ESC guidelines for diagnosis and management of peripartum cardiomyopathy

Published On 2019-09-18 13:30 GMT   |   Update On 2019-09-18 13:30 GMT

The heart failure association of the European Society of Cardiology has released new guidelines for pathophysiology, diagnosis, and management of peripartum cardiomyopathy. The guideline was published in the European Journal of Heart Failure


Cardiomyopathies are not very common diseases but may cause severe complications, making a substantial contribution to maternal morbidity and mortality during pregnancy, in the immediate peripartum period, and up to months later. Heart failure due to PPCM provides a challenge for treating physicians as PPCM presentation may vary from subtle signs and symptoms to severe acute heart failure, pulmonary oedema and/or cardiogenic shock.


In this position statement, the scientists of heart failure association of the ESC have summarized the current knowledge about pathophysiology and clinical best practice in the management of PPCM patients.


The guideline defines peripartum cardiomyopathy as




  • Heart failure secondary to left ventricular systolic dysfuntion with a LVEF < 45%

  • Occurrence towards the end of pregnancy or in the months following delivery (mostly in the month following delivery)

  • No other identifiable cause of heart failure


Pathophysiology


The aetiology of PPCM is dubious. Possible factors leading to PPCM include genetic predisposition, low selenium levels, viral infections, stress‐activated cytokines, inflammation, autoimmune reaction, a pathological response to hemodynamic stress, unbalanced oxidative stress, and induction of antiangiogenic factors. Particularly, the oxidative stress‐mediated cleavage of the hormone prolactin into a smaller antiangiogenic subfragment, 16‐kDa prolactin, may drive PPCM by inducing endothelial damage, the guideline stated.



Genetic aspects



  • PPCM is often difficult to differentiate from genetically transmitted dilated cardiomyopathy (DCM) which may manifest during early adulthood. recent observations support the notion that around 15–20% of patients with peripartum heart failure carry mutations known to induce cardiomyopathies, i.e. in genes like titin, beta‐myosin heavy chain, myosin‐binding protein C (MYBPC3), lamin A/C or sodium voltage‐gated channel alpha subunit 5 (SCN5A). Further investigation is needed regarding mutations or polymorphisms in genes regulating metabolism, oxidative stress response, angiogenesis and the immune system as well as the higher frequency of PPCM in women of African ancestry.

  • Genetic testing may be considered in PPCM, in particular in those patients with a positive familial history.


