Background
Considered a neglected tropical disease, Chagas’ disease is caused by a protozoan parasite,
Trypanosoma cruzi (
T. cruzi) and has recently become a global health concern [
1], due to immigration from endemic areas into the developed world [
2,
3]. In Latin America, Chagas’ heart disease is still a major cause of heart failure despite a drop in incidence in the last decades [
4].
Patients with Chagas’ heart disease have a poorer prognosis in comparison to other cardiomyopathies and, in particular, male gender has been associated to a higher mortality rates [
5]. The reasons for this worse clinical prognosis remain unclear and, to our knowledge, there is a lack of studies about sex-related differences in myocardial damage in patients with Chagas’ heart disease.
Cardiovascular magnetic resonance (CMR) is able to assess the extent of the myocardial fibrosis (MF), which correlates to LV ejection fraction (LVEF) and is a marker of disease severity in Chagas’ heart disease [
6,
7]. We sought to investigate whether the male gender is associated to greater myocardial damage assessed by CMR.
Methods
From 2 previous studies [
6,
8], 62 adults with chronic Chagas’ disease followed at Heart Institute (InCor), referred to CMR, from 2004 to 2012 and with low probability of having severe coronary artery disease (CAD) [
9] were included in the study. We used a validated high-risk CAD score [
9] based on the following clinical characteristics recorded at the time of CMR: age (−1 to 10 points), male sex (3 points), diabetes (2 points), hypertension (1 point), current smoking (2 points), hypercholesterolemia (1 point), family history of CAD (2 points), history of peripheral vascular disease (2 points), and chest pain symptoms (0–2 points). Patients who scored ≥18 points were excluded. Other exclusion criteria were previous myocardial infarction and severe valve disease. Patients in whom oral transmission from outbreaks of either beverage or food contaminations was suspected - which has unfortunately emerged in Brazil [
10] - were not included in our study. The reason for this exclusion was the potentially more severe course of the disease following oral transmission [
11]. The study was approved by the institutional review board for human subject studies, and all patients provided written informed consent.
CMR
CMR was performed with a 1.5 T GE CV/i CMR System (Wakeusha Wisconsin). Ventricular function, volumes and mass were obtained from at least 10 short-axis ventricular slices, imaged with a steady state free precession pulse sequence, covering the entire left ventricle. Late gadolinium enhancement (LGE) images were acquired 10–20min after an intravenous bolus of 0.2 mmol/kg of gadolinium-based contrast, with an inversion-prepared gradient echo-sequence. The sequence parameters for cine/LGE imaging were, respectively: repetition time 3.9/7.1 ms, echo time 1.7/3.1 ms, flip angle 45°/20°, cardiac phases 20/1, views per segment 8/16 to 32, matrix 256 × 128/256 × 192, slice thickness 8/8 mm, gap between slices 2/2 mm and field of view 32 to 38/32 to 38 cm, inversion time none/150 to 250 ms, receiver bandwidth 125/31.25 kHz, number of excitations 1/1, acquisition every heart beat/every-other heart beat.
Data analysis
All CMR images were analyzed with the CVI42 software (Circle Cardiovascular Imaging Inc. Calgary, Canada) by a trained observer. End-systolic, end-diastolic LV volumes, LV mass and LV ejection fraction were measured by standard methods [
12]. For quantification of myocardial fibrosis (MF), we applied a semiautomatic thresholding technique to the LGE images with a signal intensity (SI) cutoff value of mean + 6 standard deviation (SD) (MF: SI ≥ meanSI of normal myocardium + 6 standard deviation of normal myocardium), which had best agreement with visual analysis. The location and extent of MF were assessed using the American Heart Association (AHA) segment model. Additionally, the pattern of LGE was classified as subendocardial, midwall, subepicardial or transmural. The myocardial heterogeneity or gray zone extent was defined as the myocardial region with pixels SI between meanSI + 6SD and meanSI + 7SD [
13‐
15].
Statistical analysis
Chi-squared or Fisher-exact tests and two-sample t-tests or Wilcoxon rank sum test for categorical or continuous data, respectively, were performed for comparing baseline characteristics across gender groups. The correlation between MF and LVEF was performed by Spearman’s test.
