Hostname: page-component-76fb5796d-vvkck Total loading time: 0 Render date: 2024-04-25T16:49:24.566Z Has data issue: false hasContentIssue false
  • English
  • Français

Prognostic association of cardiac anxiety with new cardiac events and mortality following myocardial infarction

Published online by Cambridge University Press:  02 January 2018

Maria H. C. T. Van Beek ,
Marij Zuidersma ,
Martijn Lappenschaar ,
Gheorghe Pop ,
Annelieke M. Roest ,
Anton J. L. M. Van Balkom ,
Anne E. M. Speckens  and
Richard C. Oude Voshaar
Maria H. C. T. Van Beek*
Affiliation:
Department of Psychiatry, Radboud University Medical Centre, Nijmegen, The Netherlands
Marij Zuidersma
Affiliation:
University Medical Center Groningen, University Center for Psychiatry, and Interdisciplinary Center for Psychopathology and Emotion Regulation, University of Groningen, Groningen, The Netherlands
Martijn Lappenschaar
Affiliation:
Department of Psychiatry, Radboud University Medical Centre, Nijmegen, The Netherlands
Gheorghe Pop
Affiliation:
Department of Cardiology, Radboud University Medical Centre Nijmegen, Nijmegen, The Netherlands
Annelieke M. Roest
Affiliation:
University Medical Center Groningen, University Center for Psychiatry, and Interdisciplinary Center for Psychopathology and Emotion Regulation, University of Groningen, Groningen, The Netherlands
Anton J. L. M. Van Balkom
Affiliation:
Department of Psychiatry and EMGO+ Institute, VU University Medical Center, GGZinGeest, Amsterdam, The Netherlands
Anne E. M. Speckens
Affiliation:
Department of Psychiatry, Radboud University Medical Centre, Nijmegen, The Netherlands
Richard C. Oude Voshaar
Affiliation:
University Medical Center Groningen, University Center for Psychiatry, and Interdisciplinary Center for Psychopathology and Emotion Regulation, University of Groningen, Groningen, The Netherlands
*
Maria H. C. T. van Beek, Department of Psychiatry, Radboud University Medical Center, Nijmegen, The Netherlands. Email: marleen.vanbeek@radboudumc.nl
Rights & Permissions [Opens in a new window]

Abstract

Background

General anxiety and depressive symptoms following a myocardial infarction are associated with a worse cardiac prognosis. However, the contribution of specific aspects of anxiety within this context remains unclear.

Aims

To evaluate the independent prognostic association of cardiac anxiety with cardiac outcome after myocardial infarction.

Method

We administered the Cardiac Anxiety Questionnaire (CAQ) during hospital admission (baseline, n = 193) and 4 months (n = 147/193) after discharge. CAQ subscale scores reflect fear, attention, avoidance and safety-seeking behaviour. Study end-point was a major adverse cardiac event (MACE): readmission for ischemic cardiac disease or all-cause mortality. In Cox regression analysis, we adjusted for age, cardiac disease severity and depressive symptoms.

Results

The CAQ sum score at baseline and at 4 months significantly predicted a MACE (HRbaseline = 1.59, 95% CI 1.04–2.43; HR4-months = 1.77, 95% CI 1.04–3.02) with a mean follow-up of 4.2 (s.d. = 2.0) years and 4.3 (s.d. = 1.7) years respectively. Analyses of subscale scores revealed that this effect was particularly driven by avoidance (HRbaseline = 1.23, 95% CI 0.99–1.53; HR4-months = 1.77, 95% CI 1.04–1.83).

Conclusions

Cardiac anxiety, particularly anxiety-related avoidance of exercise, is an important prognostic factor for a MACE in patients after myocardial infarction, independent of cardiac disease severity and depressive symptoms.

Type
Papers
Information
The British Journal of Psychiatry , Volume 209 , Issue 5 , November 2016 , pp. 400 - 406
Copyright
Copyright © Royal College of Psychiatrists, 2016 

Potential factors that determine cardiac prognosis after a myocardial infarction include demographic and clinical parameters, health behaviours and psychiatric morbidities. Recently, the impact of anxiety symptoms on cardiac prognosis in patients with heart disease has gained more attention. In a meta-analysis, post-myocardial infarction anxiety was associated with a 36% increased risk of adverse cardiac outcomes. Reference Roest, Martens, Denollet and De Jonge1 Although this meta-analysis could not adjust for measures of disease severity, effect estimates of included studies that did adjust for measures of disease severity were only slightly or not attenuated. Reference Roest, Martens, Denollet and De Jonge1 Also, generalised anxiety disorder (GAD) was related to adverse outcomes in patients with myocardial infarction and this relationship was not explained by cardiac disease severity parameters. Reference Roest, Zuidersma and de Jonge2 In contrast, other studies described no association Reference Versteeg, Hoogwegt, Hansen, Pedersen, Zwisler and Thygesen3Reference Mayou, Gill, Thompson, Day, Hicks and Volmink5 or even a beneficial association in patients with myocardial infarction Reference Parker, Owen, Brotchie and Hyett6,Reference Parker, Hyett, Hadzi-Pavlovic, Brotchie and Walsh7 and those with stable coronary artery disease (CAD) Reference Meyer, Hussein, Lange and Herrmann-Lingen8 between anxiety and cardiac prognosis. Furthermore, a recent study in patients with CAD undergoing coronary artery bypass graft surgery showed different associations of different types of anxiety with cardiac prognosis: no association of fear and panic disorders and their symptom dimensions, but an adverse association with GAD. Reference Tully, Winefield, Baker, Denollet, Pedersen and Wittert9 These controversial findings suggest that different types of anxiety may be related differently to cardiac prognosis. As it remains unclear which specific aspects of anxiety are associated with cardiac prognosis, the need to examine the unique contribution of types of anxiety on cardiovascular risk has been advocated. Reference Roest, Martens, Denollet and De Jonge1,Reference Laan, Termorshuizen, Smeets, Boks, de Wit and Geerlings10 Recently, a population-based study found that worry predicted non-fatal cardiac outcome over a 3-year follow-up, whereas panic and phobia did not. Reference Batelaan, ten Have, Van Balkom, Tuithof and de Graaf11 Another population-based study suggested that in women phobic anxiety may predict fatal but not non-fatal cardiac events. Reference Albert, Chae, Rexrode, Manson and Kawachi12

