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Post-traumatic stress disorder as a risk factor for major adverse cardiovascular events: a cohort study of a South African medical insurance scheme

Published online by Cambridge University Press:  05 February 2024

Cristina Mesa-Vieira
Affiliation:
Institute of Social and Preventive Medicine, University of Bern, Bern, Switzerland Graduate School for Health Sciences, University of Bern, Bern, Switzerland
Christiane Didden
Affiliation:
Institute of Social and Preventive Medicine, University of Bern, Bern, Switzerland Department of Sociology, Ludwig-Maximilians-Universität Munich, Munich, Germany
Michael Schomaker
Affiliation:
Department of Statistics, Ludwig-Maximilians-Universität Munich, Munich, Germany Centre for Infectious Disease Epidemiology & Research, School of Public Health, University of Cape Town, Cape Town, South Africa
Johannes P. Mouton
Affiliation:
Division of Clinical Pharmacology, Department of Medicine, University of Cape Town, Cape Town, South Africa
Naomi Folb
Affiliation:
Medscheme, Cape Town, South Africa
Leigh L. van den Heuvel
Affiliation:
Department of Psychiatry, Faculty of Medicine and Health Sciences, Stellenbosch University, Cape Town, South Africa South African Medical Research Council/Stellenbosch University Genomics of Brain Disorders Research Unit, Stellenbosch University, Cape Town, South Africa
Chiara Gastaldon
Affiliation:
Institute of Social and Preventive Medicine, University of Bern, Bern, Switzerland
Morna Cornell
Affiliation:
Centre for Infectious Disease Epidemiology & Research, School of Public Health, University of Cape Town, Cape Town, South Africa
Mpho Tlali
Affiliation:
Centre for Infectious Disease Epidemiology & Research, School of Public Health, University of Cape Town, Cape Town, South Africa
Reshma Kassanjee
Affiliation:
Centre for Infectious Disease Epidemiology & Research, School of Public Health, University of Cape Town, Cape Town, South Africa
Oscar H. Franco
Affiliation:
Institute of Social and Preventive Medicine, University of Bern, Bern, Switzerland Department of Global Public Health & Bioethics, University Medical Center Utrecht, Utrecht, Netherlands
Soraya Seedat
Affiliation:
Department of Psychiatry, Faculty of Medicine and Health Sciences, Stellenbosch University, Cape Town, South Africa South African Medical Research Council/Stellenbosch University Genomics of Brain Disorders Research Unit, Stellenbosch University, Cape Town, South Africa
Andreas D. Haas*
Affiliation:
Institute of Social and Preventive Medicine, University of Bern, Bern, Switzerland
*
Corresponding author: Andreas Haas; Email: [email protected]
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Abstract

Aims

Prior research, largely focused on US male veterans, indicates an increased risk of cardiovascular disease among individuals with post-traumatic stress disorder (PTSD). Data from other settings and populations are scarce. The objective of this study is to examine PTSD as a risk factor for incident major adverse cardiovascular events (MACEs) in South Africa.

Methods

We analysed reimbursement claims (2011–2020) of a cohort of South African medical insurance scheme beneficiaries aged 18 years or older. We calculated adjusted hazard ratios (aHRs) for associations between PTSD and MACEs using Cox proportional hazard models and calculated the effect of PTSD on MACEs using longitudinal targeted maximum likelihood estimation.

Results

We followed 1,009,113 beneficiaries over a median of 3.0 years (IQR 1.1–6.0). During follow-up, 12,662 (1.3%) persons were diagnosed with PTSD and 39,255 (3.9%) had a MACE. After adjustment for sex, HIV status, age, population group, substance use disorders, psychotic disorders, major depressive disorder, sleep disorders and the use of antipsychotic medication, PTSD was associated with a 16% increase in the risk of MACEs (aHR 1.16, 95% confidence interval (CI) 1.05–1.28). The risk ratio for the effect of PTSD on MACEs decreased from 1.59 (95% CI 1.49–1.68) after 1 year of follow-up to 1.14 (95% CI 1.11–1.16) after 8 years of follow-up.

Conclusion

Our study provides empirical support for an increased risk of MACEs in males and females with PTSD from a general population sample in South Africa. These findings highlight the importance of monitoring cardiovascular risk among individuals diagnosed with PTSD.

Type
Original Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press.

Introduction

Post-traumatic stress disorder (PTSD) is a persistent and impairing mental disorder that emerges following a traumatic event (O’Donnell et al., Reference O’Donnell, Schwartz Longacre, Cohen, Fayad, Gillespie, Liberzon, Pathak, Polimanti, Risbrough, Ursano, Vander Heide, Yancy, Vaccarino, Sopko and Stein2021). The global lifetime prevalence of PTSD among the general population is estimated at 3.9%, with variations across different countries (Kessler et al., Reference Kessler, Aguilar-Gaxiola, Alonso, Benjet, Bromet, Cardoso, Degenhardt, de Girolamo, Dinolova, Ferry, Florescu, Gureje, Haro, Huang, Karam, Kawakami, Lee, Lepine, Levinson, Navarro-Mateu, Pennell, Piazza, Posada-Villa, Scott, Stein, Ten Have, Torres, Viana, Petukhova, Sampson, Zaslavsky and Koenen2017). In South Africa, the lifetime prevalence is estimated at 2.3% (Herman et al., Reference Herman, Stein, Seedat, Heeringa, Moomal and Williams2009).

The current scientific literature suggests a higher incidence of cardiovascular disease (CVD) among persons diagnosed with PTSD (Edmondson et al. Reference Edmondson, Kronish, Shaffer, Falzon and Burg2013; Edmondson and von Kanel, Reference Edmondson and von Känel2017; Jacquet-Smailovic et al., Reference Jacquet-Smailovic, Brennsthul, Denis, Kirche, Tarquinio and Tarquinio2022). In a meta-analysis by Edmondson et al., (Reference Edmondson, Kronish, Shaffer, Falzon and Burg2013), PTSD was associated with coronary heart disease. In individuals with PTSD, the pooled risk increased by 55% (95% confidence interval (CI) 34%–79%) when adjusting for sociodemographic and cardiovascular factors and by 27% (95% CI 8%–49%) after further adjustment for depression. Similarly, Jacquet-Smailovic et al., (Reference Jacquet-Smailovic, Brennsthul, Denis, Kirche, Tarquinio and Tarquinio2022) conducted a systematic review and meta-analysis of 14 studies to estimate the association between PTSD and the risk of subsequent myocardial infarction. Before adjusting for depression, the pooled risk increased by 49% (95% CI 31%–69%), while after adjustment, it decreased to 32% (95% CI 12%–56%).

