About the Author(s)


Sulaiman Moosa Email symbol
Department of Radiology, 2 Military Hospital, Wynberg, Cape Town, South Africa

Ntobeko A.B. Ntusi
Division of Cardiology, Department of Medicine, University of Cape Town, South Africa

Department of Radiology, Groote Schuur Hospital, Cape Town, South Africa

Cape Universities Body Imaging Centre, University of Cape Town, South Africa

Citation


Moosa S, Ntusi AB. Role of cardiovascular magnetic resonance in the evaluation of cardiomyopathy. S Afr J Rad. 2016;20(2), a1055. http://dx.doi.org/10.4102/sajr.v20i2.1055

Review Article

Role of cardiovascular magnetic resonance in the evaluation of cardiomyopathy

Sulaiman Moosa, Ntobeko A.B. Ntusi

Received: 29 June 2016; Accepted: 01 Aug. 2016; Published: 11 Nov. 2016

Copyright: © 2016. The Author(s). Licensee: AOSIS.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Cardiovascular magnetic resonance imaging plays a central role in the assessment and monitoring of patients with cardiomyopathy. It offers a comprehensive assessment during a single scan setting, with information on ventricular volumes, function and mass as well as tissue characterisation, fibrosis, flow, viability and perfusion. Acute tissue injury (oedema and necrosis) can be distinguished from fibrosis, infiltration and iron overload. It provides information on the cause and prognosis of the cardiomyopathy, and its high measurement accuracy makes it ideal for monitoring disease progression and effects of therapy. The present review highlights the main features of commonly encountered cardiomyopathies in imaging practice.

Introduction

Cardiomyopathies comprise a wide range of myocardial disorders that may be primary heart diseases or a feature of a systemic disease, and which may or may not have a genetic and/or familial component.1 Cardiomyopathy is defined as a:

… myocardial disorder in which the heart muscle is structurally and functionally abnormal, in the absence of coronary artery disease, hypertension, valvular disease and congenital heart disease sufficient to cause the observed myocardial abnormality.2

The key aim in the work-up of suspected cardiomyopathy is to identify a potentially treatable underlying cause, to risk-stratify the patient for prognostication, and to apply an effective therapeutic strategy. Besides evidence-based pharmacological therapeutic options, therapy includes consideration for an implantable cardioverter defibrillator (ICD), cardiac resynchronisation and orthotopic heart transplant.1

Cardiovascular magnetic resonance (CMR) provides the opportunity to obtain key information during a single non-invasive study. Data on cardiac anatomy, function, tissue characterisation, coronary and microvascular perfusion and valvular structure and function in any selected orthogonal plane, independent of the patient habitus, can be safely acquired. The absence of ionising radiation adds to its safety. This safety feature includes intravenous contrast which allows repeated follow-up imaging, family screening and serial risk stratification.

Technical aspects and sequences

A typical cardiomyopathy protocol is as follows, but should be adjusted as dictated by the clinical suspicion and continuous assessment of images during the scan.

Gross anatomical images

Half-Fourier single-shot turbo spin-echo (HASTE) in two to three orthogonal planes.

Functional imaging

Balanced steady state free precession (b-SSFP) in long-axis and short-axis views forms the cornerstone of CMR, for reproducible quantification of LV (left ventricle) and RV (right ventricle) function and LV mass.

Non-contrast tissue characterisation
  • T2-weighted and STIR images – oedema detection
  • T1-weighted images – pericardium and fat infiltration assessment
  • T2* images – direct quantification of myocardial iron in vivo.
Imaging fibrosis (scar) and infiltration

Gadolinium-based contrast agents are utilised. Gadolinium is an extracellular agent that accumulates in regions of interstitial expansion, such as in oedema, fibrosis or infiltration. After an intravenous gadolinium injection (usual dose 0.1 mmol/kg – 0.2 mmol/kg of body mass), three post-contrast phases can be assessed at the following times:

  • First pass is immediate imaging at rest or during stress perfusion to visualise inducible perfusion defects.
  • Early gadolinium enhancement (EGE), acquired at 90 s – 120 s, detects thrombi, hyperaemia and microvascular obstruction post myocardial infarction.
  • Late gadolinium enhancement (LGE) acquired at 5 min – 20 min detects delayed contrast washout in areas of infarction, fibrosis or inflammation.