After a myocardial infarction, cardiac stimuli and sensations may trigger specific anxiety symptoms, conceptualised as cardiac anxiety. This can be assessed reliably by the Cardiac Anxiety Questionnaire (CAQ). Reference Eifert, Thompson, Zvolensky, Edwards, Frazer and Haddad13,Reference Van Beek, Oude Voshaar, Deelen, Van Balkom, Pop and Speckens14 CAQ subscale scores in patients with myocardial infarction reflect fear, attention, avoidance of physical exercise and safety-seeking behaviour. Reference Van Beek, Oude Voshaar, Deelen, Van Balkom, Pop and Speckens14 Higher cardiac anxiety is shown to be associated with lower quality of life in patients with myocardial infarction. Reference Van Beek, Mingels, Oude Voshaar, Van Balkom, Lappenschaar and Pop15 To our knowledge, the association between cardiac anxiety and cardiac outcome has not been examined previously. Furthermore, in most studies anxiety symptoms are measured directly after hospital admission or surgery, Reference Roest, Martens, Denollet and De Jonge1 which may inflate the rates of psychopathology as a result of the temporary distress of admission to hospital. Long-term functional outcome may only be affected by psychopathological symptoms that persist, or develop during the first weeks as has been demonstrated for depressive symptoms. Reference Kaptein, de Jonge, van den Brink and Korf16 Previously, we showed that trajectories of cardiac anxiety after a myocardial infarction are largely determined within the first 3–4 months after the event. Reference Van Beek, Mingels, Oude Voshaar, Van Balkom, Lappenschaar and Pop15 The aim of the present study was to explore the impact of self-reported cardiac anxiety at both admission to hospital and at 4 months after discharge on cardiac prognosis after a myocardial infarction. We hypothesised that patients reporting elevated symptoms of cardiac anxiety had the worst cardiac prognosis independent of potential confounders like cardiac disease severity and depressive symptoms.

Method

Study population

For the present analysis we included patients with myocardial infarction enrolled in an exploratory prospective cohort study described previously. Reference Van Beek, Mingels, Oude Voshaar, Van Balkom, Lappenschaar and Pop15 Patients consecutively admitted to hospital with myocardial infarction between November 2006 and December 2007 to the Department of Cardiology of Radboud University Medical Centre, The Netherlands, were recruited within 2 days of admission. Eligible patients had to be diagnosed with ST-elevated myocardial infarction (STEMI) or non-ST-elevated myocardial infarction (NSTEMI). The diagnosis was confirmed by the presence of a rise and fall of troponin I (>0.20 μg/L).

Exclusion criteria were: age above 85 years, discharge from hospital within 2 days of admission, and inability to fill out questionnaires (because of insufficient knowledge of the Dutch language, cognitive impairment or being too ill to participate). The study protocol was approved by the local medical ethics committee, and all patients provided written informed consent.

Procedure

Between days 2 and 7 after admission (baseline), patients completed a set of self-report questionnaires including the CAQ Reference Eifert, Thompson, Zvolensky, Edwards, Frazer and Haddad13,Reference Van Beek, Oude Voshaar, Deelen, Van Balkom, Pop and Speckens14 and the Beck Depression Inventory (BDI). Reference Beck, Ward, Mendelson, Mock and Erbaugh17 Four months after discharge patients were sent the same questionnaires by post. If necessary, patients were contacted by phone as a reminder.

Measures

Assessment of cardiac anxiety

Cardiac anxiety was assessed with the 18-item self-report-questionnaire CAQ, rating each item on a five-point Likert scale ranging from 0 (never) to 4 (always). Reference Eifert, Thompson, Zvolensky, Edwards, Frazer and Haddad13 In line with previous publications, the overall score as well as subscale scores are expressed as an average item score, which was computed by summing the score for the relevant items and dividing it by the number of items. The CAQ is well-validated in different populations, originally by Eifert et al. Reference Eifert, Thompson, Zvolensky, Edwards, Frazer and Haddad13,Reference Van Beek, Oude Voshaar, Deelen, Van Balkom, Pop and Speckens14,Reference Marker, Carmin and Ownby18 Recently, we cross-validated the CAQ in patients with myocardial infarction and identified a factor structure of four subscales: assessing fear (for example, ‘When I have chest discomfort, or when my heart is beating fast: I get frightened’), attention (for example, ‘I pay attention to my heartbeat’), avoidance of (physical) activity (such as, ‘I avoid activities that make my heart beat faster’) and safety-seeking behaviour (such as, ‘When I have chest discomfort or when my heart is beating fast, I like to be checked out by a doctor’), respectively. Reference Van Beek, Oude Voshaar, Deelen, Van Balkom, Pop and Speckens14 Our study showed a good internal consistency of both total and subscale scores (Cronbach α = 0.84 and 0.6–0.9, respectively), a high test–retest-reliability (0.88, P<0.001) and low to moderate correlations with questionnaires such as the Agoraphobic Cognitions questionnaire (0.31), the State–Trait- Anxiety Inventory (0.39) and the Beck Depression Inventory (BDI, 0.27). Comparable results, including the four subscales, have been previously reported in an independent cross-validation study in 658 people referred for screening for coronary artery disease. Reference Marker, Carmin and Ownby18 We confirmed the four subscales factor solution on the present data. In the present study, our main predictors were the continuous overall mean item score of the CAQ (i.e. total score divided by number of items), as well as the mean item score of the subscales.

Assessment of covariates

Sociodemographic and cardiac-related variables

Sociodemographic and clinical data concerning the severity of the cardiac disease (left ventricular ejection fraction (LVEF) and a history of myocardial infarction), as well as relevant cardiac risk factors (including smoking, hypertension, hypercholesterolemia, diabetes mellitus, history of stroke, peripheral atherosclerotic disease, history of cardiac disease other than myocardial infarction) were collected by the cardiologist during the admission to hospital for the myocardial infarction. LVEF was determined by echocardiography according to the modified Simpson's rule. Reference Folland, Parisi, Moynihan, Jones, Feldman and Tow19 Information on possible treatment with percutaneous coronary intervention (PCI) and assignment for cardiac rehabilitation after admission was retrieved from the hospital files.