A key limitation of prior research on the relationship between PTSD and CVD is its primary focus on males from the United States. Much of the research has focused on male veterans from the US and World Trade Center survivors, with only a few studies looking at females in the US or other high-income countries (Edmondson et al., Reference Edmondson, Kronish, Shaffer, Falzon and Burg2013; Edmondson and von Kanel, Reference Edmondson and von Känel2017; Jacquet-Smailovic et al., Reference Jacquet-Smailovic, Brennsthul, Denis, Kirche, Tarquinio and Tarquinio2022). This focus leaves a considerable knowledge gap concerning females and populations from low- and middle-income settings, who are exposed to a range of traumas that extend beyond war-related experiences. According to a nationally representative household survey conducted between January 2002 and June 2004, the most common traumatic event in South Africa is the unexpected death of a loved one, affecting 39.2% of the population, followed by physical violence at 37.6%, accidents at 31.9% and witnessing traumatic events at 29.5%. Among specific types of events, being mugged or threatened with a weapon is relatively common, with a prevalence of 18.3%. Life-threatening illnesses also affect 13.2% of the population. Sexual violence affects 7.6% of the population, with specific events such as rape and sexual assault affecting 2.1% and 1.6%, respectively (Atwoli et al., Reference Atwoli, Stein, Williams, McLaughlin, Petukhova, Kessler and Koenen2013). However, it is important to consider that these estimates from the household survey might not reflect the full extent of the issue, given that sexual violence might be under-reported in such surveys. The Global Database on Violence Against Women reports that lifetime physical and/or sexual intimate partner violence in South Africa is at 21.3% (NDoH et al., 2019), indicating that the actual prevalence of sexual violence could be considerably higher than what is suggested by the survey data.

Another potential issue with previous studies may be the inappropriate adjustment for psychiatric comorbidities. Psychiatric comorbidities which include substance use disorders (Akasaki and Ohishi, Reference Akasaki and Ohishi2020), major depressive disorder, psychotic disorders (Lambert et al., Reference Lambert, Parretti, Pearce, Price, Riley, Ryan, Tyldesley-Marshall, Avşar, Matthewman, Lee, Ahmed, Odland, Correll, Solmi and Marshall2022) and sleep disorders (McCall et al., Reference McCall, Turkheimer, Tsang, Avery, Duncan and Watson2019; Nambiema et al., Reference Nambiema, Lisan, Vaucher, Perier, Boutouyrie, Danchin, Thomas, Guibout, Solelhac, Heinzer, Jouven, Maruqes-Vidal and Empana2023) can be risk factors for both CVD and PTSD (Sareen, Reference Sareen2014). For this reason, it is necessary to adjust for these confounding factors (Hernán and Robins, Reference Hernán and Robins2020). However, psychiatric comorbidities can also act as mediators in the relationship between PTSD and CVD and lie on the causal pathway between exposure and outcome (Breslau et al., Reference Breslau, Davis, Peterson and Schultz1997; Radell et al., Reference Radell, Hamza and Moustafa2020). In such a situation, adjustment for psychiatric comorbidity using traditional survival models can lead to biased estimates (Mansournia et al., Reference Mansournia, Etminan, Danaei, Kaufman and Collins2017; Schisterman et al., Reference Schisterman, Cole and Platt2009).

In our study, we aim to quantify the increase in the risk of incident major adverse cardiovascular events (MACEs) in South African males and females diagnosed with PTSD, applying both traditional survival analysis and modern causal inference methods. South Africa, as a middle-income country with a high prevalence of diverse trauma exposures, provides a unique study setting that broadens our understanding of the PTSD-MACE relationship beyond the predominantly male, US-centric populations typically studied. Addressing the methodological limitations of previous research, we used longitudinal targeted maximum likelihood estimation. This modern causal inference approach can handle time-varying confounding affected by prior exposure without blocking the causal path from exposure to outcome (Petersen et al., Reference Petersen, Schwab, Gruber, Blaser, Schomaker and van der Laan2014), thereby allowing for sound adjustment for psychiatric comorbidities and potentially mitigating overcontrol bias inherent in previous studies using conventional survival models.

Methods

Study design

In this longitudinal study, we followed a cohort of beneficiaries from a large South African private medical insurance scheme. We analysed outpatient, laboratory, hospital and drug claims from the medical insurance scheme and linked these with beneficiary vital status information from the National Population Register.

Study population

We included beneficiaries aged 18 years or older, who had health insurance coverage at any point, between 1 January 2011 and 15 March 2020, the beginning of the COVID-19 pandemic in South Africa. We excluded beneficiaries with unknown sex, or age, MACE on the first day of follow-up, and those whose vital status could not be ascertained because they did not have civil identification numbers and could not be linked to the National Population Register.

Measures

We defined the study measures based on the International Classification of Diseases, 10th Revision (ICD-10) diagnoses from outpatient and hospital claims, hospital procedure codes and medication claims. Hospital procedures were coded according to the Current Procedural Terminology (CPT) and medication claims according to the Anatomical Therapeutic Chemical (ATC) classification system.

The primary outcome was a three-point MACE (Bosco et al., Reference Bosco, Hsueh, McConeghy, Gravenstein and Saade2021), which included ICD-10 diagnoses of either myocardial infarction (I21–I22), stroke (I60–I61, I63–I64 and H34.1) or hospitalization for unstable angina (I20) or hospital procedure codes for revascularization (CPT 33,503–33,572 and 92,920–92,984). The complete list of ICD-10 and CPT codes is shown in the appendix (Tables S1 and S2). In sensitivity analysis, we considered a two-point MACE (MACE2) consisting of myocardial infarction or stroke and a four-point MACE (MACE4) consisting of myocardial infarction, stroke, hospitalization for unstable angina or revascularization and heart failure (Table S1) as outcomes. We also considered individual MACE components such as stroke (ischaemic, bleeding or unspecified) and acute coronary syndrome (myocardial infarction or hospitalization due to unstable angina and revascularization procedures) in sensitivity analyses. A single claim code was considered evidence of the outcome.

The primary exposure was at least one ICD-10 diagnosis of PTSD (F43.1). We considered the following psychiatric comorbidities that can increase the risk of both PTSD (Brewin et al., Reference Brewin, Andrews and Valentine2000; Ozer et al., Reference Ozer, Best, Lipsey and Weiss2003; Sareen, Reference Sareen2014) and CVD (Akasaki and Ohishi, Reference Akasaki and Ohishi2020; Lambert et al., Reference Lambert, Parretti, Pearce, Price, Riley, Ryan, Tyldesley-Marshall, Avşar, Matthewman, Lee, Ahmed, Odland, Correll, Solmi and Marshall2022; Nambiema et al., Reference Nambiema, Lisan, Vaucher, Perier, Boutouyrie, Danchin, Thomas, Guibout, Solelhac, Heinzer, Jouven, Maruqes-Vidal and Empana2023; Shao et al., Reference Shao, Lin, Jiang, Tian, Xu, Wang, Ji, Zhou, Song and Zhuo2020): substance use disorders (F10–F16 and F18–F19), major depressive disorder (F32–F33), psychotic disorders (F20–F29) and sleep disorders (F51 and G47). Additionally, we considered antipsychotic medication as a risk factor for CVD (De Hert et al., Reference De Hert, Detraux and Vancampfort2018). Antipsychotic medication was defined based on ATC codes for psychotic medication (N05A).