Sequences utilised for LGE include inversion recovery gradient echo (magnitude images) or phase sensitive inversion recovery (PSIR) images, the latter being less dependent on accurate inversion time, but which is an absolute prerequisite for the former.1,3

LGE demonstrates fibrosis (scar) by revealing the relative difference between the scar (delayed contrast washout) and normal myocardium (rapid washout). The pattern and extent of LGE varies according to the pathological process and contributes to the correct diagnosis in cardiomyopathy.1 Fibrosis is assessed visually, and the extent can be quantified as a percentage of mass using dedicated software.

Myocardial mapping

More recently, myocardial mapping techniques have expanded our ability to characterise myocardium without contrast administration. T1 mapping measures the absolute myocardial T1 relaxation time on a pixel-by-pixel basis, hence being able to detect subtle changes in T1 relaxation times, the latter being proportional to the local concentration of gadolinium. Fibrosis causes expansion of the interstitial space and results in increased native T1 times, and the increased gadolinium concentration results in shortening of T1 values.1 T1 mapping is also useful for detecting small amounts of fibrosis and cardiomyopathies with diffuse fibrosis.4 Recently, T2 mapping5 and T2* mapping6 has been validated for imaging of myocardial oedema and/or inflammation and iron content, respectively.

Flow quantification

CMR velocity mapping can provide reproducible assessment of valvular disease, intracardiac shunts and congenital heart disease, and compares well with echocardiography.7

Limitations and contraindications

Metallic implants and intracardiac devices (pacemakers and ICDs) represent the only absolute contraindications to CMR. However, this is being overcome with the increasing use of MR-compatible devices. Metallic objects in delicate positions (e.g. within the eye) continue to pose a problem as ferromagnetic objects may act as projectiles within the powerful magnetic field of the scanner and cause injury. Relative contraindications include claustrophobia, florid heart failure and clinical instability. CMR up to 3 Telsa is safe during all trimesters of pregnancy.8

Severe renal failure (glomerular filtration rate [GFR] < 30 mL/min) precludes the use of gadolinium owing to a small but tangible risk of nephrogenic systemic fibrosis, which is enhanced by concomitant heart failure (HF).1 The limited availability of CMR scanners and CMR expertise are currently the most important limitations.

A practical approach to an unknown cardiomyopathy

The imaging clinician’s first task is to obtain maximum information about the suspected diagnosis by evaluating clinical notes, operative notes, and previous investigations such as electrocardiograms (ECGs), echocardiography (echo), cardiac tomography and prior CMR studies.

After performing the anatomical and functional sequences to assess heart morphology and function, the following features should be identified to assist in optimising scan planning:9

  • Myocardial thinning: Global myocardial thinning is often found in dilated cardiomyopathy (DCM), left ventricular noncompaction (LVNC), and arrythmogenic right ventricular cardiomyopathy (ARVC). Regional thinning suggests chronic myocardial infarction, sarcoidosis and burnt-out hypertrophic cardiomyopathy (HCM).
  • Enlarged RV: A dilated RV indicates ARVC, DCM, sarcoid, chronic myocarditis, intracardiac shunt (e.g. atrial septal defect) and congenital disease (e.g. tetralogy of Fallot, Ebstein’s anomaly).
  • Myocardial hypertrophy: Increased myocardial thickness points to HCM, cardiac amyloidosis, Anderson-Fabry disease and cardiomyopathy related to mitochondrial disease. However, pressure overload conditions such as hypertension, aortic stenosis and aortic coarctation should always be considered.
  • Biatrial enlargement: Marked atrial enlargement indicates a restrictive cardiomyopathy, amyloidosis, constrictive pericarditis and DCM.