Psychiatric comorbidity

Anxiety often coincides with depression in patients with myocardial infarction. Reference Denollet, Strik, Lousberg and Honig20 Two meta-analyses have identified depression in individuals with myocardial infarction as a risk factor for all-cause mortality, cardiac mortality and cardiac events. Reference Meijer, Conradi, Bos, Thombs, van Melle and de Jonge21,Reference Nicholson, Kuper and Hemingway22 In order to adjust for depression as a covariate, depressive symptoms were measured with the BDI, a 21-item self-report questionnaire rating each item on a four-point Likert scale, which is well-validated in people with myocardial infarction. Reference Beck, Ward, Mendelson, Mock and Erbaugh17,Reference Strik, Honig, Lousberg and Denollet23

Assessment of adverse outcomes

The primary outcome was a major adverse cardiac event (MACE), defined by all-cause mortality or a readmission for a major cardiac event, occurring after the CAQ assessment at baseline or 4 months after discharge, respectively. Hospital readmissions with discharge diagnoses with ICD-9 codes 410, 411, 413, 414 (ischemic heart disease); 427.4 (ventricular fibrillation and flutter), 427.5 (cardiac arrest) and/or readmissions for an acute (unplanned) coronary intervention (coronary artery bypass graft/ percutaneous coronary intervention) were included as a major cardiac event. 24 Data on all-cause mortality were obtained up until 1 January 2013 from the Dutch Central Bureau of Statistics by linkage to the municipal personal records database. Data concerning hospital admissions came from the Dutch national registry of hospital discharges and were obtained up until 1 January 2012 from the Dutch Central Bureau of Statistics by linkage to the municipal personal records database. Furthermore, in order to obtain more complete data, we also examined the administration and patient records of the Radboud University Medical Centre on readmissions for a MACE and/or mortality. These data were obtained up until 1 January 2013.

Statistical analysis

Multiple imputation model

In order to use all available data for survival analysis, we performed multiple imputations in patients with data on a MACE. Rubin's rules were used to pool the data. Reference Rubin25 Linear and logistic regression for multiple imputations was performed with all variables to be included in the final analysis model, as well as other relevant variables that were not included in the analyses, including cardiac risk and disease variables, PCI treatment and assignment to cardiac rehabilitation. These variables were examined for normal distribution and, if needed, transposed before the imputation was run; BDI was natural log-transformed. In total, 7.0% of all values in the imputation model were missing. A total of 67 data-sets were created, because 67.0% of the cases had at least one missing value. Reference White, Royston and Wood26 For each imputed file, SPSS estimated the missing values in 100 iterations.

Baseline

Baseline demographic and clinical characteristics were compared between patients with and without a MACE with logistic regression (for categorical variables), Student's t-test, or when continuous variables were not normally distributed with the Mann–Whitney U-test.

Correlation and survival analysis.

The correlation between sum scores of the CAQ and the BDI was evaluated with Spearman's rho. For the survival analysis, Cox regression was used to evaluate risk of a MACE associated with CAQ sum scores at baseline and at 4 months after discharge. Next, using Cox regression, the association between each of the four CAQ subscales at baseline and at 4 months after discharge with MACE was evaluated. For analyses with CAQ at admission to hospital as determinant, the follow-up period for the primary end-point started at admission to hospital for the index myocardial infarction. For analyses with CAQ at 4 months after index myocardial infarction as determinant, the follow-up period for the primary end-point started at the date of this CAQ assessment. In all analyses the follow-up period for primary end-points ended on 1 January 2013, and patients who did not have the outcome of interest until 1 January 2013 were censored on 1 January 2013.

In the basic model, adjustments were made for age and gender. A priori we decided to adjust for a history of myocardial infarction and LVEF as objective parameters of cardiac disease severity, as both have been shown to be consistently related to worse cardiac prognosis. In addition, since cardiac-related hospital readmissions between baseline and 4 months also reflect cardiac disease severity, we adjusted for this characteristic when examining the CAQ score at 4 months after discharge. In the final model, we also adjusted for BDI scores.

Sensitivity analyses

Post hoc sensitivity analyses were performed in order to further adjust separately for possible confounders. In the basic model we tested those characteristics that at baseline differed between patients with and without a MACE. Furthermore, gender-effects were explored post hoc as depression has a greater impact on mortality in men than in women, Reference Van Loo, van den Heuvel, Schoevers, Anselmino, Carney and Denollet27 although other studies have not found gender-specific effects with respect to cardiac prognosis. Reference Frasure-Smith, Lesperance, Juneau, Talajic and Bourassa28,Reference Frasure-Smith and Lesperance29 For the latter sensitivity analysis, we included this interaction variable in the regression model for multiple imputations. For all analyses, SPSS 20 for Windows was used and the significance level was set at 0.05, two-tailed.

Results

Sample

Of 398 people with myocardial infarction admitted to the cardiology ward, 135 patients were, after a primary PCI, relocated to a hospital in their home area within 2 days of admission. Of the 263 patients who were still present at the time we asked for informed consent, 203 patients (77%) agreed to participate. Ten individuals had to be excluded because of missing data on a MACE, leaving 193 patients to be analysed for the association between CAQ at baseline and a MACE. Baseline characteristics, resulting from the imputational model, for the 193 patients stratified according to occurrence of a MACE are shown in Table 1. Four people died before the assessment 4 months after discharge, leaving 189 people to be analysed for the association between CAQ at 4 months after discharge and a MACE.

Table 1 Baseline characteristics of 193 patients with myocardial infarction according to incidence of a major adverse cardiac event (MACE) (yes/no) a

MACE
(n = 77)		 No MACE
(n = 116)		 OR b t-test Mann-Whitney
U-test		 P
Age, mean (s.d.) 66.0 (11.6) 58.7 (11.0) 4.394 <0.001***
Male, n (%) 46 (59.7) 83 (71.6) 0.590 0.089
Stable relationship, n (%) 57 (74.0) 97 (83.6) 1.791 0.107
Higher education, n (%) 20 (26.0) 30 (25.9) 0.981 0.953
Hypertension, n (%) 40 (51.9) 45 (38.8) 0.586 0.072
Diabetes mellitus, n (%) 21 (27.3) 12 (10.3) 0.308 0.003**
Hypercholesterolemia, n (%) 22 (28.6) 33 (28.4) 0.994 0.985
History of myocardial infarction, n (%) 41 (53.2) 21 (18.1) 0.194 <0.001***
History of cardiac disease other than myocardial
infarction, c n (%)		 30 (39.0) 11 (9.5) 0.164 <0.001***
Peripheral atherosclerotic disease, n (%) 14 (18.2) 14 (12.1) 0.618 0.241
History of stroke, n (%) 3 (3.9) 4 (3.4) 0.881 0.871
Smoker at inclusion, n (%) 38 (49.4) 45 (38.8) 1.58 0.157
Family history of cardiac disease, n (%) 34 (44.2) 51 (44.0) 0.993 0.982
Left ventricular ejection fraction %, mean (s.d.) 51.9 (12.7) 54.2 (10.3) 1.164 0.245
CAQ at hospital admission, mean (s.d.) 1.5 (0.6) 1.3 (0.6) 2.333 0.020*
CAQ 4 months after discharge, mean (s.d.) 1.3 (0.7) 1.0 (0.6) 2.908 0.004**
BDI at hospital admission, median (IQR) 6.8 (4.0–12.0) 6.0 (3.9–9.5) 3483 0.257
BDI 4 months after discharge, median (IQR) 7.0 (4.8–11.0) 4.0 (2.0–8.0) 1758.5 0.002**
Percutaneous coronary intervention, n (%) 44 (57.1) 73 (62.9) 1.28 0.412
Assigned for cardiac rehabilitation, n (%) 35 (45.5) 87 (75.0) 3.56 0.001**