We assumed that MF lies on the causal pathway between gender and myocardial dysfunction in Chagas’ disease, as a mediator variable and we tested the following mediation assumptions [
16]: gender has a significant effect on MF; gender has a significant effect on LVEF in the absence of the MF; MF has a significant unique effect on LVEF; and the effect of the gender on LVEF shrinks when the MF is added to the model. A Sobel-Goodman test was used to assess whether the amount of mediation effect was statistically significant [
17]. After confirming the mediation assumptions, MF was added to the final model and a multivariate linear regression analysis was performed to determine the effect of gender on LVEF adjusted possible confounders. For all univariate and multivariate analysis, we used MF assessed as % LV mass since the normal population males have significantly greater myocardial mass [
18].
All statistical analyses were performed with Stata 13.0 (StataCorp, Texas, USA) and a P-value < 0.05 was considered as statistically significant and all reported P-values were two-tailed.
Discussion
In this study, we observed sex-related differences in myocardial damage assessed by CMR in patients with Chagas’ heart disease: males had significantly more adverse ventricular remodeling and greater MF, as well as different LGE patterns in comparison with females. Moreover, male gender was independently associated with reduced myocardial function and this effect was mostly mediated by MF. These findings might help to understand the observed gender-related differences in the pathogenesis of chronic Chagas’ heart disease.
Clinical data have revealed higher mortality among male patients with Chagas’ heart disease [
5,
19], but this is the first study to demonstrate a significantly higher degree of myocardial damage in vivo. In our study, males patients had lower LVEF by 30% and higher MF by 165% on average compared to females. The pathogenesis of chronic Chagas’ heart disease is complex, but the inflammatory process with autoimmune reaction is considered the main pathway for myocardial damage, increasing MF, adverse left ventricular remodeling and heart failure severity [
20‐
23]. In mouse models, this immune response against
T. cruzi infection was more unfavorable in male species, and linked to gonadal hormone differences [
24,
25]. MF measured by CMR is a key marker of myocardial damage in non-ischemic cardiomyopathies [
26‐
28] and, likewise, in Chagas’ heart disease [
6,
8]. For our patients, we found that the association between gender and LVEF was mediated by the amount of MF (53% of the effect was mediated). Hence, we hypothesized that male hormone differences might be an exposure to greater myocardial dysfunction in Chagas’ pathogenic, being the amount of MF a partly causal pathway.
Furthermore, the presence, size and heterogeneity of MF assessed by CMR have been described as independent predictors for death in ischemic and non-ischemic cardiomyopathies [
29‐
31]. Besides the greater MF amount, we observed the transmural pattern of MF more frequently in males than females (23.7 vs. 9.9%,
P < 0.001), as well as higher extent of the gray zones. Interestingly, the transmural pattern has been identified as independent predictor to ventricular tachycardia (4.1-fold greater) in Chagas’ heart disease [
32]. A higher myocardial heterogeneity and/or larger gray zone extent have also been associated with a higher frequency of adverse cardiac events in non-ischemic cardiomyopathies [
33].
There are several limitations in this study. First, although ventricular remodeling and MF have been linked to worse clinical prognosis, this study was not designed to investigate cardiac outcomes. Secondly, as this was a cross-sectional study in Chagas’ disease, the time of disease onset remained undetermined, and duration of exposure could influence myocardial damage. However, children aged <5 years are most likely to be infected in domiciliary vector transmission (by far, the most common mode of transmission in Brazil in the past) [
1,
34], and the number of new cases of Chagas’ disease have dramatically been decreasing in Brazil since 1990 [
1]. Consequently, our male and female patients, who were not different in age at the moment of CMR, may have similar exposure times. Thirdly, we recognize that as the patients have been followed at a tertiary hospital and current guidelines in Brazil do not recommend that patients with Chagas’ disease routinely undergo CMR, our results may not apply to other clinical settings and may suffer from some referral bias. Lastly, we did not assess the possible association between hormones and myocardial damage. Therefore our findings should be considered as hypothesis-generating for future studies adequately designed for addressing these issues.
Acknowledgements
Not applicable.
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