Indications for CMR

CMR is considered as a Class I indication for global and regional LV and RV function, volume and mass quantification.10,11 Indications include:

  • systolic function assessment in patients with poor echocardiographic acoustic window and precise ejection fraction (EF) determination that will affect management or device implantation,
  • prognostic information from the LGE burden,
  • reproducible LV mass assessment and follow-up,
  • RV evaluation in suspected cardiomyopathies, right ventricular ejection fraction (RVEF), wall motion abnormalities, oedema and scarring,
  • assessing the cause of LV dysfunction in newly diagnosed heart failure; it can play a role as an effective gatekeeper to coronary angiograms in such patients,
  • screening family members with cardiomyopathy,
  • screening athletes with syncope or aborted sudden cardiac death (SCD),
  • chest pain syndrome (CPS) with unobstructed coronaries,
  • suspected myocarditis, congenital heart disease and infiltrating conditions.

Dilated cardiomyopathy

DCM refers to LV systolic dysfunction with concomitant LV dilation; RV dilatation may be present. In 50% of cases, the diagnosis remains unknown; up to 30% have a familial association to known genetic abnormalities.12 Chronic myocarditis has been implicated in the aetiology of DCM.12

CMR provides accurate evaluation of biventricular EFs, volumes and mass assessment, and the pattern of LGE allows the exclusion of an ischaemic cause, typically subendocardial or transmural enhancement. LGE provides prognostic information and acts as a gatekeeper role to coronary angiography.13

In a large study with DCM and unobstructed coronary arteries, three LGE patterns were reported: no LGE in 59%, midwall and mainly septal LGE in 28%, and subendocardial ischaemic LGE pattern in 13%, probably on the basis of transient occlusion by non-obstructive unstable plaque or vasoconstriction.13

Other studies have shown additional LGE patterns that include epicardial LGE, patchy LGE and diffuse LGE.14 The finding of LGE in DCM is associated with increased risk of SCD, presumably arrhythmogenic.

Figure 1 and Figure 2 provide the representative imaging features of DCM.

FIGURE 1: Dilated cardiomyopathy. Cine b-SSFP in end-diastole demonstrates enlarged LV volumes with the end-diastolic diameter 67 mm. The end-systolic diameter was 58 mm.

FIGURE 2: Dilated cardiomyopathy. Late gadolinium-enhanced PSIR images in four-chamber (left) and basal short-axis (right) demonstrating virtual circumferential midwall enhancement (arrows).

Left ventricular noncompaction

LVNC is a rare congenital cardiac disorder owing to arrested embryogenesis and results in a ‘spongy’ appearance of the LV myocardium and apex, commonly involving the anterior and lateral walls and characterised by increased trabeculation and intratrabecular recesses in the myocardium.16 LVNC is associated with neuromuscular disorders and is complicated by heart failure, arrhythmia and thromboembolic events.1 Diagnosis is achieved by measuring at end-diastole, the ratio of the noncompact myocardium over the compact myocardium. A value of 2.3 has a sensitivity of 80% and specificity of 99%.17

The absence of well-formed papillary muscles is a clue to the diagnosis.1 LGE patterns include subendocardial, midwall and transmural enhancement.1 LVNC is commonly associated with a DCM phenotype. Figure 3 demonstrates the imaging features of LVNC.

FIGURE 3: Left ventricular noncompaction. Four-chamber cine b-SSFP demonstrating increased LV trabeculations (arrow) at the LV free wall and apex compared with the compact LV myocardium. The RV trabeculations are prominent too.

Arrhythmogenic right ventricular cardiomyopathy

ARVC is a genetic desmosomal disease characterised pathologically by progressive RV myocyte loss and fibrofatty replacement.1 In 75% of cases, the LV is affected and hence it can be misdiagnosed as DCM, especially in phenotypes with early and predominant LV involvement.1 ARVC should be considered in all cases of unexplained RV dilation. Aborted SCD from arrhythmia is often the initial presentation.