BDI, Beck Depression Inventory; CAQ, Cardiac Anxiety Questionnaire; IQR, interquartile range.

a. Rubin's rules were used to pool the data of the imputed data-sets. Reference Rubin25

b. We report odds ratio (based on univariate analysis) for all categorical variables.

c. Including for example stable angina pectoris, endocarditis, heart failure and atrial fibrillation.

*P<0.05; **P<0.01; ***P<0.001.

The mean duration of assessment of CAQ and BDI at baseline was 3.7 days (s.d. = 3.8) from admission to hospital (or index myocardial infarction). The next CAQ assessment took place 138.8 days (s.d. = 59.4) from admission to hospital (i.e. about 4 months post-myocardial infarction). A total of 77.8% of patients (n = 147/189) completed the CAQ at follow-up. Sum scores of CAQ and BDI were moderately correlated at admission to hospital (Spearman's ρ = 0.332, P<0.001)) and highly correlated at 4 months after discharge (ρ = 0.501, P<0.001).

Predictors of a MACE

During a mean follow-up period of 4.2 years (s.d. = 2.0) (range 0–6.6 years), 77 (39.9%) of 193 patients had a MACE after baseline. A total of 36 of them (46.8%) died. During a mean follow-up period of 4.3 years (s.d. = 1.7) (range 0–6.0 years), 67 (35.4%) of 189 patients had a MACE after the 4-month CAQ assessment. A total of 32 of them (47.8%) died. Patients who had an event during the follow-up period were older (P<0.001), had higher CAQ scores at baseline (P = 0.020) and 4 months after the index myocardial infarction (P = 0.004), had higher BDI scores at 4 months after the index myocardial infarction (P = 0.002), were more likely to have a history of myocardial infarction and cardiac disease other than myocardial infarction (P<0.001), or diabetes mellitus (P = 0.003) and were less likely to be assigned to cardiac rehabilitation (P = 0.004) (Table 1).

CAQ sum score and risk of a MACE

CAQ at baseline was significantly associated with a higher risk of a MACE, independent of age and gender, LVEF and cardiac history, and BDI. CAQ at 4 months after discharge was also significantly associated with a higher risk of a MACE, even when adjusted for age, gender, LVEF, cardiac history, cardiac-related hospital readmissions between the index event and CAQ assessment and BDI (see Table 2 for hazard ratios (HRs) with 95% confidence intervals).

Table 2 Hazard ratios (95% CI) for a major adverse cardiac event (MACE) associated with scores on the Cardiac Anxiety Questionnaire (CAQ) during admission to hospital and at 4 months after discharge a

CAQ sum score at hospital admission (n = 77/193) CAQ sum score at approximately 4 months after discharge (n = 67/189)
Hazard ratio (95% CI) P R 2, % Hazard ratio (95% CI) P R 2
Model 1 1.70 (1.16–2.46) 0.006** 4.1 2.09 (1.38–3.17) 0.001** 8.0
Model 2 1.64 (1.14–2.38) 0.008** 13.1 2.04 (1.30–3.19) 0.002** 12.9
Model 3 1.52 (1.03–2.23) 0.034* 22.6 2.00 (1.24–3.23) 0.005** 20.3
Model 4 1.59 (1.04–2.43) 0.033* 22.8 1.77 (1.04–3.02) 0.036* 21.1

a. Rubin's rules were used to pool the data of the imputed data-sets. Reference Rubin25 The explained variance (R 2) for Cox regression was estimated based on the log likelihood as proposed in Hosmer et al. Reference Hosmer, Lemeshow and May30 Model 1: unadjusted; Model 2: adjusted for age and gender; Model 3: Model 2 + left ventricular ejection fraction, history of myocardial infarction and hospital readmissions between the index event and CAQ assessment 4 months after discharge in the model evaluating hazard ratios at 4 months. Model 4: Model 3 + transformed Beck Depression Inventory score at same time as cardiac anxiety assessment (i.e. at baseline or 4 months after discharge, respectively). Baseline assessment was at a mean of 3.7 days (s.d. = 3.8) from admission to hospital; assessment 4 months after discharge was a mean of 138.8 days (s.d. = 59.4) from hospital admission; mean follow-up time for a MACE after CAQ at hospital admission was 4.2 years (s.d. = 2.0); mean follow-up time for MACE after CAQ at 4 months after discharge was 4.3 years (s.d. = 1.7).

*P<0.05; **P<0.01; ***P<0.001.

Subscales of CAQ at 4 months after discharge and risk of a MACE

Only the subscale ‘Avoidance’ at 4 months after discharge was significantly associated with a MACE independent from all previously mentioned covariates. The prognostic association of ‘Avoidance’ at baseline lost significance after adjusting for severity of cardiac disease (see Table 3 for hazard ratios with 95% confidence intervals).