We considered the following CVD risk factors: hypertension, diabetes mellitus, dyslipidaemia and HIV. Hypertension was defined based on ICD-10 codes for hypertensive disease (I10-I13, I15, H35.0 and I67.4), evidence of use of medication used to treat hypertension (i.e. certain diuretics, beta-blockers or drug combinations) or at least two elevated systolic (≥140 mmHg) or diastolic (≥90 mmHg) blood pressure measurements (Appendix, Table S3). Diabetes mellitus was defined using the ICD-10 codes for diabetes (E10–E14, H28, H36, M14.2, M14.6, G59.0, G63.2 or G99.0), evidence of use of medications used for diabetes control (ATC codes A10) or at least two abnormal laboratory results of HbA1c ≥6.5% (≥48 mmol/L), fasting blood glucose ≥7 mmol/L or random blood glucose ≥11.1 mmol/L (American Diabetes, 2021) (Appendix, Table S4). Dyslipidaemia was identified with the ICD-10 codes E78.0–E78.5, evidence of the use of lipid-modifying medication (ATC codes C10) or at least two abnormal lipid measurements (High-Density Lipoprotein [HDL] cholesterol <1 mmol/L, Low-Density Lipoprotein [LDL] cholesterol >4.1 mmol/L or total cholesterol >6.2 mmol/L) (Arnett et al., Reference Arnett, Blumenthal, Albert, Buroker, Goldberger, Hahn, Himmelfarb, Khera, Lloyd-Jones, McEvoy, Michos, Miedema, Munoz, Smith, Virani, Williams, Yeboah and Ziaeian2019) (Appendix, Table S5). We considered persons to be HIV positive if they had received an HIV viral load, CD4 cell count or a positive confirmatory HIV test, an ICD-10 diagnosis for HIV (B20–B24, Z21, R75 and O98.7) or antiretroviral medication for treating HIV, excluding medication commonly used in pre- or post-exposure prophylaxis (Appendix, Table S6). Self-identified ethnic population groups were defined as Black African, Indian/Asian, mixed ancestry, white or unknown. We included beneficiaries’ age as a continuous variable. Psychiatric and physical health conditions were modelled as time-varying covariates. Individuals were considered exposed from the date of the first diagnosis of the respective condition.

Statistical analysis

In survival analyses, we followed beneficiaries from the start of insurance coverage, their 18th birthday or 1 January 2011 (whichever occurred last) until the event of interest (e.g., the MACE), or censoring events such as death or end of insurance coverage (whichever occurred first), for a maximum of 8 years.

We estimated the cumulative incidence of PTSD and 95% CIs by sex considering death as a competing event (Gooley et al., Reference Gooley, Leisenring, Crowley and Storer1999). Next, we calculated adjusted hazard ratios (aHRs) for hypothesized predictors of PTSD using a Cox proportional hazards model, stratified by population group and adjusted for age group, sex and HIV status.

To assess the association between PTSD and MACE and evaluate the influence of potential confounders and mediators, we fitted three adjusted Cox proportional hazards models: model 1 adjusted for HIV and sociodemographic characteristics (age, sex and population group); model 2 adjusted for HIV, sociodemographic characteristics and psychiatric comorbidity (substance use disorders, psychotic, major depressive disorder and sleep disorders); model 3 adjusted for HIV, sociodemographic characteristics, psychiatric comorbidity and CVD risk factors (diabetes mellitus, dyslipidaemia and hypertension). We fitted Cox models for both sexes, separate models for male and female beneficiaries and tested for interactions between sex and PTSD. In sensitivity analysis, we fitted model 2 with alternative MACE definitions (MACE2 and MACE4) and MACE components separately (stroke and acute coronary syndrome). We did not consider secondary MACE (repeated events). Beneficiaries exited the study at their first MACE. This analytic approach ensures that the PTSD diagnoses occurred before the MACE. We fitted Cox models to examine the association between PTSD and CVD risk factors. We checked the proportional hazard assumption using log–log plots and estimating Schoenfeld residuals after fitting the Cox models. We stratified Cox models by variables not satisfying the proportional hazards assumption.

We used modern doubly robust causal inference methods, specifically longitudinal targeted maximum likelihood estimation (Lendle et al., Reference Lendle, Schwab, Petersen and van der Laan2017; Schomaker et al., Reference Schomaker, Luque-Fernandez, Leroy and Davies2019), to estimate the marginal risks of MACE over 8 years of follow-up from the start of insurance coverage, beneficiaries’ 18th birthday, or 1 January 2011, whichever occurred last. We modelled two scenarios: continuous PTSD presence throughout follow-up for all beneficiaries and the counterfactual, no PTSD presence for any beneficiary. We divided beneficiaries’ follow-up into 16 six-monthly intervals and assessed confounders, mediators and the outcome at the end of each interval. We adjusted for measured time-varying confounding by HIV (Tang et al., Reference Tang, Goldsamt, Meng, Xiao, Zhang, Williams and Wang2020), CVD risk factors, and psychiatric comorbidity and antipsychotic medication. Results are presented as absolute risks, risk differences and risk ratios with 95% CIs. To avoid model misspecification in longitudinal targeted maximum likelihood estimation, we fitted models for the conditional expectation of both MACE and PTSD in each 6-month follow-up period using super learning. This data-adaptive approach combines different modelling approaches to minimize the expected prediction error (estimated via cross-validation). Our learner sets included logistic (additive) regression models (with penalized splines and optional interactions), Bayesian logistic regression models and multivariate adaptive regression splines, after prior variable screening with Least Absolute Shrinkage and Selection Operator (LASSO) (Tibshirani, Reference Tibshirani1996) and Cramer’s V (Heumann and Shalabh, Reference Heumann and Shalabh2016). Due to computational constraints, we split the total sample randomly into two 50% subsets, executed longitudinal targeted maximum likelihood estimation on each and combined the results.

Statistical analyses were performed using Stata (Version 16. College Station, TX: StataCorp) and R 4.1.2 (R Foundation for Statistical Computing, Vienna, Austria). Causal inference analysis was performed on UBELIX (http://www.id.unibe.ch/hpc), the high-performance computing cluster at the University of Bern.

Ethical considerations

The Ethics Committee of the University of Cape Town in South Africa and the Cantonal Ethics Committee in Bern, Switzerland, granted permission for the analysis of this database.

Results

Study population

The database included 1,537,056 beneficiaries who had insurance coverage at any point between 1 January 2011 and 15 March 2020. We excluded 527,943 (34.3%) beneficiaries, including 438,759 (28.5%) children and adolescents under the age of 18, 70,062 (4.6%) persons who could not be linked to the National Population Register, 9,928 (0.6%) persons with unknown sex, 9,108 (0.6%) persons with unknown age and 86 who had an MACE on the first day of follow-up (Figure S1).

Characteristics of the study population

We followed 1,009,113 beneficiaries over a median duration of 3 years (IQR 1.1–6.0). During follow-up, 12,662 (1.3%) beneficiaries were diagnosed with PTSD and 39,255 (3.9%) had an MACE (Table 1). Half of the study population (51.8%) were female, and the mean age was 39.3 years (SD 15.2). Hypertension was the most frequent CVD risk factor (29.0%) followed by dyslipidaemia (15.7%) and diabetes (12.4%). Of the study population, 8.2% had a positive HIV status. Major depressive disorder (13.9%) was the most frequently diagnosed mental health condition (Table 1).