ARVC task force criteria (TFC) forms the cornerstone of the diagnosis, and the 2010 revision has improved sensitivity for gene carriers with limited disease and patients with left-sided disease.18 The values for RVEF and EDV have been defined on the basis of comparison with normal patient data and divided into two categories.

Major criteria

RV regional wall motion abnormality (akinesia, dyssynchrony or aneurysm) and one of the following:

  • RVEF ≤ 40%
  • RV end-diastolic volume ≥ 110 mL/m2 for male and ≥ 100 mL/m2 for female patients.
Minor criteria

Regional wall motion abnormality and one of the following:

  • RVEF > 40% and ≤45%
  • RV end-diastolic volume ≥ 100 mL/m2 – < 110 mL/m2 for male and ≥ 90 mL/m2 – < 100 mL/m2 for female patients.

Taking into account the revised TFC for the diagnosis of ARVC, a definite diagnosis of ARVC is made when a patient has:

  • two major criteria
  • one major and two minor criteria
  • four minor criteria.9

A borderline diagnosis of ARVC is made when a patient has:

  • one major and one minor criterion
  • three minor criteria.

A possible diagnosis of ARVC is made when a patient has:

  • one major or two minor criteria.

Major and minor criteria have been defined for histology, ECG and family history, and are applied in the diagnosis.18

CMR transaxial cine stack is included as part of the work-up and detects regional and global RV dysfunction, wall motion abnormalities, aneurysms and wall thinning.

T1-weighted fat detection and LGE are not part of the revised ARVC TFC. Fat can appear in the RV in healthy individuals and can be difficult to image in the thin RV wall or discriminate with confidence from epicardial fat. LGE is part of the ARVC protocol and its absence does not preclude the diagnosis but, when present, it has a high diagnostic sensitivity and specificity.19

However, RV LGE presents imaging problems:20 Firstly, it is difficult to discriminate from RV fat; and secondly it requires significantly different inversion times compared with the LV. However, LGE patterns of the RV can delineate different patterns of ARVC: (1) classic form – LGE in inferior and inferolateral walls; and (2) left-predominant phenotype – septal midwall enhancement with preserved RV function. This type is often misdiagnosed as DCM. Figure 4 demonstrates RV free wall dyskinesia, typical of ARVC.

FIGURE 4: Arrhythmogenic right ventricle cardiomyopathy. RV two-chamber views cine b-SSFP in end-diastole (left) and end-systole (right) demonstrating a dyskinetic RV apex (arrows).

Hypertrophic cardiomyopathy

HCM is the most common genetic cardiomyopathy, with an incidence of 1 in 500. It is also the most common cause of sudden death in the young, including athletes. Clinical findings and abnormal ECG findings associated with apical or asymmetrical septal hypertrophy, with or without dynamic LV outflow tract obstruction, is diagnostic. Pathologically, HCM demonstrates myocyte hypertrophy, disarray and fibrosis, manifesting in various genetic mutations.1 The majority of individuals carrying an HCM genetic defect do not manifest the clinical expression at all times of their lives. Hence an unexplained mildly thickened LV wall may be consistent with a HCM-causing mutation. Making a diagnosis of HCM can be complicated in patients with aortic stenosis or hypertension.1

Cine images allow the detection of LV wall thickness, especially at the apex, basal anteroseptal wall and posterolateral wall – regions that are difficult to visualise on echocardiography. However, a spectrum of LV wall thickening has been described.21 Myocardial crypts are additional typical findings. Apical aneurysms are associated with an increased risk for arrhythmia, thromboembolic events and progressive heart failure.22

LGE is present in 80% of HCM, both patchy or diffuse scarring, the latter in areas of increased thickness typically and less commonly in regions of normal wall thickness.23 Patchy LGE is typically midwall in thickened myocardium and commonly the RV-LV insertion points are also involved. In burnt-out HCM, the myocardium is thinned and has transmural LGE, mimicking ischaemic disease, but not in a coronary artery territory.

