reversal of endomyocarditis
- Allergy/Atopy/Asthma/phArmAceuticAl-induced eosinophilia (i.e. DRESS from CArbAmAzepine, SulfonAmides)
- HAN : MC identifiable cause of Eosinophilia :: CHINA : MCC eosinophilia
- 2 phases of diseases:
- Acute inflammatory phase
- Eosinophils damage the endocardium
- Systemic injury to other organs
- Subacute/chronic fibrotic phase
- Cardiac inflammation replaced by fibrosis with superimposed thrombosis
- In severe disease, the fibrotic layer can:
- obliterate the ventricular apex
- extend to the AV valve leaflets causing fibrotic, thickened valvular apparatus
- In severe disease, the fibrotic layer can:
- Unclear risk factors or triggers to mark the transition from hypereosinophilic syndrome to extensive fibrosis
- Symptoms: CHF (Right>Left), Emoblic events, Atrial arrythmias
- Cardiac inflammation replaced by fibrosis with superimposed thrombosis
- Acute inflammatory phase
- Most common cause of Endomyocardial fibrosis outside of equatorial regions
- Tropical endomyocardial fibrosis
- Carcinoid syndrome
- Only occurs with liver mets, as liver unable to metabolize serotonin → more serotonin released to venous circulation
- Systemic Serotonin → fibrous plaques in the endocardium & heart valves (Right >>> Left)
- Associated symptoms of flushing & wheezing
- Radiation
- Medications: e.g. Serotonin, Ergotamine
- Overlap with Other Cardiomyopathies
- Hypertrophic cardiomyopathy/"pseudohypertrophic"
- Pseudohypertrophy refers to thickened myocardium secondary to infiltration of products between or within cells
- Restrictive phenotype predominates, but may also concurrently have mildly dilated CM
- "Minimally dilated" cardiomyopathy
- Early-stage dilated cardiomyopathy
- Partial recovery from dilated cardiomyopathy
- Sarcoidosis
- Hypertrophic cardiomyopathy/"pseudohypertrophic"
- Idiopathic
Gross Pathology
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Cardiomyopathy: Gross excellent view of mitral valve from left atrium anterior leaflet appears to balloon a bit into the atrium
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Cardiomyopathy: Gross excellent view of mitral and tricuspid valves from atria, appear normal anatomy.
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Cardiomyopathy: Gross apical slice of left and right ventricles concentric hypertrophy with cavitary obliteration sudden unexpected death obstructive cardiomyopathy
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Dilated Cardiomyopathy: Gross natural color close-up view of heart surgically removed for a transplantation shows aortic valve and anterior leaflet of mitral valve with cholesterol deposits endocardium of left ventricle is diffusely thickened
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Cardiomyopathy: Gross montage of ventricular slices showing hypertrophy and about normal ventricular lumen size a hypertrophic non-dilated cardiomyopathy
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Cardiomyopathy: Gross ventricular slices hypertrophy and extensive myocardial fibrosis a unique case of global fiber disarray with atrophy and fibrosis
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Cardiomyopathy: Gross close up view of a ventricle slice
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Cardiomyopathy: Gross excellent ventricular slice with hypertrophy and fibrosis a unique case of global fiber disarray with hypertrophy then atrophy and then fibrosis
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Cardiomyopathy: Gross external view of globular heart with patchy fibrosis seen through epicardium
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Cardiomyopathy: Gross interventricular septum showing asymmetrical hypertrophy in posterior septum
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Cardiomyopathy: Gross hypertrophic cardiomyopathy obstructive excellent section through left ventricle outlet to show subvalvular narrowing case of sudden death in a 27 yo male playing basketball no history of disease
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Cardiomyopathy: Gross obstructive cardiomyopathy showing aorta outflow tract with marked endocardial thickening mitral valve appears normal (Same case as previous one)
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Cardiomyopathy: Gross excellent view of mitral valve atrial surface showing thickening which is fibrous in body of valve and myxoid at area of free margin changes presumed secondary to insufficiency due to anterior motion
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Cardiomyopathy: Gross dilated left ventricle with marked endocardial thickening this is what has been called adult fibroelastosis
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Dilated Cardiomyopathy: Gross good example huge dilated left ventricle
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Dilated Cardiomyopathy: Gross dilated left ventricle with marked endocardial sclerosis (an excellent example)
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Cardiomyopathy: Gross intact globular shaped heart
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Dilated Cardiomyopathy: Gross opened left ventricle dilated with endocardial thickening good example
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Cardiomyopathy: Gross globular heart external view 10 year old girl with sickle cell anemia
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Cardiomyopathy: Gross horizontal sections of ventricles dilation type 10 year old girl with sickle cell anemia
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Cardiomyopathy: Intermediate between hypertrophic and dilated
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Cardiomyopathy Asymmetrical Septal Hypertrophy
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Dilated Cardiomyopathy: Gross opened globular left ventricle natural color (very good example)
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Diabetic Cardiomyopathy: Gross natural color moderately hypertrophied heart shown in horizontal section hyperemic subendocardium has no microscopic lesion long standing type I diabetic patient, no significant coronary artery lesions, congestive heart failure
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Dilated Cardiomyopathy: Gross natural color external view globular heart 500 gm 24yo female seven pregnancies
Microscopic Pathology
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Cardiomyopathy: Micro H&E high mag excellent example myofiber disarray
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Cardiomyopathy: Micro H&E low mag interventricular septum at junction of normal myofiber orientation with asymmetrical hypertrophy (an excellent example)
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Cardiomyopathy: Micro trichrome low mag bizarre vacuolated fibers with disarray and focal fibrosis excellent low mag epicardial surface
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Alcoholic Cardiomyopathy: Micro plastic section lipid in perinuclear area loss of myofibrils
Reference
By David Richfield (User:Slashme)When using this image in external works, it may be cited as follows:Richfield, David (2014). "Medical gallery of David Richfield". WikiJournal of Medicine 1 (2). DOI:10.15347/wjm/2014.009. ISSN 2002-4436. - Own work, CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=2264027