Table 3 Hazard ratio's (95% CI) for a major adverse cardiac event (MACE) associated with scores on the four Cardiac Anxiety Questionnaire (CAQ) subscales during hospital admission and at 4 months post-myocardial infarction

Fear Avoidance Attention Safety seeking
Hazard ratio
(95% CI), P 		R 2, % Hazard ratio
(95% CI), P 		R 2, % Hazard ratio
(95% CI), P 		R 2, % Hazard ratio
(95% CI), P 		R 2, %
CAQ baseline: n = 77 of a total N = 193 had a MACE
    Model 1 1.29 (0.95–1.75) 0.104 1.3 1.34 (1.10–1.64) 0.003** 5.0 1.02 (0.73–1.42) 0.917 0.0 1.29 (1.01–1.66) 0.046* 2.1
    Model 2 1.33 (0.98–1.80) 0.067 11.2 1.31 (1.08–1.59) 0.007** 13.5 1.08 (0.78–1.50) 0.625 9.9 1.20 (0.94–1.54) 0.137 10.8
    Model 3 1.30 (0.94–1.81) 0.119 21.7 1.23 (1.00–1.51) 0.053 22.4 1.05 (0.76–1.46) 0.761 20.8 1.25 0.97–1.61) 0.084 22.0
    Model 4 1.32 (0.92–1.90) 0.1436 21.8 1.23 (0.99–1.53) 0.060 22.5 1.04 (0.74–1.45) 0.843 20.8 1.25 (0.96–1.62) 0.093 22.0
CAQ 4 months after discharge: n = 67 of a total N = 189 had a MACE
    Model 1 1.27 (0.95–1.70) 0.114 2.7 1.64 (1.32–2.04) <0.001** 10.3 1.41 (0.93–2.12) 0.106 1.9 1.13 (0.85–1.50) 0.416 0.6
    Model 2 1.24 (0.93–1.66) 0.138 8.6 1.60 (1.26–2.02) <0.001*** 14.2 1.54 (0.99–2.39) 0.054 9.0 1.07 (0.80–1.42) 0.665 6.6
    Model 3 1.25 (0.93–1.68) 0.146 17.1 1.51 (1.18–1.95) 0.001** 20.4 1.52 (0.98–2.36) 0.062 17.3 1.10 (0.80–1.50) 0.557 15.5
    Model 4 1.09 (0.78–1.53) 0.616 19.0 1.41 (1.07–1.86) 0.014* 21.7 1.45 (0.92–2.28) 0.111 20.2 1.07 (0.78–1.46) 0.690 18.8

The explained variance (R 2) for Cox regression was estimated according based on the log likelihood as proposed in Hosmer et al Reference Hosmer, Lemeshow and May30

Model 1: unadjusted; Model 2: adjusted for age and gender; Model 3: Model 2 + left ventricular ejection fraction and history of myocardial infarction, and hospital readmissions between the index event and CAQ assessment 4 months after discharge in the model evaluating hazard ratio at 4 months; Model 4: Model 3 + transformed Beck Depression Inventory score at the same time as CAQ assessment (i.e. baseline or 4 months after discharge respectively).

*P<0.05; **P<0.01; ***P<0.001.

Sensitivity analyses for potential cardiac risk factors

In sensitivity analyses, we tested whether characteristics that differed at baseline between patients with and without a MACE and that were not included in our model, might have influenced our results. Adding these variables (see Table 1) to model 2 generally did not affect the association between overall CAQ score and adverse prognosis. The only exception was the presence of a history of cardiac disease other than myocardial infarction: in this model the hazard ratio for CAQ at baseline and a MACE was attenuated to just be non-significant (HR = 1.43, 95% CI 0.96–2.11, P = 0.076).

Sensitivity analyses for gender differences in overall CAQ score and risk of a MACE

We found an interaction effect between gender with overall CAQ score in the prognostic model (included variables: CAQ, gender, age, interaction gender–CAQ) at baseline (HRbaseline = 2.16, 95% CI 1.03–4.56, P = 0.043; HR4-months = 2.78, 95% CI 1.00–7.72, P = 0.050). Stratified analyses showed larger hazard ratios and more significant results in the women compared with the men. Only in women, did the full model remain significant for the CAQ at baseline (HR = 3.04, 95% CI 1.47–6.28, P = 0.003, n = 64 of which n = 31 had a MACE during follow-up), whereas the hazard ratio for the CAQ at 4 months lost significance after additional adjustment for BDI (HR = 2.17 (95% CI 0.78–6.07), P = 0.139, n = 62 of which n = 27 had a MACE during follow-up, see online Tables DS1–3).

Discussion

Main finding

This study was the first to address the independent prognostic association of cardiac anxiety following myocardial infarction with adverse cardiac prognosis. Patients reporting higher cardiac anxiety were at increased risk of an adverse prognosis after adjustment for age, gender, cardiac disease severity parameters and depressive symptoms; with each point increase on the CAQ, which has a possible range of 0 to 4, the risk of a new cardiac event increased from 56% (at baseline) to 71% (at 4 months after discharge). This effect seemed to be particularly driven by avoidance behaviour.

Our findings are in line with previous research reporting the prognostic impact of anxiety Reference Roest, Martens, Denollet and De Jonge1 and anxiety disorders Reference Roest, Zuidersma and de Jonge2,Reference Frasure-Smith and Lesperance29,Reference Martens, de Jonge, Na, Cohen, Lett and Whooley31 in patients with myocardial infarction. These heterogeneous studies used different anxiety measures and the reported hazard ratios in the meta-analysis (around 1.30) Reference Roest, Martens, Denollet and De Jonge1 were based on dichotomous cut-off points of anxiety (present or not) that makes it difficult to compare the reported hazard ratios with ours. One study evaluated the prognostic association of separate dimensions of anxiety in patients with myocardial infarction. It also described an adverse prognostic association: significant associations for somatic anxiety (HR = 1.29) and total anxiety (HR = 1.38), with a trend for psychological anxiety. Reference Roest, Martens, de Jonge and Denollet32 However, these anxiety dimensions were derived from a questionnaire assessing general anxiety (Hamilton Anxiety and Depression Rating Scales) and all dimensions are more or less associated with avoidance behaviour. These general findings are extended by our findings showing the most specific results for avoidance behaviour related to cardiac stimuli, especially at 4 months after discharge.