Differential diagnoses of peripartum cardiomyopathy














































































































HistoryOnsetBiomarkersEchocardiography/cardiac MRIDifferentiation from PPCM
PPCMNo known cardiac disease, no HF signs and/or symptoms prior pregnancyTowards the end of pregnancy and the months following deliveryElevated natriuretic peptidesReduced systolic LV function, LVEF < 45%
MyocarditisPrior viral infection (e.g. respiratory)Acute or subacute onset after viral infectionElevated troponin, elevated CRPNormal or reduced systolic LV function, typical myocardial late gadolinium enhancement pattern, pericardial effusionCardiac MRI (LE pattern), myocardial biopsy
Pre‐existing idiopathic/ familial dilated or acquired cardiomyopathyHF signs and/or symptoms and/or known heart disease prior pregnancyDuring second trimester of pregnancyElevated natriuretic peptidesReduced systolic LV function, RV dysfunction possible, typical myocardial LE pattern (DCM)History, echocardiography, cardiac MRI (LE pattern)
Takotsubo syndromeChest pain, very stressful delivery or emergency due to foetal complicationsAcute onset, during delivery or immediately after deliveryElevated natriuretic peptidesRegional wall motion abnormalities with typical anatomical patternsHistory, echocardiography
Pregnancy‐associated myocardial infarctionChest pain, epigastric painAcute onset, during pregnancy or immediately after deliveryElevated troponinRegional wall motion abnormalities, ischaemic myocardial scarHistory, ECG, coronary angiography, cardiac MRI (LE pattern)
Pulmonary embolismChest pain, unilateral leg swelling, acute dyspnoeaAcute onset during pregnancy or after deliveryElevated natriuretic peptides and/or troponin, elevated D‐dimerRV dysfunction, RV dilatation, LV function usually normalComputed tomography, VQ scan
Amniotic fluid embolismChest pain during/immediately after delivery, acute dyspnoeaAcute onset during delivery or immediately after deliveryElevated natriuretic peptides possibleReduced RV systolic function, RV dilatationHistory, echocardiography
Hypertensive heart disease/severe pre‐eclampsiaPre‐existing or new‐onset hypertension, proteinuriaDuring second trimester of pregnancyElevated natriuretic peptidesLV hypertrophy, diastolic dysfunction, transient LV dysfunctionHistory, echocardiography
Hypertrophic cardiomyopathyFamilial predispositionDuring second trimester of pregnancyElevated natriuretic peptidesLV hypertrophy, typical myocardial late enhancement pattern, LVOTO (HOCM)History, echocardiography, cardiac MRI (LE pattern)
HIV/AIDS cardiomyopathyHIV infection, AIDSDuring second trimester of pregnancyElevated natriuretic peptidesReduced systolic LV function, LV/RV often not dilatedHIV serology/test
Pre‐existing (unknown) congenital heart diseaseHF signs and/or symptoms prior pregnancy, known heart disease, prior cardiac surgeryDuring second trimester of pregnancyElevated natriuretic peptides(Corrected) congenital heart defects, cardiac shuntsHistory, echocardiography
Pre‐existing valvular heart diseaseHF signs and/or symptoms prior pregnancy, known heart diseaseDuring second trimester of pregnancyElevated natriuretic peptidesValvular stenosis or regurgitation, prosthetic heart valvesHistory, echocardiography

PPCM should be suspected in all women with a delayed return to the pre‐pregnancy state. Table 2 summarizes the diagnostic tests that are recommended for the diagnosis of PPCM at initial diagnosis and at follow‐up visits.









































































































Clinical examinationECGNatriuretic peptidesEchocardiographyChest X‐rayCardiac MRICT scanCoronary angiography
Diagnosis of PPCMXXXXX(X)b(X)b(X)b
4‐6 weeks after diagnosisXXXX(X)b(X)b(X)b
3 months after diagnosisXXXaX
6 months after diagnosisXXXaX(X)b
12 months after diagnosisXXXaX
18 months after diagnosisXXXaX
Annually for at least 5 years afterXXXaX
diagnosis (especially if not fully recovered)


  • Generally, an individual approach is recommended depending on the severity of the disease and/or potential differential diagnoses.

  • CT, computed tomography; ECG, electrocardiogram; MRI, magnetic resonance imaging; PPCM, peripartum cardiomyopathy.

  • a May be considered depending on costs and local availability.

  • b May be considered depending on the clinical presentation and/or differential diagnoses.


Electrocardiogram



  • An ECG should be performed in all patients with suspected PPCM because it is safe, inexpensive and may help distinguish PPCM from other causes of symptoms. Although there is no specific ECG pattern for PPCM, at initial evaluation, the ECG is rarely normal and repolarization abnormalities are common.

  • Left bundle branch block may be an indirect sign for cardiomyopathy and structural heart disease should be ruled out in these women.

  • A recent study identified a long QTc interval at baseline which was found in almost 50% of the patients, and tachycardia as predictors of poor outcome in PPCM.


Biomarkers



  • Concerning diagnostic properties of natriuretic peptides, one should keep in mind that B‐type natriuretic peptide (BNP)/N‐terminal proBNP (NT‐proBNP) levels are not or only slightly elevated in normal pregnancy.


Cardiac imaging



  • Echocardiography is indicated as soon as possible in all cases of suspected PPCM to confirm the diagnosis, assess concomitant or pre‐existing cardiac disease, exclude complications of PPCM (e.g. LV thrombus) and obtain prognostic information (for example LVEF and pulmonary hypertension).