HCM without LGE has 100% event-free survival at 6-year follow-up; LGE > 5% of LV mass, septal wall thickness > 30 mm and AF are independent predictors of death and ICD discharges.24

Left ventricular outflow tract (LVOT) obstruction and the presence of systolic anterior motion of the mitral valve can be quantified with velocity flow mapping and has been correlated with increased severity of hypertrophy, heart failure and poor outcome.25

Figure 5 and Figure 6 demonstrate the imaging features of HCM.

FIGURE 5: Hypertrophic cardiomyopathy. Four-chamber end-diastole cine b-SSFP image demonstrating a thickened septum and LV lateral wall.

FIGURE 6: Hypertrophic cardiomyopathy. Two-chamber (left) and short-axis (right) late gadolinium images demonstrate diffuse enhancement of the thickened myocardium (arrows).

Amyloidosis

Myocardial involvement in systemic amyloidosis is an important prognostic marker, often presenting as congestive heart failure in 50% of patients, and death occurring in less than 6 months in untreated patients. Early detected cases may respond to therapy, and exclusion of other causes is important for management.26 Typical CMR findings include normal or reduced LV function, small LV cavity with homogeneous wall thickening, inconsistent RV involvement, biatrial enlargement, interatrial wall thickening, valve thickening, small pericardial effusions and pleural effusions. About 55% of patients with amyloidosis present with asymmetrical septal hypertrophy mimicking HCM.1

LGE reflects the distribution of amyloid on histology with widespread subendocardial enhancement, giving the typical ‘zebra’ pattern and sparing the midwall of the septum. Other patterns are midwall (33%), and subepicardial (up to 20%).27 RV free wall and interatrial septum LGE has been reported.1

When amyloid fibrils accumulate in the myocardium, the wash-in and washout features of gadolinium are abnormal, with inability to null the myocardial signal. The rapid washout from the blood pool and high myocardial uptake results in a dark blood pool, owing to similar T1 values to the visualised myocardium.1 To optimally visualise myocardial and blood pool kinetics in suspected amyloidosis, an inversion time scout is acquired at 5 min after contrast administration. LGE has a sensitivity of 86% for detecting amyloid. Identifying early abnormalities in patients with normal LV wall thickness is strongly related to the amyloid burden and predicted mortality risk.28,29

Figure 7 demonstrates the representative imaging findings of amyloidosis.

FIGURE 7: Amyloidosis. Four-chamber end-diastole cine b-SSFP image (left) demonstrates a thickened septum and LV lateral wall with small pericardial and pleural effusions. The four-chamber late gadolinium image (right) shows diffuse subendocardial enhancement (arrow) in a non-coronary artery distribution, with enhancement of the RV free wall and interatrial septum.

Anderson-Fabry disease

Anderson-Fabry disease is a treatable X-linked disorder of lysosome storage, caused by partial or complete alpha galactosidase A deficiency which results in glycosphingolipid accumulation within the vessels and heart.30 Concentric LV hypertrophy and cardiac fibrosis then leads to heart failure. CMR is used to evaluate LV function, wall thickness and scar detection. The typical LGE is inferolateral midwall enhancement which correlates well with histology and may serve as a substrate for electrical re-entry and SCD.31 Recently, T1 mapping has been shown to have a relative specific signature for conditions with a decreased T1 value, especially in areas of LGE.32 Six per cent of suspected HCM turns out to be Anderson-Fabry, with important implications for management. Anderson-Fabry is treated with enzyme replacement, with resultant improvement in LV function. The enzyme replacement is optimally utilised before fibrosis sets in. An unexplained LV hypertrophy, especially in young patients, should have Anderson-Fabry excluded.

Sarcoidosis

Sarcoidosis is a multisystem granulomatous disease affecting the myocardium in 50% of cases, but only half of them are symptomatic.33 HF and arrhythmia are the important presentations, and early identification allows medical therapy and ICD implantation.