Table 1. Characteristics of beneficiaries with and without PTSD diagnosis at the end of follow-up

Abbreviations: PTSD, post-traumatic stress disorder; SD, standard deviation; CVD, cardiovascular disease; HIV, human immunodeficiency virus; MACE, major adverse cardiovascular event; IQR, interquartile range.

a MACE: myocardial infarction, stroke or hospitalization for unstable angina/revascularization.

The cumulative incidence of PTSD and associated factors

Figure 1 shows the cumulative incidence of PTSD by sex. After 8 years of follow-up, the cumulative incidence was 3.2% (95% CI 3.1–3.2) among females and 2.1% (95% CI 2.0–2.1) among males. Females (aHR 1.55, 95% CI 1.50–1.61), beneficiaries aged 35–44 years (aHR 1.13, 95% CI 1.07–1.18) and people living with HIV (aHR 1.34, 95% CI 1.27–1.42) had a higher risk of PTSD (Appendix, Table S7).

Abbreviations: PTSD, post-traumatic stress disorder; CI, confidence interval.

Figure 1. Cumulative incidence of PTSD by sex.

Association between PTSD and MACE

After adjustment for sex, HIV status, age and population group (model 1), PTSD was associated with an increased risk of MACE (aHR 1.46, 95% CI 1.33–1.62). In a model adjusted for sex, HIV status, age, population group, psychiatric comorbidities and antipsychotic medication (model 2), the increase in risk was attenuated (aHR 1.16, 95% CI 1.05–1.28). Additional adjustment for CVD risk factors (model 3) did not affect the association between PTSD and MACE (aHR 1.16, 95% CI 1.05–1.28) (Fig. 2, Appendix, Table S8). Results were similar in sensitivity analyses of associations between PTSD and MACE2 (model 2: aHR 1.17, 95% CI 1.04–1.32) and MACE4 (model 2: aHR 1.14, 95% CI 1.05–1.24) (Appendix, Table S8). Associations between PTSD and MACE were similar among male and female beneficiaries (Appendix, Figure S2), and the test for an interaction between PTSD and sex was not significant in model 1 (P = 0.317) and model 2 (P = 0.244). PTSD was associated with an increased risk of incident stroke (aHR 1.18, 95% CI 1.03–1.35) and acute coronary syndrome (aHR 1.22, 95% CI 1.06–1.39) in models adjusted for sex, HIV status, age, population group, and psychiatric comorbidities and use of antipsychotic medication (model 2) (Figure S3).

Abbreviations: PTSD, post-traumatic stress disorder; HIV, human immunodeficiency virus; CI, confidence interval. 1We considered the following major adverse cardiovascular events: myocardial infarction, stroke or hospitalization for unstable angina/revascularization. Model 1 was adjusted for PTSD, sex, HIV, age and population group. Model 2 was adjusted for PTSD, sex, HIV, age, population group, substance use disorder, psychotic disorders, major depressive disorder, use of antipsychotic medication and sleep disorder. Model 3 was adjusted for PTSD, sex HIV, age, population group, substance use disorder, psychotic disorder, major depressive disorder, use of antipsychotic medication, sleep disorder, diabetes, dyslipidaemia and hypertension.

Figure 2. Factors associated with major adverse cardiovascular events1.

Association between PTSD and CVD risk factors

PTSD diagnosis was associated with an increased incidence of hypertension (aHR 1.23, 95% CI 1.17–1.29), diabetes mellitus (aHR 1.12, 95% 1.05–1.20) and dyslipidaemia (1.32, 95% 1.25–1.40) after adjusting for age, sex, population group and psychiatric comorbidities.

Risk of MACE under PTSD and no PTSD

Using longitudinal targeted maximum likelihood estimation, we calculated an absolute risk of MACE after 8 years of follow-up of 7.2% under no PTSD and 8.2% under PTSD (Fig. 3, panel A). After year 3, the risk difference between PTSD and no PTSD increased from 0.3% (95% CI 0.2–0.4) to 1.0% (95% CI 0.8–1.2) in year 8 (Fig. 3, panel B). Risk ratios decreased from 1.59 (95% CI 1.49–1.68) in year 1 to 1.14 (95% CI 1.11–1.16) in year 8 (Fig. 3, panel C).

Abbreviations: PTSD, post-traumatic stress disorder; MACEs, major adverse cardiovascular events.

Figure 3. Major adverse cardiovascular events under PTSD and no PTSD.

Discussion

In this cohort study of over one million South African medical insurance beneficiaries, we demonstrated an increased risk of MACE among individuals diagnosed with PTSD compared to those without it, using both traditional survival analysis and modern causal inference methods. In survival analysis, adjusted for sociodemographic factors, HIV and psychiatric comorbidities, beneficiaries with a PTSD diagnosis experienced a 16% increase in MACE risk compared to beneficiaries without PTSD. The causal inference analysis showed a 14% increase in MACE risk for the PTSD scenario compared to the non-PTSD scenario after the eighth year of follow-up.

There are two potential causal mechanisms that might explain the increased risk of CVD in individuals with PTSD. The first mechanism is psychological and behavioural, with PTSD increasing the risk of depression, substance misuse and sleep disorders and these factors leading to unhealthy lifestyle choices such as reduced physical activity and poor dietary habits. These behaviours can subsequently contribute to the development of CVD risk factors including hypertension, diabetes and high cholesterol, which may ultimately result in CVD (Edmondson and von Kanel, Reference Edmondson and von Känel2017; Scherrer et al., Reference Scherrer, Salas, Cohen, Schnurr, Schneider, Chard, Tuerk, Friedman, Norman, van den Berk-clark and Lustman2019). The second mechanism is pathophysiological, as PTSD can impact various physiological processes that may directly cause cardiovascular events, such as myocardial infarction, unstable angina or stroke. These processes include systemic inflammation, dysregulation of the hypothalamic–pituitary–adrenal axis and imbalances in the autonomic nervous system (Edmondson and von Kanel, Reference Edmondson and von Känel2017). In our study, we evaluated the potential contribution of CVD risk factors, specifically hypertension, diabetes and dyslipidaemia. Using Cox models adjusted for sex, HIV status, age, population group and psychiatric comorbidities, we found a 16% increased risk of MACE in individuals diagnosed with PTSD. After further adjustments for CVD risk factors, this association remained unchanged. This finding suggests that in our study population the elevated MACE risk in individuals with PTSD occurs independent of traditional CVD risk factors. Physiological changes induced by PTSD might play a significant role in driving the increased risk of MACE observed in our study.

