Multimodality Approach Chagas Disease PDF

Summary

This medical case report explores the use of a multimodality approach, combining cardiac magnetic resonance imaging (CMR) and computed tomography angiography (CTA), for managing dilated cardiomyopathy in patients with Chagas disease. The report details the case of a 58-year-old male from Peru with chronic dilated cardiomyopathy. This approach is crucial in evaluating myocardial inflammation and tailoring treatment strategies.

Full Transcript

Exploration of Cardiology

Open Access Case Report

Enhancing patient care: a multimodality strategy for dilated
cardiomyopathy in Chagas disease
Luigy Vasquez-Yeng1 , Juan Jose Hernandez-Ruiz2 , Mauricio Garcia-Cardenas1 , Raul
Velazquez-Castañeda2 , Santiago Luna-Alcala2 , Pavel Martinez-Dominguez2 , Enrique C. Guerra2 ,
José Armendariz-Ferrari1 , Nilda Espinola-Zavaleta2*
1
Department of Cardiology, Hipolito Unanue National Hospital, Lima 15007, Peru
2
Department of Nuclear Cardiology, National Institute of Cardiology Ignacio Chavez, Mexico City 14080, Mexico

*Correspondence: Nilda Espinola-Zavaleta, Department of Nuclear Cardiology, National Institute of Cardiology Ignacio
Chavez, Juan Badiano No 1, Colonia Seccion XVI Tlalpan, Mexico City 14080, Mexico. [email protected]
Academic Editor: Andrea Borghini, Institute of Clinical Physiology - National Research Council (IFC-CNR), Italy
Received: March 23, 2024 Accepted: August 5, 2024 Published: September 22, 2024

Cite this article: Vasquez-Yeng L, Hernandez-Ruiz JJ, Garcia-Cardenas M, Velazquez-Castañeda R, Luna-Alcala S, Martinez-
Dominguez P, et al. Enhancing patient care: a multimodality strategy for dilated cardiomyopathy in Chagas disease. Explor
Cardiol. 2024;2:196–203. https://doi.org/10.37349/ec.2024.00033

Abstract
Chagas disease is a systemic illness characterized by acute and chronic phases. If untreated, it can lead to
dysfunction of vital organs, notably the heart, ultimately resulting in heart failure. Transmission primarily
occurs through the feces of triatomine insects carrying the protozoan parasite Trypanosoma cruzi, either via
a bite wound or intact mucous membranes. Diagnosis of Chagas disease involves serological tests,
electrocardiographic findings, and imaging studies. A 58-year-old male patient from Peru with chronic
dilated cardiomyopathy underwent evaluation at a tertiary care hospital. Given the uncertain etiology, a
comprehensive diagnostic approach was adopted, emphasizing the pivotal role of cardiovascular magnetic
resonance imaging and computed tomography angiography in managing chronic cardiomyopathy of Chagas
disease. Leveraging these imaging modalities together could augment our ability to evaluate myocardial
inflammation and tailor therapeutic strategies accordingly.

Keywords
Cardiac magnetic resonance imaging, Chagas disease, multimodality, cardiomyopathy

Introduction
Chagas disease (CD) is caused by the protozoan Trypanosoma cruzi and is transmitted by triatomine insects
in endemic areas such as Mexico, Central America, and South America. In 2023, Peru was considered a high-
prevalence country, with 19 confirmed cases of CD reported [1, 2]. The infection leads to an acute phase
lasting 4–8 weeks, with 20–30% of cases progressing to chronic CD, characterized by cardiomyopathy and
megaviscera, ultimately leading to heart failure (HF).

© The Author(s) 2024. This is an Open Access article licensed under a Creative Commons Attribution 4.0 International
License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, sharing, adaptation, distribution
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original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Explor Cardiol. 2024;2:196–203 | https://doi.org/10.37349/ec.2024.00033 Page 196
 Recently, cardiovascular magnetic resonance (CMR) has gained significance as a noninvasive tool for
identifying myocardial inflammatory activity (edema and myocardial hyperemia) at an early stage. These
changes are identifiable before irreversible lesions such as necrosis and fibrosis develop. However, other
tools have also emerged, such as computed tomography (CT), for the early recognition of tissue
characterization. The combined use of these modalities can further enhance our ability to assess myocardial
inflammation and guide therapeutic interventions.