In our study, after adjustment for parameters of cardiac disease severity, the association of cardiac anxiety with a MACE remained significant. More importantly, the hazard ratios hardly attenuated, implying a prognostic effect of cardiac anxiety independent from cardiac disease severity. Adjustment for depressive symptoms did not affect the effect size of the cardiac anxiety on adverse cardiac prognosis. This is consistent with other studies assessing the association between general anxiety or anxiety disorder and cardiovascular events independent from depression. Reference Roest, Zuidersma and de Jonge2,Reference Martens, de Jonge, Na, Cohen, Lett and Whooley31,Reference Strik, Denollet, Lousberg and Honig33

Potential mechanisms

The association between anxiety and ischemic heart disease might be explained by both behavioural and biological mechanisms. First, anxiety appears to be associated with unhealthy behaviour (for example, physical inactivity and smoking) in individuals at risk of coronary heart disease. Reference Bonnet, Irving, Terra, Nony, Berthezene and Moulin34 Our finding that the main prognostic effect of cardiac anxiety was driven by the subscale assessing avoidance of physical activity supports this. Surprisingly though, in our study patients reporting higher anxiety less often smoked. Although this is in contrast with a recent finding suggesting less adherence to risk-reducing recommendations (such as cessation of smoking) in patients with myocardial infarction who are also anxious, Reference Kuhl, Fauerbach, Bush and Ziegelstein35 this difference might be caused by the type of anxiety (general v. cardiac) examined, or by differences in coping strategies of individual patients.

Unfortunately, our data do not provide any insight into potential biological mechanisms explaining the negative association between anxiety and cardiac disease, such as reduced heart rate variability, cardiac arrhythmias and increased platelet activity or inflammation. Reference Cameron, Smith, Lee, Hollingsworth, Hill and Curtis36Reference Martens, Nyklícek, Szabó and Kupper38 For example, increased anxiety levels may trigger ventricular tachycardias in a dose-dependent way and are, among patients with implantable cardioverter defibrillators, associated with a higher number of implantable cardioverter defibrillator shocks. Reference Habiboviæ, Pedersen, van den Broek, Theuns, Jordaens and van der Voort39

Methodological considerations

A strength of the present study is that cardiac anxiety was assessed not only at admission to hospital but also at 4 months after the infarction, when the possible inflating impact of the stressful admission to hospital and the event itself on anxiety parameters is expected to have settled down. Reference Van Beek, Mingels, Oude Voshaar, Van Balkom, Lappenschaar and Pop15 Importantly, although our sample size was relatively small, it was large enough to adjust for several important confounders simultaneously. Nonetheless, we were not able to address all indicators of cardiac disease severity. Therefore, we adjusted for the two most important indicators, LVEF and a history of a myocardial infarction, in line with previous studies on this topic. However, since cardiac anxiety was inversely correlated with cardiac disease severity, as previously reported by our group, Reference van Beek, Oude Voshaar, van Deelen, van Balkom, Pop and Speckens40 it seems unlikely that our results are driven by residual confounding because of cardiac disease severity.

In line with previous studies we chose as primary outcome a combination of all-cause mortality and cardiac readmissions. However, whereas previous studies included a rather broad range of cardiovascular events, Reference Roest, Martens, Denollet and De Jonge1,Reference Roest, Zuidersma and de Jonge2,Reference Meijer, Conradi, Bos, Thombs, van Melle and de Jonge21 we only included readmissions for acute ischemic events. We consider this as an advantage. As patients with high cardiac anxiety might be more likely to consult their doctor and be admitted to the hospital with cardiac complaints, this might partly explain the association between cardiac anxiety and cardiovascular-related hospital readmissions. By only including readmissions because of acute ischemic events, this risk is minimised.

Although the prognostic association of cardiac anxiety with a MACE was particularly driven by avoidance of physical activity, it is important to realise that physical activity was not assessed in the present study and some of the other dimensions of cardiac anxiety (fear and attention, respectively) showed even higher hazard ratios than avoidance. The prognostic associations of these subscales were not significant in the final model, but this may be explained by a power problem (type two error). Studies in larger populations are needed to examine this more closely. Future studies should include physical activity as a mediating mechanism when studying the prognostic impact of cardiac anxiety.

Limitations of the present study include the absence of information on presence (and/or history) of a formal diagnosis of an anxiety and/or depressive disorder, nor did we have information on possible psychiatric treatment. Therefore, we do not know how cardiac anxiety is related to psychiatric diagnosis. As (some) anxiety disorders have been associated with the development of coronary heart disease in the general population Reference Albert, Chae, Rexrode, Manson and Kawachi12,Reference Janszky, Ahnve, Lundberg and Hemmingsson41 and prognosis in patients with heart disease, Reference Roest, Zuidersma and de Jonge2,Reference Frasure-Smith and Lesperance29,Reference Hosmer, Lemeshow and May30 this would have been interesting. Nevertheless, we did adjust for depressive symptoms, which is an important possible confounder. Reference Meijer, Conradi, Bos, Thombs, van Melle and de Jonge21,Reference Nicholson, Kuper and Hemingway22

Our study had a good response rate of 77%, Reference Van Beek, Mingels, Oude Voshaar, Van Balkom, Lappenschaar and Pop15 even though we had to exclude the most severely ill patients. On the other hand, patients with milder symptoms, who were transported to other hospitals within 2 days, were not eligible for the present study and it is questionable whether this limits generalisation of our results.

In our study, the association between cardiac anxiety and adverse prognosis could not be explained by cardiac disease severity parameters, including LVEF and cardiac history. Nevertheless, it is still possible that the association is confounded by disease severity, especially since some symptoms of cardiac anxiety, such as chest pain, might also be symptoms of heart disease. However, most items in the CAQ focus on the impact of these symptoms on affect (anxious), thought (worrying) or behaviour (avoidance and safety-seeking behaviour).

Although the hazard ratios were particularly higher for women, the gender-specific findings should be considered preliminary because of lack of statistical power. Moreover, the gender-effect was opposite to that found for the association between depression and mortality in cardiac patients Reference Van Loo, van den Heuvel, Schoevers, Anselmino, Carney and Denollet27 and two smaller studies with underrepresentation of women did not find gender effects. Reference Frasure-Smith, Lesperance, Juneau, Talajic and Bourassa28,Reference Frasure-Smith and Lesperance29 Therefore, future studies examining anxiety should preferably examine possible interaction effects with gender.