With the exception of few studies from Sweden (Song et al., Reference Song, Fang, Arnberg, Mataix-Cols, Fernández de la Cruz, Almqvist, Fall, Lichtenstein, Thorgeirsson and Valdimarsdóttir2019), Denmark (Gradus et al., Reference Gradus, Farkas, Svensson, Ehrenstein, Lash, Milstein, Adler and Sørensen2015) and Taiwan (Chen et al., Reference Chen, Pan, Li, Lin, Chen, Lee, Tsai, Hsu, Huang, Tsai, Chang, Chen, Su and Bai2015), most previous research in this field was conducted has been among males from the US and has primarily focused on war- and terror-related trauma among veterans and World Trade Centre survivors. In contrast, our study extends this knowledge by using a general population sample likely exposed to a variety of traumatic experiences, which are prevalent in the context of South Africa. Common traumas in South Africa are physical or sexual violence, the death of a loved one, witnessing traumatic incidents and accidents (Atwoli et al., 2013). Our findings not only reinforce and complement the prevailing evidence but also extend our understanding the implications of PTSD in diverse, trauma-exposed, and middle-income settings. The consistency of our findings with prior research strengthens the credibility of the elevated CVD risk in individuals with PTSD and underscores their wide applicability across diverse countries, populations and trauma exposures.

The relationship between PTSD and psychiatric comorbidities is complex and bi-directional. Psychiatric comorbidities like depression, substance use disorders, sleep disturbance and generalized anxiety disorder can act as important confounders in the relationship between PTSD and CVD, making adjustments for their effects crucial. On the other hand, psychiatric comorbidities can also mediate the relationship between PTSD and CVD (Scherrer et al., Reference Scherrer, Salas, Cohen, Schnurr, Schneider, Chard, Tuerk, Friedman, Norman, van den Berk-clark and Lustman2019). In this situation, using traditional survival models to adjust for psychiatric comorbidities can lead to overadjustment bias (Mansournia et al., Reference Mansournia, Etminan, Danaei, Kaufman and Collins2017; Schisterman et al., Reference Schisterman, Cole and Platt2009). Despite this potential bias, much of the previous research has adjusted for psychiatric comorbidity using traditional survival models. For instance, a recent meta-analysis of 14 studies investigating the relationship between PTSD and myocardial infarction included nine studies that adjusted for depression (Jacquet-Smailovic et al., Reference Jacquet-Smailovic, Brennsthul, Denis, Kirche, Tarquinio and Tarquinio2022). To overcome this issue, we implemented modern causal inference methods, which can adjust for time-varying confounding affected by prior exposure without blocking the causal pathway from exposure to outcome (Petersen et al., Reference Petersen, Schwab, Gruber, Blaser, Schomaker and van der Laan2014). With these methods, we could appropriately adjust for important potential confounders like depression, substance use disorders, psychotic disorders and sleep disturbance. We could, however, not adjust for other anxiety disorders. The common symptoms between PTSD and other anxiety disorders complicate differential diagnosis. In our data, many patients initially diagnosed with an unspecific or another anxiety disorder were later accurately diagnosed with PTSD. Consequently, adjusting for other anxiety disorders would lead to overadjustment. From a clinical standpoint, it may also be questionable whether adjusting for psychiatric comorbidities, like depression and other anxiety disorders, to estimate an independent effect of PTSD on cardiovascular outcomes is justified. Psychiatric comorbidity is the rule, rather than the exception in PTSD, with epidemiologic studies demonstrating comorbidity in over 75% of patients with PTSD, with depression the most frequent comorbid disorder (Brady et al., Reference Brady, Kileen, Brewerton and Lucerini2000; Kessler, Reference Kessler, Aguilar-Gaxiola, Alonso, Benjet, Bromet, Cardoso, Degenhardt, de Girolamo, Dinolova, Ferry, Florescu, Gureje, Haro, Huang, Karam, Kawakami, Lee, Lepine, Levinson, Navarro-Mateu, Pennell, Piazza, Posada-Villa, Scott, Stein, Ten Have, Torres, Viana, Petukhova, Sampson, Zaslavsky and Koenen2017). Psychiatric comorbidity is also associated with chronicity, greater functional impairment and worse outcomes, including poorer response to treatment (Brady et al., Reference Brady, Kileen, Brewerton and Lucerini2000, Flory and Yehuda, Reference Flory and Yehuda2015). There is also evidence to suggest that individuals with comorbid depression may represent a subtype of PTSD, with shared negative affectivity (Contractor et al., Reference Contractor, Weiss, Dolan and Mota2020; Flory and Yehuda, Reference Flory and Yehuda2015). Since PTSD, depression and other anxiety disorders share common symptoms (Angelakis and Nixon, Reference Angelakis and Nixon2015; Flory and Yehuda, Reference Flory and Yehuda2015) and comorbidity may reflect severity of PTSD, such adjustment could potentially be seen as overadjusting for PTSD severity. Given that we used ICD10 diagnoses from administrative data, this issue might be further complicated by potential misdiagnoses of PTSD as depression due to symptom overlap.

This study has important implications for clinical practice. Despite the growing evidence of the impact of mental disorders on physical comorbidity and premature mortality (Ruffieux et al., Reference Ruffieux, Wettstein, Maartens, Folb, Mesa-Vieira, Didden, Tlali, Williams, Cornell, Schomaker, Johnson, Joska, Egger and Haas2023), mental healthcare in many settings remains underfunded and segmented into silos of mental and physical healthcare (O’Connor et al., Reference O’Connor, Worthman, Abanga, Athanassopoulou, Boyce, Chan, Christensen, Das-Munshi, Downs, Koenen, Moutier, Templeton, Batterham, Brakspear, Frank, Gilbody, Gureje, Henderson, John, Kabagambe, Khan, Kessler, Kirtley, Kline, Kohrt, Lincoln, Lund, Mendenhall, Miranda, Mondelli, Niederkrotenthaler, Osborn, Pirkis, Pisani, Prawira, Rachidi, Seedat, Siskind, Vijayakumar and Yip2023). To address the physical healthcare needs of individuals with mental illnesses, the World Health Organization, along with international experts, advocates for integrated care models that combine mental health services with physical healthcare (O’Connor et al., 2023). It is crucial for health professionals to be informed about the potential cardiovascular implications of PTSD to ensure comprehensive care including management of CVD risk factors.

Key strengths of our study include our distinctive study population and our analytic approach. Our sample is drawn from a population exposed to a wide spectrum of traumatic experiences and females. Our second major strength is the use of modern causal inference methods, which enabled us to overcome methodological limitations of previous research. The use of modern causal inference methods has several benefits over traditional survival analysis methods. First, the causal inference methods allow to adjust for time-dependent confounding by psychiatric comorbidity and CVD risk factors without blocking the causal path from PTSD to MACE (Hernán and Robins, Reference Hernán and Robins2020). Second, our chosen estimands (i.e. causal risks) prevent potential survivor bias inherent in traditional survival analysis due to conditioning on being event-free under PTSD/no PTSD at each time point in the definition of the hazard (Young et al., Reference Young, Stensrud, Tchetgen Tchetgen and Hernán2020). Third, longitudinal targeted maximum likelihood estimation is a doubly robust method that incorporates machine learning procedures to reduce the risk of bias due to model misspecification (Van der Laan and Rose, Reference Van der Laan and Rose2011).