Case report
A 58-year-old male from San Martín, Peru, with a history of valvular disease diagnosed in 2020 and HF
(NYHA functional class II), sought medical care after two years of persistent and worsening respiratory
symptoms. He has worked in the agriculture field over the past decades. A transthoracic echocardiogram
revealed severe symptomatic mitral valve insufficiency. He was evaluated at a tertiary care hospital due to
exacerbated dyspnea (NYHA functional class IV), orthopnea, prominent edema, chest pain, and syncope.
Cardiovascular examination revealed jugular distension, hepatojugular reflux, and a holosystolic murmur at
the mitral and tricuspid foci.
As part of the medical evaluation, an electrocardiogram revealed sinus rhythm with left anterior
fascicular block and low QRS voltage (Figure 1); a chest X-ray showed moderate to severe cardiomegaly.
Subsequently, transthoracic echocardiography revealed a significant reduction in left ventricular systolic
function with a reduced left ventricular ejection fraction (LVEF 24%), global hypokinesia associated with a
suggestive image of an interatrial aneurysm, four-chamber dilation, and severe mitral and tricuspid
insufficiency (Figure 2). Mortality risk stratification was performed using the Rassi score, which yielded a
high-risk score of 17/20, considering the NYHA functional class IV, cardiomegaly, global wall-motion
abnormality, male sex, and low QRS voltage.

Figure 1. 12-lead electrocardiogram (ECG). The ECG shows sinus rhythm, frontal plane axis left deviation of 60°, in lead avL
qR pattern and R-peak time of 60 ms is observed (red square), QRS duration of 80 ms, and generalized low voltage

Due to suspicion of chronic ischemia, patient age, and findings of mitral insufficiency on
echocardiography, a coronary computed tomography angiography (CTA) was conducted, along with high-
sensitivity cardiac troponin T test (hs-cTnT) and C-reactive protein (CRP) levels. The imaging test did not
reveal abnormalities, and the hs-cTnT level upon admission was 6 ng/L, with no significant changes during
hospitalization, ruling out the probability of obstructive subepicardial coronary artery disease (Figure 3).
Additionally, the CRP levels were within the normal range at 0.55 mg/dL. Iodine contrast enhancement
confirmed inferolateral and apical aneurysmatic images, revealing transmural enhancement patterns in
aneurysmatic segments (Figure 4).
Systematically, the most common causes of non-ischemic dilated cardiomyopathy were excluded,
including toxic, endocrinological, nutritional, and autoimmune factors. Notably, given the endemic nature of

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Figure 2. Four-chamber view transthoracic echocardiography. (A) Global hypokinesia associated with a suggestive image of an
interatrial aneurysm (red circle). (B) Color-Doppler echocardiography evidencing four-chamber dilation with severe tricuspid
valve insufficiency (red arrow)

Figure 3. Coronary computed tomography angiography. (A and B) 3D cardiac reconstruction of the RCA (green arrow) and LCA
(red arrow). (C–E) Coronary computed tomography angiography showing adequate blood flow, absence of luminal
abnormalities, ruling out coronary disease. RCA: right coronary artery; LCA: left coronary artery; LAD: left anterior descending
artery; Cx: circumflex artery

Figure 4. Computed tomography showing delayed enhancement with iodine, protocol was implemented with low 80 kV and
maximum milliampere at 700 to enhance the iodine. Images were acquired at 7 min post-contrast. (A–C) Short axis view
showing inferolateral (white arrows) and apical (red arrows) aneurysmatic segment with transmural enhancement. (D and E)
Two-chamber view showing transmural enhancement at the level of the aneurysmatic segments (white arrows)

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Figure 5. Short axis view CMR. (A) T1 mapping CMR evidencing shortened global relaxation time (1,100 s) showed by areas
with increased signal (green circle), indicative of diffuse myocardial fibrosis. (B) T1 mapping CMR evidencing prolonged global
relaxation time (1,091 s) and presence of aneurysmatic segment (white arrow). (C and D) T2 mapping CMR evidencing increase
signal areas (red arrows) with increased T2 values corresponding to late gadolinium enhancement demonstrating presence of
edema. CMR: cardiovascular magnetic resonance

Figure 6. Post-contrast enhanced short T1 mapping cardiovascular magnetic resonance. (A) Four-chamber view providing a
comprehensive assessment of the heart chambers. (B–D) Basal third, middle third and apical third of the LV indicating fibrotic
changes according to ECV (32%). LV: left ventricle; ECV: extracellular volume