Clinical implications

The present findings of a prognostic association with a MACE, independent from cardiac disease severity and depressive symptoms, stress the potential clinical impact of cardiac anxiety. Interestingly, when looking at the CAQ score alone, the explained variance increased in the follow-up model compared with the baseline measurement (4 and 8% respectively), indicating the importance of identifying (persisting) cardiac anxiety symptoms in the months post-myocardial infarction. Diagnosing elevated cardiac anxiety symptoms, and its specific subtypes, can be helpful in developing specific interventions to reduce maintaining or exacerbating factors, such as avoidance of cardiac stimuli and physical exercise. Cognitive–behavioural therapy (CBT) may target anxiety-related avoidance behaviour, which may even result in a better cardiac outcome. General CBT focusing on stress management has been shown to improve cardiac outcome over 8 years post-myocardial infarction. Reference Gulliksson, Burell, Vessby, Lundin, Toss and Svärdsudd42 For this reason, cardiac anxiety should be explicitly addressed in cardiac rehabilitation programmes. Whereas there is awareness of general anxiety in cardiac rehabilitation programmes and recent studies have paid attention to specific types of anxiety recognised by the DSM, such as GAD, Reference Tully, Winefield, Baker, Denollet, Pedersen and Wittert9 cardiac anxiety may in fact be relatively unexplored. Outcomes of cardiac rehabilitation programmes might even improve further if physical exercise is used as a behavioural experiment to test out specific cardiac fears patients may have. In conclusion, the findings of the present study indicate the need to evaluate and target cardiac anxiety – in addition to depression and general anxiety – in the future.

Footnotes

Declaration of interest

None.