Our results should be interpreted considering the following limitations. First, our study’s results, focused on South African private medical insurance beneficiaries, are not representative of the general population of South Africa since only 15% of the populace has such coverage (Day and Gray, Reference Day and Gray2013). This insured group generally has a higher socioeconomic status (Gordon et al., Reference Gordon, Booysen and Mbonigaba2020) and likely lower exposure to trauma and poor health outcomes than those using the public health system. Second, we used medical insurance scheme data to determine the presence of MACE, PTSD and physical and psychiatric comorbidities. Administrative data limitations may include inaccuracy and misclassification. We based PTSD and psychiatric comorbidity presence on ICD-10 diagnoses from outpatient and hospital claims, possibly overlooking undiagnosed cases or those not seeking care. Our MACE definition depended on ICD-10 diagnoses and procedure codes, potentially missing cases who died before medical attention. Third, our dataset lacked information on socioeconomic factors, other CVD risk factors or behaviours, or pre-insurance medical history, which could confound results. Moreover, the lack of pre-insurance medical history could be an explanation for the relatively high risk ratio of the absolute risks in year 1. Factors like employment, education and neighbourhood characteristics impact CVD (Schultz et al., Reference Schultz, Kelli, Lisko, Varghese, Shen, Sandesara, Quyyumi, Taylor, Gulati, Harold, Mieres, Ferdinand, Mensah and Sperling2018), PTSD vulnerability (DiGangi et al., Reference DiGangi, Gomez, Mendoza, Jason, Keys and Koenen2013) and control of CVD risk factors (Rosengren et al., Reference Rosengren, Smyth, Rangarajan, Ramasundarahettige, Bangdiwala, AlHabib, Avezum, Bengtsson Bostrom, Chifamba, Gulec, Gupta, Igumbor, Iqbal, Ismail, Joseph, Kaur, Khatib, Kruger, Lamelas, Lanas, Lear, Li, Wang, Quiang, Wang, Lopez-Jaramillo, Mohammadifard, Mohan, Mony, Poirier, Srilatha, Szuba, Teo, Wielgosz, Yeates, Yusoff, Yusuf, Yusufali, Attaei, McKee and Yusuf2019). Our study group, being private insurance members, was relatively homogeneous with regard to socioeconomic status. Still, residual confounding from socioeconomic differences among these members may still impact our estimates. Fourth, a notable limitation of our study is the exclusion of cardiovascular death in our definition of MACE. This exclusion stems from our lack of access to detailed data regarding the exact causes of death among the beneficiaries. Consequently, we may have overlooked MACE events in individuals who succumbed to an MACE-related cause but died before they could be diagnosed with an MACE or underwent a revascularization procedure. This limitation leads to an underestimation of the MACE prevalence in our study. Fifth, our dataset did not contain information on traumatic events, and as such, we could not compare the MACE risk between individuals exposed to traumatic events with and without subsequent PTSD. Consequently, we were unable to determine whether the increased MACE risk is a consequence of the traumatic event itself or the psychological sequelae that characterize PTSD.

Conclusion

Our study provides empirical support for an increased risk of MACE among males and female beneficiaries with PTSD in South Africa, a population exposed to a range of traumas that extend beyond war-related experiences. These findings highlight the importance of monitoring cardiovascular risk among individuals diagnosed with PTSD and support integrated care models that combine mental health services with physical healthcare.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S2045796024000052.

Availability of data and materials

Data were obtained from the International Epidemiology Databases to Evaluate AIDS-Southern Africa (IeDEA-SA). Due to legal and ethical restrictions, the data cannot be made publicly available. For inquiries about the data, readers can contact IeDEA-SA through the online form available at https://www.iedea-sa.org/contact-us/.

Author contributions

Cristina Mesa-Vieira and Christiane Didden are joint first authors.

Financial support

Research reported in this publication was supported by the Swiss National Science Foundation under Award Number 193381, the Marie Skłodowska-Curie (Horizon 2020 – COFUND), and the U.S. National Institutes of Health’s National Institute of Allergy and Infectious Diseases, the Eunice Kennedy Shriver National Institute of Child Health and Human Development, Division of Cancer Epidemiology and Genetics, National Cancer Institute, the National Institute of Mental Health, the National Institute on Drug Abuse, the National Heart, Lung, and Blood Institute, the National Institute on Alcohol Abuse and Alcoholism, the National Institute of Diabetes and Digestive and Kidney Diseases and the Fogarty International Center under Award Number U01AI069924. The content is solely the responsibility of the authors and does not necessarily represent the official views of the funders.

Competing interests

The authors declare none.

Ethical standards

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008.