CD vectors in Peru, suspicion was raised, prompting the performance of an indirect chemiluminescent
immunoassay to detect specific IgG antibodies against excretory-secretory antigens of T. cruzi, as well as an
enzyme-linked immunosorbent assay for IgG, both of which returned positive results.
CMR was performed to quantify myocardial fibrosis and assess disease severity. T1 mapping revealed
prolonged global relaxation times (1,100 ms), indicating diffuse myocardial fibrosis (Figure 5). The
examination also revealed a 32% extracellular volume (ECV) fraction in post-contrast-enhanced T1
mapping, suggesting edema (Figure 6). Furthermore, contrast-enhanced gadolinium images confirmed a

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transmural pattern of late gadolinium enhancement (LGE), revealing 16 grams of fibrosis mass in
aneurysmal segments (Figure 7).

Figure 7. CMR with gadolinium. (A) Short axis view CMR with aneurysmal segments in the LV free wall, evidenced with LGE
(white arrow). (B) Short axis view CMR evidencing LGE transmural pattern with a fibrosis mass (white arrow) of 16 grams in the
apical aneurysmatic segments located in the LV. (C) Vertical long axis view CMR evidencing basal aneurysmatic segment with
presence of fibrosis (white arrow). CMR: cardiovascular magnetic resonance; LV: left ventricle; LGE: late gadolinium
enhancement

A 24-hour Holter study revealed sinus rhythm with a mean heart rate of 65 bpm. Additionally, it
showed isolated supraventricular extrasystoles, including bigeminy and trigeminy patterns, without
supraventricular tachycardia. Due to the high mortality risk associated with chronic cardiomyopathy of
Chagas disease (CCCD), an implantable cardioverter-defibrillator (ICD) was recommended for the
prevention of sudden cardiac death (SCD). The patient was discharged without complications following the
placement of the ICD.

Discussion
The diagnosis of CD involves conventional and non-conventional serological tests. According to the World
Health Organization, confirmation requires two positive results. Common electrocardiographic
abnormalities include complete right bundle branch block and left anterior fascicular block [3, 5].
Echocardiography plays a crucial role in assessing CCCD, enabling the prediction of mortality from
early changes to advanced stages with left ventricular enlargement and impaired systolic function. CCCD
patients presenting with atypical pain may undergo CTA to rule out obstructive subepicardial coronary
artery disease. Additionally, CT can be used for the early characterization of myocardial fibrosis through
late enhancement assessment and evaluate biventricular systolic function, complementing
echocardiography.
Holter monitoring aids in detecting cardiac arrhythmias for routine CCCD assessment, facilitating the
diagnosis of conditions such as sinus node dysfunction and supraventricular tachyarrhythmias.
Long-term mortality risk stratification using the Rassi score aids in directing therapy based on
individual survival probabilities determined by the existence of six clinical features: NYHA class III or IV,
cardiomegaly on chest radiography, segmental or global wall-motion abnormalities on echocardiography,
non-sustained ventricular tachycardia on Holter monitoring, low QRS voltage on electrocardiography, and
male sex. Patients at high risk of mortality may benefit the most from aggressive therapeutic interventions,
including ICD, heart transplantation, and cardiac resynchronization.
Comprehensive evaluation of CCCD also involves CMR, which correlates myocardial fibrosis with
disease severity, ventricular arrhythmias, and cardiovascular events. CMR assesses biventricular systolic
function, T2 mapping for edema, and LGE for regional fibrosis detection. Myocardial T1 mapping measures
ECV for interstitial fibrosis assessment, and global T1-weighted enhancement aids in detecting hyperemia
and inflammation. ECV fraction has a prognostic role in early-stage cardiomyopathy. The late enhancement
technique in CMR serves as a crucial predictor for severe cardiovascular events, independently forecasting

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Table 1. Role of cardiac imaging for the diagnosis and prognosis of CCCD