CMR cine imaging facilitates the detection of wall thinning, regional wall motion abnormalities, ventricular dysfunction and pericardial effusion, whilst LGE CMR detects fibrosis. LGE is typically patchy, midwall or subepicardial, in an unpredictable manner, in the anteroseptal and anterolateral walls as well as in the RV free wall and RV side of the septum.34 Sarcoid may mimic ischaemic disease with subendocardial or transmural patterns.35 LGE acts as a guide to endomyocardial biopsy and improves after steroid therapy. T2W imaging may monitor disease activity with inflamed oedematous regions being highlighted.34 Recently, T1 and T2 mapping has been shown to have a role in the assessment and monitoring of sarcoidosis.36 Figure 8 demonstrates the representative imaging findings of sarcoidosis.

FIGURE 8: Sarcoidosis. End-diastole four-chamber cine b-SSFP image (left) demonstrates increased RV size. The four-chamber late gadolinium PSIR image (right) demonstrates prominent RV free wall enhancement (smaller arrow) as well as nodular enhancement of the septum and LV lateral wall (larger arrow).

Iron overload cardiomyopathy

Cardiac siderosis is evident in transfusion-dependent anaemia and primary haemachromatosis. If chelation therapy is initiated early, the cardiomyopathy is reversible; but the diagnosis is often delayed owing to the late onset of symptoms. T2* imaging arises from local magnetic inhomogeneities that increase with greater iron deposition.1 As myocardial iron increases, heart failure progresses and T2* times diminish so that all heart failure patients have a T2* value < 20 m/sec. The efficacy of chelation can also be monitored.1 CMR has a significant role to play in the diagnosis and management of this disease.

Chest pain syndrome with unobstructed arteries

CMR has increasing utility in providing diagnostic information in patients presenting with troponin-positive CPS with normal coronary arteries. It contributes to a diagnosis in 77% of patients, correcting a wrong diagnosis in 10% and changing therapy in 33%.30 The main causes of CPS with normal coronary arteries are myocarditis, takotsubo cardiomyopathy, recanalised infarcts and the inflammatory phases of DCM, HCM and ARVC.

Myocarditis

Myocarditis refers to inflammation of the myocardium that may be caused by infection, autoimmune diseases or drug toxicity; some cases are idiopathic. It has a wide range of clinical manifestations, ranging from an influenza-like viral illness, troponin-positive CPS, new onset HF and even SCD. The diagnosis is usually one of exclusion, and endomyocardial biopsy is the gold standard but sampling bias and insensitivity limits its utilisation; however, CMR-guided biopsies result in higher yields.37

CMR is a non-invasive tool to diagnose myocarditis, utilising T2-weighted imaging to detect subendocardial and midwall myocardial oedema.38 EGE matching areas of T2-weighted hyperintensity may reflect tissue hyperaemia and increased interstitial space, and LGE reflects myocardial necrosis which has a subepicardial distribution, with varying degrees of midmyocardial involvement; the subendocardium is often spared. The lateral and inferolateral walls are frequently involved.39

The presence of a typical LGE pattern is a strong indicator for the diagnosis, but the absence of this pattern does not exclude the diagnosis.40 The focal LGE pattern evolves and becomes diffuse over a period of weeks, then decreases during healing and may become invisible after recovery.37 Midwall myocardial scarring can be evident after myocarditis, in a pattern similar to that seen in DCM subjects and suggests that previous myocarditis is a cause of LV dysfunction in a proportion of DCM patients.41 T1 mapping has been shown to be superior to LGE and T2-weighted imaging in the diagnosis of myocarditis, without the need for contrast agent.42 Figure 9 demonstrates the representative imaging findings of myocarditis.

FIGURE 9: Myocarditis. T2W short-axis image (left) demonstrates LV inferolateral wall high signal and oedema (arrow). The equivalent late gadolinium image (right) demonstrates epicardial enhancement in the same region (arrow).