References

American Diabetes Association (2021) 2. Classification and diagnosis of diabetes: Standards of medical care in diabetes—2021. Diabetes Care 44(Suppl 1), S15S33.CrossRefGoogle Scholar
Akasaki, Y and Ohishi, M (2020) Cerebrovascular and cardiovascular diseases caused by drugs of abuse. Hypertension Research 43(5), 363371.CrossRefGoogle ScholarPubMed
Angelakis, S and Nixon, RDV (2015) The comorbidity of PTSD and MDD: Implications for clinical practice and future research. Behaviour Change 32(1), 125.CrossRefGoogle Scholar
Arnett, DK, Blumenthal, RS, Albert, MA, Buroker, AB, Goldberger, ZD, Hahn, EJ, Himmelfarb, CD, Khera, A, Lloyd-Jones, D, McEvoy, JW, Michos, ED, Miedema, MD, Munoz, D, Smith, SC Jr, Virani, SS, Williams, KA Sr, Yeboah, J and Ziaeian, B (2019) 2019 ACC/AHA Guideline on the Primary Prevention of Cardiovascular Disease: A report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. Circulation 140(11), e596e646.Google Scholar
Atwoli, L, Stein, DJ, Williams, DR, McLaughlin, KA, Petukhova, M, Kessler, RC and Koenen, KC (2013) Trauma and posttraumatic stress disorder in South Africa: analysis from the South African Stress and Health Study. BMC Psychiatry 13(1), .CrossRefGoogle ScholarPubMed
Bosco, E, Hsueh, L, McConeghy, KW, Gravenstein, S and Saade, E (2021) Major adverse cardiovascular event definitions used in observational analysis of administrative databases: A systematic review. BMC Medical Research Methodology 21(1), .CrossRefGoogle ScholarPubMed
Brady, KT, Kileen, TK, Brewerton, T and Lucerini, S (2000) Comorbidity of psychiatric disorders and posttraumatic stress disorder. Journal of Clinical Psychiatry 61(Supplement 7), 2232.Google ScholarPubMed
Breslau, N, Davis, GC, Peterson, EL and Schultz, L (1997) Psychiatric sequelae of posttraumatic stress disorder in women. Archives of General Psychiatry 54(1), 8187.CrossRefGoogle ScholarPubMed
Brewin, CR, Andrews, B and Valentine, JD (2000) Meta-analysis of risk factors for posttraumatic stress disorder in trauma-exposed adults. Journal of Consulting and Clinical Psychology 68(5), 748766.CrossRefGoogle ScholarPubMed
Chen, M-H, Pan, T-L, Li, C-T, Lin, W-C, Chen, Y-S, Lee, Y-C, Tsai, S-J, Hsu, J-W, Huang, K-L, Tsai, C-F, Chang, W-H, Chen, T-J, Su, T-P and Bai, Y-M (2015) Risk of stroke among patients with post-traumatic stress disorder: Nationwide longitudinal study. The British Journal of Psychiatry 206(4), 302307.CrossRefGoogle ScholarPubMed
Contractor, AA, Weiss, NH, Dolan, M and Mota, N (2020) Examination of the structural relations between posttraumatic stress disorder symptoms and reckless/self-destructive behaviors. International Journal of Stress Management 27(1), 3544.CrossRefGoogle ScholarPubMed
Day, C and Gray, A (2013) Health and related indicators. South African Health Review 17.Google Scholar
De Hert, M, Detraux, J and Vancampfort, D (2018) The intriguing relationship between coronary heart disease and mental disorders. Dialogues in Clinical Neuroscience 20(1), 3140.CrossRefGoogle ScholarPubMed
DiGangi, JA, Gomez, D, Mendoza, L, Jason, LA, Keys, CB and Koenen, KC (2013) Pretrauma risk factors for posttraumatic stress disorder: A systematic review of the literature. Clinical Psychology Review 33(6), 728744.CrossRefGoogle ScholarPubMed
Edmondson, D, Kronish, IM, Shaffer, JA, Falzon, L and Burg, MM (2013) Posttraumatic stress disorder and risk for coronary heart disease: A meta-analytic review. American Heart Journal 166(5), 806814.CrossRefGoogle ScholarPubMed
Edmondson, D and von Känel, R (2017) Post-traumatic stress disorder and cardiovascular disease. The Lancet Psychiatry 4(4), 320329.CrossRefGoogle ScholarPubMed
Flory, JD and Yehuda, R (2015) Comorbidity between post-traumatic stress disorder and major depressive disorder: Alternative explanations and treatment considerations. Dialogues in Clinical Neuroscience 17(2), 141150.CrossRefGoogle ScholarPubMed
Gooley, TA, Leisenring, W, Crowley, J and Storer, BE (1999) Estimation of failure probabilities in the presence of competing risks: New representations of old estimators. Statistics in Medicine 18(6), 695706.3.0.CO;2-O>CrossRefGoogle ScholarPubMed
Gordon, T, Booysen, F and Mbonigaba, J (2020) Socio-economic inequalities in the multiple dimensions of access to healthcare: The case of South Africa. BMC Public Health 20(1), .CrossRefGoogle ScholarPubMed
Gradus, JL, Farkas, DK, Svensson, E, Ehrenstein, V, Lash, TL, Milstein, A, Adler, N and Sørensen, HT (2015) Associations between stress disorders and cardiovascular disease events in the Danish population. BMJ Open 5(12), .CrossRefGoogle ScholarPubMed
Herman, AA, Stein, DJ, Seedat, S, Heeringa, SG, Moomal, H and Williams, DR (2009) The South African Stress and Health (SASH) study: 12-month and lifetime prevalence of common mental disorders. South African Medical Journal 99(5 Pt 2), 339344.Google ScholarPubMed
Hernán, MA and Robins, JM (2020) Causal Inference: What If. Boca Raton: Chapman & Hall/CRC.Google Scholar
Heumann, C and Shalabh, MS (2016) Introduction to Statistics and Data Analysis. Switzerland: Springer Cham.CrossRefGoogle Scholar
Jacquet-Smailovic, M, Brennsthul, M, Denis, I, Kirche, A, Tarquinio, C and Tarquinio, C (2022) Relationship between Post-traumatic Stress Disorder and subsequent myocardial infarction: A systematic review and meta-analysis. Journal of Affective Disorders 297, 525535.CrossRefGoogle ScholarPubMed
Kessler, RC, Aguilar-Gaxiola, S, Alonso, J, Benjet, C, Bromet, EJ, Cardoso, G, Degenhardt, L, de Girolamo, G, Dinolova, RV, Ferry, F, Florescu, S, Gureje, O, Haro, JM, Huang, Y, Karam, EG, Kawakami, N, Lee, S, Lepine, JP, Levinson, D, Navarro-Mateu, F, Pennell, BE, Piazza, M, Posada-Villa, J, Scott, KM, Stein, DJ, Ten Have, M, Torres, Y, Viana, MC, Petukhova, MV, Sampson, NA, Zaslavsky, AM and Koenen, KC (2017) Trauma and PTSD in the WHO World Mental Health Surveys. European Journal of Psychotraumatology 8(sup5), .CrossRefGoogle ScholarPubMed
Lambert, AM, Parretti, HM, Pearce, E, Price, MJ, Riley, M, Ryan, R, Tyldesley-Marshall, N, Avşar, TS, Matthewman, G, Lee, A, Ahmed, K, Odland, ML, Correll, CU, Solmi, M and Marshall, T (2022) Temporal trends in associations between severe mental illness and risk of cardiovascular disease: A systematic review and meta-analysis. PLoS Medicine 19(4), .CrossRefGoogle ScholarPubMed
Lendle, SD, Schwab, J, Petersen, ML and van der Laan, MJ (2017) ltmle: An R package implementing targeted minimum loss-based estimation for longitudinal data. Journal of Statistical Software 81(1), 121.CrossRefGoogle Scholar
Mansournia, MA, Etminan, M, Danaei, G, Kaufman, JS and Collins, G (2017) Handling time varying confounding in observational research. BMJ 359, .Google ScholarPubMed
McCall, CA, Turkheimer, E, Tsang, S, Avery, A, Duncan, GE and Watson, NF (2019) Sleep duration and post-traumatic stress disorder symptoms: A twin study. Sleep 42(12), 110.CrossRefGoogle ScholarPubMed
Nambiema, A, Lisan, Q, Vaucher, J, Perier, MC, Boutouyrie, P, Danchin, N, Thomas, F, Guibout, C and Solelhac, G, Heinzer, R, Jouven, X, Maruqes-Vidal, P and Empana, JP (2023) Healthy sleep score changes and incident cardiovascular disease in European prospective community-based cohorts. European Heart Journal 44(47), 49684978.CrossRefGoogle ScholarPubMed