Cardiac study Initial indications Repeated testing Typical features
12-lead ECG Initial diagnostic and prognostic Perform an ECG Most frequent and defined alterations are
assessment of every individual with annually if there are atrioventricular conduction blocks, right
positive serology for CD, enabling the multiple specific bundle branch block, left anterior fascicular
clinical classification. changes or every two block, ventricular repolarization alterations,
years if the ECG is and ventricular ectopic beats.
normal or has Association of 2 or more abnormalities in
nonspecific (isolated) the same electrocardiographic tracing,
changes. characterizes severe cardiomyopathy.
Chest X-ray Initial diagnostic and prognostic Perform when there is An enlarged cardiac area with minimally
assessment of every individual with clinical evidence of congested pulmonary fields is often
CCCD. To diagnose cardiovascular pulmonary or systemic present. In addition, right ventricle
impairment. congestion. enlargement signs are common on
posteroanterior and lateral views. Signs of
right pleural effusion secondary to
systemic congestion can also be
evidenced.
Echocardiography Initial assessment and follow-up of Reassess periodically: Left ventricular enlargement, segmental
patients with CD. Assessment of every 3 to 5 years for and/or diffuse hypokinesia, ventricular
every individual with CCCD. preserved ejection aneurysms , and left ventricle dysfunction.
Suspicion of CCCD arises from fraction cases and no Alteration in myocardial relaxation is the
history, clinical examination, or previous segmental first change visible, as it progresses, it can
electrocardiographic changes. contractility changes. worsen to a typical restrictive pattern.
Reassess every 1 to
2 years for cases with
global or segmental left
ventricular dysfunction.
CMR When there is suspicion of concurrent Not established. Allows for morphological and functional
CCCD and coronary artery disease or assessment, globally and segmentally, as
other non-ischemic cardiomyopathy, well as the detection of intracardial
CMR is utilized to assess the etiology thrombi, overcoming technical limitations
and extent of myocardial fibrosis. of echocardiography.
In non-endemic areas where initial Identification of myocardial inflammatory
clinical suspicion of CD is absent, activity (edema and myocardial hyperemia)
CMR can strongly indicate probable at an early stage before the development
CCCD diagnosis based on LGE of irreversible lesions, such as necrosis
patterns, prompting further and fibrosis. They can aid in risk
serological tests for etiological stratification and therapeutic decision-
diagnosis confirmation. making.
T2-weighted images and T2 mapping
should be included for assessment of
myocardial edema in addition of LGE to
detect gross regional myocardial fibrosis.
T1 mapping should be included to
calculate the myocardial extracellular
volume (interstitial and diffuse fibrosis
measure).
Computed Non-invasive evaluation of coronary Not established. Characterization of normal myocardial
tomography anatomy in patients with CCCD and a tissue/fibrosis using late enhancement as
angiography high likelihood of obstructive an alternative to CMR.
subepicardial coronary artery Assessment of biventricular systolic
disease. function, along with echocardiography, for
patients with contraindications to CMR.
CCCD: chronic cardiomyopathy of Chagas disease; ECG: electrocardiogram; CD: Chagas disease; CMR: cardiovascular
magnetic resonance; LGE: late gadolinium enhancement

total death, cardiovascular death, and sustained ventricular tachyarrhythmias. The European Association of
Cardiovascular Imaging and the SBC Cardiovascular Imaging Department recommend CMR for quantifying
myocardial fibrosis extension, assessing SCD risk, and potentially influencing implantable ICD indications
[3, 7].
With a confirmed diagnosis of non-ischemic HF, a LVEF of 24%, and NYHA class IV, the individual met
class I Level B evidence criteria for an ICD according to the 2012 American Heart Association guidelines.
The ICD effectively addresses potential ventricular arrhythmias, preventing SCD, and offers a promising
approach to enhancing overall survival [8, 9].

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 The clinical case presented demonstrates how patients can benefit from a multimodality-based
strategy in CCCD, aiding in the selection of the most appropriate therapeutic management based on specific
findings (Table 1). While iodine late enhancement is an innovative technique that can assist in guiding
management, it does not replace gadolinium late enhancement for the determination of fibrosis and disease
severity.

Abbreviations
CCCD: chronic cardiomyopathy of Chagas disease
CD: Chagas disease
CMR: cardiovascular magnetic resonance
ECV: extracellular volume
HF: heart failure
ICD: implantable cardioverter-defibrillator
SCD: sudden cardiac death

Declarations
Author contributions
LVY: Project administration, Resources. JJHR: Writing—original draft, Writing—review & editing,
Investigation, Visualization, Supervision. MGC, PMD, ECG, and JAF: Resources. RVC: Investigation,
Writing—review & editing, Validation. SLA: Resources, Writing—review & editing. NEZ: Resources,
Writing—review & editing, Project administration. All authors read and approved the submitted version.