References

1 Roest, AM, Martens, EJ, Denollet, J, De Jonge, P. Prognostic association of anxiety post myocardial infarction with mortality and new cardiac events: a meta-analysis. Psychosom Med 2010; 72: 563–9.Google Scholar
2 Roest, AM, Zuidersma, M, de Jonge, P. Myocardial infarction and generalised anxiety disorder: 10-year follow-up. Br J Psychiatry 2012; 200: 324–9.Google Scholar
3 Versteeg, H, Hoogwegt, MT, Hansen, TB, Pedersen, SS, Zwisler, AD, Thygesen, LC. Depression, not anxiety, is independently associated with 5-year hospitalizations and mortality in patients with ischemic heart disease. J Psychosom Res 2013; 75: 518–25.Google Scholar
4 Lane, D, Carroll, D, Ring, C, Beevers, DG, Lip, GY. Mortality and quality of life 12 months after a myocardial infarction: effects of depression and anxiety. Psychosom Med 2001; 63: 221–30.CrossRefGoogle ScholarPubMed
5 Mayou, RA, Gill, D, Thompson, DR, Day, A, Hicks, N, Volmink, J, et al. Depression and anxiety as predictors of outcome after myocardial infarction. Psychosom Med 2000; 62: 212–19.Google Scholar
6 Parker, GB, Owen, CA, Brotchie, HL, Hyett, MP. The impact of differing anxiety disorders on outcome following an acute coronary syndrome: time to start worrying? Depress Anxiety 2010; 27: 302–9.Google Scholar
7 Parker, G, Hyett, M, Hadzi-Pavlovic, D, Brotchie, H, Walsh, W. GAD is good? Generalized anxiety disorder predicts a superior five year outcome following an acute coronary syndrome. Psychiatry Res 2011; 188: 383–9.Google Scholar
8 Meyer, T, Hussein, S, Lange, HW, Herrmann-Lingen, C. Anxiety is associated with a reduction in both mortality and major adverse cardiovascular events five years after coronary stenting. Eur J Prev Cardiol 2015; 22: 7582.Google Scholar
9 Tully, PJ, Winefield, HR, Baker, RA, Denollet, J, Pedersen, SS, Wittert, GA, et al. Depression, anxiety and major adverse cardiovascular and cerebrovascular events in patients following coronary artery bypass graft surgery: a five year longitudinal cohort study. Biopsychosoc Med 2015; 9: 14.Google Scholar
10 Laan, W, Termorshuizen, F, Smeets, HM, Boks, MP, de Wit, NJ, Geerlings, MI. A comorbid anxiety disorder does not result in an excess risk of death among patients with a depressive disorder. J Affect Disord 2011; 135: 284–91.CrossRefGoogle ScholarPubMed
11 Batelaan, NM, ten Have, M, Van Balkom, AJ, Tuithof, M, de Graaf, R. Anxiety disorders and onset of cardiovascular disease: The differential impact of panic, phobias and worry. J Anxiety Disord 2014; 28: 252–8.Google Scholar
12 Albert, CM, Chae, CU, Rexrode, KM, Manson, JE, Kawachi, I. Phobic anxiety and risk of coronary heart disease and sudden cardiac death among women. Circulation 2005; 111: 480–7.Google Scholar
13 Eifert, GH, Thompson, RN, Zvolensky, MJ, Edwards, K, Frazer, NL, Haddad, JW, et al. The Cardiac Anxiety Questionnaire: development and preliminary validity. Behav Res Ther 2000; 38: 1039–53.Google Scholar
14 Van Beek, MH, Oude Voshaar, RC, Deelen, van FM, Van Balkom, AJ, Pop, G, Speckens, AE. The Cardiac Anxiety Questionnaire: cross-validation among cardiac inpatients. Int J Psychiatry Med 2012; 43: 349–64.Google Scholar
15 Van Beek, MH, Mingels, M, Oude Voshaar, RC, Van Balkom, AJ, Lappenschaar, M, Pop, G, et al. One-year follow up of cardiac anxiety after a myocardial infarction: a latent class analysis. J Psychosom Res 2012; 73: 362–8.CrossRefGoogle ScholarPubMed
16 Kaptein, KI, de Jonge, P, van den Brink, RH, Korf, J. Course of depressive symptoms after myocardial infarction and cardiac prognosis: a latent class analysis. Psychosom Med 2006; 68: 662–8.CrossRefGoogle ScholarPubMed
17 Beck, AT, Ward, CH, Mendelson, M, Mock, J, Erbaugh, J. An inventory for measuring depression. Arch Gen Psych 1961; 4: 561–71.Google Scholar
18 Marker, CD, Carmin, CN, Ownby, RL. Cardiac anxiety in people with and without coronary atherosclerosis. Depress Anxiety 2008; 25: 824–31.Google Scholar
19 Folland, ED, Parisi, AF, Moynihan, PF, Jones, DR, Feldman, CL, Tow, DE. Assessment of left ventricular ejection fraction and volumes by real-time, two-dimensional echocardiography. A comparison of cineangiographic and radionuclide techniques. Circulation 1979; 60: 760–6.Google Scholar
20 Denollet, J, Strik, JJ, Lousberg, R, Honig, A. Recognizing increased risk of depressive comorbidity after myocardial infarction: looking for 4 symptoms of anxiety–depression. Psychother Psychosom 2006; 75: 346–52.Google Scholar
21 Meijer, A, Conradi, HJ, Bos, EH, Thombs, BD, van Melle, JP, de Jonge, P. Prognostic association of depression following myocardial infarction with mortality and cardiovascular events: a meta-analysis of 25 years of research. Gen Hosp Psychiatry 2011; 33: 203–16.Google Scholar
22 Nicholson, A, Kuper, H, Hemingway, H. Depression as an etiologic and prognostic factor in coronary heart disease: a meta-analysis of 6362 events among 146 538 participants in 54 observational studies. Eur Heart J 2006; 27: 2763–74.CrossRefGoogle Scholar
23 Strik, JHM, Honig, A, Lousberg, R, Denollet, J. Sensitivity and specificity of observer and self-report questionnaires in major and minor depression following myocardial infarction. Psychosomatics 2001; 42: 423–8.Google Scholar
24 World Health Organization. International Statistical Classification of Diseases and Related Health Problems (ICD–9). WHO, 1978.Google Scholar
25 Rubin, DB. Multiple Imputation for Nonresponse in Surveys. Wiley, 1987.Google Scholar
26 White, IR, Royston, P, Wood, AM. Multiple imputation using chained equations: issues and guidance for practice. Stat Med 2011; 30: 377–99.Google Scholar
27 Van Loo, HM, van den Heuvel, ER, Schoevers, RA, Anselmino, M, Carney, RM, Denollet, J, et al. Sex dependent risk factors for mortality after myocardial infarction: individual patient data meta-analysis. BMC Med 2014; 12: 242.Google Scholar
28 Frasure-Smith, N, Lesperance, F, Juneau, M, Talajic, M, Bourassa, MG. Gender, depression, and one-year prognosis after myocardial infarction. Psychosom Med 1999; 61: 2637.Google Scholar
29 Frasure-Smith, N, Lesperance, F. Depression and anxiety as predictors of 2-year cardiac events in patients with stable coronary artery disease. Arch Gen Psychiatry 2008; 65: 6271.Google Scholar
30 Hosmer, DW, Lemeshow, S, May, M. Applied Survival Analysis: Regression Modelling of Time-to-Event Data (2nd edn). Wiley, 2008.Google Scholar
31 Martens, EJ, de Jonge, P, Na, B, Cohen, BE, Lett, H, Whooley, MA. Scared to death? Generalized anxiety disorder and cardiovascular events in patients with stable coronary heart disease: The Heart and Soul Study. Arch Gen Psychiatry 2010; 67: 750–8.Google Scholar
32 Roest, AM, Martens, EJ, de Jonge, P, Denollet, J. Symptom dimensions of anxiety following myocardial infarction: associations with depressive symptoms and prognosis. Health Psychol 2014; 33: 1468–76.Google Scholar
33 Strik, JJ, Denollet, J, Lousberg, R, Honig, A. Comparing symptoms of depression and anxiety as predictors of cardiac events and increased health care consumption after myocardial infarction. J Am Coll Cardiol 2003; 42: 1801–7.CrossRefGoogle ScholarPubMed
34 Bonnet, F, Irving, K, Terra, JL, Nony, P, Berthezene, F, Moulin, P. Anxiety and depression are associated with unhealthy lifestyle in patients at risk of cardiovascular disease. Atherosclerosis 2005; 178: 339–44.Google Scholar
35 Kuhl, EA, Fauerbach, JA, Bush, DE, Ziegelstein, RC. Relation of anxiety and adherence to risk-reducing recommendations following myocardial infarction. Am J Cardiol 2009; 103: 1629–34.Google Scholar
36 Cameron, OG, Smith, CB, Lee, MA, Hollingsworth, PJ, Hill, EM, Curtis, GC. Adrenergic status in anxiety disorders: platelet alpha 2-adrenergic receptor binding, blood pressure, pulse, and plasma catecholamines in panic and generalized anxiety disorder patients and in normal subjects. Biol Psychiatry 1990; 28: 320.Google Scholar
37 Pitsavos, C, Panagiotakos, DB, Papageorgiou, C, Tsetsekou, E, Soldatos, C, Stefanadis, C. Anxiety in relation to inflammation and coagulation markers, among healthy adults: the ATTICA study. Atherosclerosis 2006; 185: 320–6.Google Scholar
38 Martens, EJ, Nyklícek, I, Szabó, BM, Kupper, N. Depression and anxiety as predictors of heart rate variability after myocardial infarction. Psychol Med 2008; 38: 375–83.Google Scholar
39 Habiboviæ, M, Pedersen, SS, van den Broek, KC, Theuns, DA, Jordaens, L, van der Voort, PH, et al. Anxiety and risk of ventricular arrhythmias or mortality in patients with an implantable cardioverter defibrillator. Psychosom Med 2013; 75: 3641.Google Scholar
40 van Beek, MH, Oude Voshaar, RC, van Deelen, FM, van Balkom, AJ, Pop, G, Speckens, AE. Inverse correlation between cardiac injury and cardiac anxiety: a potential role for communication. J Cardiovasc Nurs 2014; 29: 448–53.Google Scholar
41 Janszky, I, Ahnve, S, Lundberg, I, Hemmingsson, T. Early-onset depression, anxiety, and risk of subsequent coronary heart disease: 37-year follow-up of 49,321 young Swedish men. J Am Coll Cardiol 2010; 56: 31–7.Google Scholar
42 Gulliksson, M, Burell, G, Vessby, B, Lundin, L, Toss, H, Svärdsudd, K. Randomized controlled trial of cognitive behavioral therapy vs standard treatment to prevent recurrent cardiovascular events in patients with coronary heart disease: Secondary Prevention in Uppsala Primary Health Care project (SUPRIM). Arch Intern Med 2011; 171: 134–40.Google Scholar
Figure 0

Table 1 Baseline characteristics of 193 patients with myocardial infarction according to incidence of a major adverse cardiac event (MACE) (yes/no)a

Figure 1

Table 2 Hazard ratios (95% CI) for a major adverse cardiac event (MACE) associated with scores on the Cardiac Anxiety Questionnaire (CAQ) during admission to hospital and at 4 months after dischargea

Figure 2

Table 3 Hazard ratio's (95% CI) for a major adverse cardiac event (MACE) associated with scores on the four Cardiac Anxiety Questionnaire (CAQ) subscales during hospital admission and at 4 months post-myocardial infarction

Supplementary material: PDF

Van Beek et al. supplementary material

Supplementary Table S1-S3

Download Van Beek et al. supplementary material(PDF)
PDF 523 KB
Submit a response

eLetters

No eLetters have been published for this article.