Takotsubo cardiomyopathy

Takotsubo (also called stress cardiomyopathy or catecholamine-induced cardiomyopathy) is typically seen in postmenopausal women in whom emotional stress may result in a clinical picture similar to acute myocardial infarction with anterior lead ECG changes. However, many patients do not report a clear stressor and this condition has been diagnosed in men. The rapidly reversible LV systolic dysfunction is caused by a temporary stunning of the apical to mid LV segments with apical ballooning, resulting in a dynamic obstruction.1

Myocardial oedema is evident as T2-weighted hyperintensity in a focal pattern, matching the wall motion abnormality and related to the severity of the systolic dysfunction.43 Lack of LGE is typical, and distinguishes it from myocarditis and infarction, but there may be mild patchy LGE composite with the myocardial oedema.44 The RV is involved in 25% of cases and complete resolution is typically at 4 weeks.1 Figure 10 demonstrates the representative imaging findings of takotsubo cardiomyopathy.

FIGURE 10: Takotsubo. Two-chamber cine b-SSFP at end-diastole (left) and end-systole (right) demonstrating a hypokinetic apex and mid LV, resulting in a Japanese ‘octopus trap’ appearance on the end-systole image.

Systemic sclerosis

Systemic sclerosis is a connective tissue disorder affecting mainly the skin but also involving the lungs, kidneys and heart.45 Myocardial fibrosis is a common finding at autopsy studies.46 LGE manifests in a linear midmyocardial wall distribution at the basal and mid-ventricular levels. The development of clinical features indicates a poor prognosis, with a 5- year survival rate of 30%.9

Churg-Strauss

Churg-Strauss is a rare small vessel syndrome with a poor prognosis. A subendocardial pattern of fibrosis in the absence of coronary artery disease is the typical pattern.47 Associated features are normal myocardial function, apical obliteration and thrombus formation. Elevated blood eosinophils are commonly found and imaging features overlap with hypereosinophillic cardiomyopathy.

Rheumatoid arthritis

Rheumatoid arthritis (RA) is a chronic autoimmune disease primarily involving the synovium, but extra-articular manifestations include cardiac involvement which can lead to a 10-year reduction in life span, especially in young women. CMR has been shown to detect diffuse and focal myocardial fibrosis as well as inflammation in RA patients. In addition, myocardial fibrosis and inflammation correlates with a C-reactive protein (CRP) score of disease activity as well as with systolic and diastolic strain patterns.48 Myocardial fibrosis is not related with disease duration and T1 mapping can provide a new biomarker of disease activity in the heart, beyond that provided by the standard sequences such as short T1 inversion recovery (STIR) and LGE.48

Phaeochromocytoma

Cardiac involvement in phaeochromocytoma is frequent and often persistent, manifesting as myocarditis, global LV dysfunction, subclinical systolic and diastolic dysfunction as well as focal and diffuse fibrosis. The myocardial effects of phaeochromocytoma have been shown to be beyond that of hypertension; catecholamine-induced cardiac toxicity is the likely cause, leading to inflammation, myocyte necrosis and fibrosis.49

Peripartum cardiomyopathy

Peripartum cardiomyopathy is characterised by heart failure in the last trimester of pregnancy or first six post-partum months in previously healthy women. The cause is unknown and considered to be multifactorial. LGE is evident in the midmyocardium, mainly in the anterior and anterolateral segments. These features tend to regress over time as LV function improves.50

Future perspectives and conclusion

CMR is a unique non-invasive tool and currently integral part of cardiomyopathy work-up. Tissue characterisation remains its major strength, detecting fat, oedema, fibrosis, infiltration and infarction. Its excellent spatial resolution allows accurate evaluation of biventricular function and morphology. It is predicted that most patients with HF will eventually undergo CMR as part of diagnostic work-up and risk stratification.35 Its utility in the South African context is limited by the cost and availability of imaging expertise.

Acknowledgements

Dr Ntobeko Ntusi gratefully acknowledges support from the Harry Crossley Foundation, National Research Foundation and Medical Research Council of South Africa.

Competing interests

The authors declare that they have no financial or personal relationships which may have inappropriately influenced them in writing this article.

Authors’ contributions

S.M. was the project leader. N.N. assisted with corrections and editing.

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