Conflicts of interest
The authors declare that they have no conflicts of interest.

Ethical approval
The research described in this case report has been conducted in accordance with the ethical guidelines
established by the World Medical Association’s Declaration of Helsinki for research involving human
subjects. Given the nature of this research—specifically, the retrospective analysis of anonymized clinical
data—the Ethics Committee of the National Institute of Cardiology Ignacio Chavez has determined that
specific ethical approval is not required.

Consent to participate
Informed consent to participate in the study was obtained from the participant.

Consent to publication
Informed consent to publication was obtained from relevant participant.

Availability of data and materials
The data is not publicly available due to ethical restrictions and legal constraints. But the data analyzed
during the current case report is available from the corresponding author on reasonable request.

Funding
Not applicable.

Copyright
© The Author(s) 2024.

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References
1. Nunes MCP, Beaton A, Acquatella H, Bern C, Bolger AF, Echeverría LE, et al.; American Heart
Association Rheumatic Fever, Endocarditis and Kawasaki Disease Committee of the Council on
Cardiovascular Disease in the Young; Council on Cardiovascular and Stroke Nursing; Stroke Council.
Chagas Cardiomyopathy: An Update of Current Clinical Knowledge and Management: A Scientific
Statement From the American Heart Association. Circulation. 2018;138:e169–209. [DOI] [PubMed]
2. Número de casos de Enfermedad de Chagas [Internet]. Centro Nacional de Epidemiologia, Prevención y
Control de Enfermedades; [cited 2023 May 21]. Available from: https://www.dge.gob.pe/portal/docs/
vigilancia/sala/2023/SE20/chagas.pdf
3. Marin-Neto JA, Rassi A Jr, Oliveira GMM, Correia LCL, Júnior ANR, Luquetti AO, et al. SBC Guideline on
the Diagnosis and Treatment of Patients with Cardiomyopathy of Chagas Disease — 2023. Arq Bras
Cardiol. 2023;120:e20230269. [DOI] [PubMed] [PMC]
4. Rassi A Jr, Rassi A, Little WC, Xavier SS, Rassi SG, Rassi AG, et al. Development and validation of a risk
score for predicting death in Chagas’ heart disease. N Engl J Med. 2006;355:799–808. [DOI] [PubMed]
5. Rojas LZ, Glisic M, Pletsch-Borba L, Echeverría LE, Bramer WM, Bano A, et al. Electrocardiographic
abnormalities in Chagas disease in the general population: A systematic review and meta-analysis.
PLoS Negl Trop Dis. 2018;12:e0006567. [DOI] [PubMed] [PMC]
6. Cardoso S, Azevedo Filho CF, Fernandes F, Ianni B, Torreão JA, Marques MD, et al. Lower Prevalence
and Severity of Coronary Atherosclerosis in Chronic Chagas’ Disease by Coronary Computed
Tomography Angiography. Arq Bras Cardiol. 2020;115:1051–60. [DOI] [PubMed] [PMC]
7. Haaf P, Garg P, Messroghli DR, Broadbent DA, Greenwood JP, Plein S. Cardiac T1 Mapping and
Extracellular Volume (ECV) in clinical practice: a comprehensive review. J Cardiovasc Magn Reson.
2016;18:89. [DOI] [PubMed] [PMC]
8. Tracy CM, Epstein AE, Darbar D, Dimarco JP, Dunbar SB, Estes NA 3rd, et al.; American College of
Cardiology Foundation; American Heart Association Task Force on Practice Guidelines; Heart Rhythm
Society. 2012 ACCF/AHA/HRS focused update of the 2008 guidelines for device-based therapy of
cardiac rhythm abnormalities: a report of the American College of Cardiology Foundation/American
Heart Association Task Force on Practice Guidelines and the Heart Rhythm Society. Circulation. 2012;
126:1784–800. [DOI] [PubMed]
9. Arbelo E, Protonotarios A, Gimeno JR, Arbustini E, Arbelo E, Barriales-Villa R, et al.; ESC Scientific
Document Group. 2023 ESC Guidelines for the management of cardiomyopathies. Eur Heart J. 2023;44:
3503–626. [DOI] [PubMed]

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