  • After stabilization, magnetic resonance imaging may provide a more accurate evaluation of cardiac structure and function, and can sometimes be helpful if there is high suspicion for another diagnosis such as arrhythmogenic right ventricular cardiomyopathy and myocarditis.

  • The incremental value of cardiac magnetic resonance imaging in addition to echocardiography is uncertain.

  • Administration of gadolinium to assess late enhancement should be avoided until after delivery due to the increased risk of stillbirth, neonatal death, and rheumatological, inflammatory, or infiltrative skin conditions.


Endomyocardial biopsy



  • Endomyocardial biopsy adds limited diagnostic or prognostic information in PPCM.

  • It may be used to exclude acute myocarditis after delivery, reveal significant viral presence, and exclude rare autoimmune myocarditis, storage or metabolic disease.


Management



  • For rapid diagnosis and decision making in all pregnant women with acute heart failure, a pre‐specified management algorithm and the establishment of a multidisciplinary team is crucial.

  • Multidisciplinary care includes cardiologists, intensivists, obstetricians, neonatologists, anaesthetists and cardiac surgeons.





  • If a patient is in cardiogenic shock/dependent on inotropes, she should be transferred immediately to an advanced heart failure centre where mechanical circulatory support (MCS), ventricular assist devices (VAD), and transplant consult teams are available.

  • Experimental data and a study in PPCM patients indicated that patients with PPCM may be especially sensitive to toxic effects of beta‐adrenergic receptor stimulation which should be avoided whenever possible.

  • Norepinephrine is indicated to restore blood pressure, and levosimendan may be considered, however the only (small) randomized clinical trial in PPCM patients did not show a beneficial effect on outcome.

  • The teratogenic effects of inotropic support and vasopressors in humans are unknown but their use may be necessary.

  • In PPCM patients with severely reduced LV function and/or cardiogenic shock, VAD implantation as bridge to recovery or transplantation can be necessary (2–7% of PPCM patients).

  • It is important to note, however, that a significant proportion of PPCM patients improve or normalize their LV function over the first 6 months after diagnosis, which must be considered when decisions are made.

  • Short‐term assist devices, e.g. microaxial pump, Centrimag or venoarterial extracorporeal membrane oxygenation (ECMO), may be required.

  • Long‐term assist devices with left VAD or biventricular VAD can be implanted and some have been explanted after recovery.

  • Due to the toxic effects of beta‐adrenergic agonists specifically in PPCM, MCS may be considered with a lower threshold than in other patients with inotrope‐dependent cardiogenic shock.


Heart transplantation in peripartum cardiomyopathy


Early cardiac transplantation should be reserved for patients with refractory severe heart failure where MCS is not possible or not desirable for individual reasons, mainly for cases with biventricular failure or severe initial right ventricular dysfunction.



Stabilized/chronic heart failure



  • For treatment of stabilized/chronic heart failure, the pregnancy status of the patient is important.

  • Women who present with PPCM during pregnancy require joint cardiac and obstetric care.

  • Possible adverse effects on the foetus must be considered when prescribing drugs.

  • For those not breastfeeding, heart failure should be treated according to guidelines on acute and chronic heart failure including ACE inhibition, beta‐blockade and MRAs, and then replacing ACE inhibitors and ARBs with ARNI.

  • As high resting heart rate is a predictor of adverse outcome, treatment with ivabradine might be useful in PPCM patients with high heart rate in sinus rhythm on top of beta‐blockade.


Delivery



  • Vaginal delivery is always preferable if the patient is haemodynamically stable and there are no absolute obstetric indications for caesarean delivery.

  • Close haemodynamic monitoring is required.

  • Epidural analgesia is preferred.

  • Urgent delivery irrespective of gestation duration should be considered in women with advanced heart failure and haemodynamic instability despite optimal heart failure treatment.

  • In these cases, caesarean section is recommended with central neuraxial anaesthesia.

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