NDoH, STATS S, SAMRC and ICF (2019) South Africa Demographic and Health Survey 2016. Pretoria, South Africa, and Rockville, Maryland, USA: National Department of Health, Statistics South Africa, South African Medical Research Council, and ICF.Google Scholar
O’Connor, RC, Worthman, CM, Abanga, M, Athanassopoulou, N, Boyce, N, Chan, LF, Christensen, H, Das-Munshi, J, Downs, J, Koenen, KC, Moutier, CY, Templeton, P, Batterham, P, Brakspear, K, Frank, RG, Gilbody, S, Gureje, O, Henderson, D, John, A, Kabagambe, W, Khan, M, Kessler, D, Kirtley, OJ, Kline, S, Kohrt, B, Lincoln, AK, Lund, C, Mendenhall, E, Miranda, R, Mondelli, V, Niederkrotenthaler, T, Osborn, D, Pirkis, J, Pisani, AR, Prawira, B, Rachidi, H, Seedat, S, Siskind, D, Vijayakumar, L and Yip, PSF (2023) Gone Too Soon: Priorities for action to prevent premature mortality associated with mental illness and mental distress. The Lancet Psychiatry 10(6), 452464.CrossRefGoogle ScholarPubMed
O’Donnell, CJ, Schwartz Longacre, L, Cohen, BE, Fayad, ZA, Gillespie, CF, Liberzon, I, Pathak, GA, Polimanti, R, Risbrough, V, Ursano, RJ, Vander Heide, RS, Yancy, CW, Vaccarino, V, Sopko, G and Stein, MB (2021) Posttraumatic stress disorder and cardiovascular disease: State of the science, knowledge gaps, and research opportunities. JAMA Cardiology 6(10), 12071216.CrossRefGoogle ScholarPubMed
Ozer, EJ, Best, SR, Lipsey, TL and Weiss, DS (2003) Predictors of posttraumatic stress disorder and symptoms in adults: A meta-analysis. Psychological Bulletin 129(1), 5273.CrossRefGoogle ScholarPubMed
Petersen, M, Schwab, J, Gruber, S, Blaser, N, Schomaker, M and van der Laan, M (2014) Targeted maximum likelihood estimation for dynamic and static longitudinal marginal structural working models. Journal of Causal Inference 2(2), 147185.CrossRefGoogle ScholarPubMed
Radell, M L, Hamza, EA and Moustafa, AA (2020) Depression in post-traumatic stress disorder. Reviews in the Neurosciences 31(7), 703722.CrossRefGoogle ScholarPubMed
Rosengren, A, Smyth, A, Rangarajan, S, Ramasundarahettige, C, Bangdiwala, SI, AlHabib, KF, Avezum, A, Bengtsson Bostrom, K, Chifamba, J, Gulec, S, Gupta, R, Igumbor, EU, Iqbal, R, Ismail, N, Joseph, P, Kaur, M, Khatib, R, Kruger, IM, Lamelas, P, Lanas, F, Lear, SA, Li, W, Wang, C, Quiang, D, Wang, Y, Lopez-Jaramillo, P, Mohammadifard, N, Mohan, V, Mony, PK, Poirier, P, Srilatha, S, Szuba, A, Teo, K, Wielgosz, A, Yeates, KE, Yusoff, K, Yusuf, R, Yusufali, AH, Attaei, MW, McKee, M and Yusuf, S (2019) Socioeconomic status and risk of cardiovascular disease in 20 low-income, middle-income, and high-income countries: The Prospective Urban Rural Epidemiologic (PURE) study. The Lancet Global Health 7(6), e748e760.CrossRefGoogle ScholarPubMed
Ruffieux, Y, Wettstein, A, Maartens, G, Folb, N, Mesa-Vieira, C, Didden, C, Tlali, M, Williams, C, Cornell, M, Schomaker, M, Johnson, LF, Joska, JA, Egger, M and Haas, AD(2023) Life-years lost associated with mental illness: A cohort study of beneficiaries of a South African medical insurance scheme. Journal of Affective Disorders 340, 204212.CrossRefGoogle ScholarPubMed
Sareen, J (2014) Posttraumatic stress disorder in adults: Impact, comorbidity, risk factors, and treatment. The Canadian Journal of Psychiatry 59(9), 460467.CrossRefGoogle ScholarPubMed
Scherrer, JF, Salas, J, Cohen, BE, Schnurr, PP, Schneider, FD, Chard, KM, Tuerk, P, Friedman, MJ, Norman, SB, van den Berk-clark, C and Lustman, PJ (2019) Comorbid conditions explain the association between posttraumatic stress disorder and incident cardiovascular disease. Journal of the American Heart Association 8(4), .CrossRefGoogle ScholarPubMed
Schisterman, EF, Cole, SR and Platt, RW (2009) Overadjustment bias and unnecessary adjustment in epidemiologic studies. Epidemiology 20(4), 488495.CrossRefGoogle ScholarPubMed
Schomaker, M, Luque-Fernandez, MA, Leroy, V and Davies, MA (2019) Using longitudinal targeted maximum likelihood estimation in complex settings with dynamic interventions. Statistics in Medicine 38(24), 48884911.CrossRefGoogle ScholarPubMed
Schultz, WM, Kelli, HM, Lisko, JC, Varghese, T, Shen, J, Sandesara, P, Quyyumi, AA, Taylor, HA, Gulati, M, Harold, JG, Mieres, JH, Ferdinand, KC, Mensah, GA and Sperling, LS (2018) Socioeconomic status and cardiovascular outcomes: Challenges and interventions. Circulation 137(20), 21662178.CrossRefGoogle ScholarPubMed
Shao, M, Lin, X, Jiang, D, Tian, H, Xu, Y, Wang, L, Ji, F, Zhou, C, Song, X and Zhuo, C (2020) Depression and cardiovascular disease: Shared molecular mechanisms and clinical implications. Psychiatry Research 285, .CrossRefGoogle ScholarPubMed
Song, H, Fang, F, Arnberg, FK, Mataix-Cols, D, Fernández de la Cruz, L, Almqvist, C, Fall, K, Lichtenstein, P, Thorgeirsson, G and Valdimarsdóttir, UA (2019) Stress related disorders and risk of cardiovascular disease: Population based, sibling controlled cohort study. BMJ 365, .Google ScholarPubMed
Tang, C, Goldsamt, L, Meng, J, Xiao, X, Zhang, L, Williams, AB and Wang, H (2020) Global estimate of the prevalence of post-traumatic stress disorder among adults living with HIV: A systematic review and meta-analysis. BMJ Open 10(4), .CrossRefGoogle ScholarPubMed
Tibshirani, R (1996) Regression shrinkage and selection via the Lasso. Journal of the Royal Statistical Society. Series B (Methodological) 58(1), 267288.CrossRefGoogle Scholar
Van der Laan, M and Rose, S (2011) Targeted Learning in Data Science. New York, NY: Springer.CrossRefGoogle Scholar
Young, JG, Stensrud, MJ, Tchetgen Tchetgen, EJ and Hernán, MA (2020) A causal framework for classical statistical estimands in failure-time settings with competing events. Statistics in Medicine 39(8), 11991236.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Characteristics of beneficiaries with and without PTSD diagnosis at the end of follow-up

Figure 1

Figure 1. Cumulative incidence of PTSD by sex.

Abbreviations: PTSD, post-traumatic stress disorder; CI, confidence interval.
Figure 2

Figure 2. Factors associated with major adverse cardiovascular events1.

Abbreviations: PTSD, post-traumatic stress disorder; HIV, human immunodeficiency virus; CI, confidence interval. 1We considered the following major adverse cardiovascular events: myocardial infarction, stroke or hospitalization for unstable angina/revascularization. Model 1 was adjusted for PTSD, sex, HIV, age and population group. Model 2 was adjusted for PTSD, sex, HIV, age, population group, substance use disorder, psychotic disorders, major depressive disorder, use of antipsychotic medication and sleep disorder. Model 3 was adjusted for PTSD, sex HIV, age, population group, substance use disorder, psychotic disorder, major depressive disorder, use of antipsychotic medication, sleep disorder, diabetes, dyslipidaemia and hypertension.
Figure 3

Figure 3. Major adverse cardiovascular events under PTSD and no PTSD.

Abbreviations: PTSD, post-traumatic stress disorder; MACEs, major adverse cardiovascular events.
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