Hostname: page-component-78c5997874-dh8gc Total loading time: 0 Render date: 2024-11-10T05:11:53.226Z Has data issue: false hasContentIssue false

The association between common mental disorders and tuberculosis: a case–control study from Guinea-Bissau

Published online by Cambridge University Press:  08 February 2024

Lena Larson*
Affiliation:
Bandim Health Project, Bissau, Guinea-Bissau Department of Infectious Diseases, Aarhus University Hospital, Aarhus, Denmark
Grethe Lemvik
Affiliation:
Bandim Health Project, Bissau, Guinea-Bissau Department of Infectious Diseases, Aarhus University Hospital, Aarhus, Denmark
Frauke Rudolf
Affiliation:
Bandim Health Project, Bissau, Guinea-Bissau Department of Infectious Diseases, Aarhus University Hospital, Aarhus, Denmark
Victor Francisco Gomes
Affiliation:
Department of Infectious Diseases, Aarhus University Hospital, Aarhus, Denmark
Andreas Schröder
Affiliation:
Research Clinic for Functional Disorders and Psychosomatics, Aarhus University Hospital, Aarhus, Denmark
Christian Wejse
Affiliation:
Bandim Health Project, Bissau, Guinea-Bissau Department of Infectious Diseases, Aarhus University Hospital, Aarhus, Denmark GloHAU, Centre for Global Health, School of Public HealthAarhus University, Aarhus, Denmark
*
Corresponding author: Lena Larson; Email: lenalarson@live.dk
Rights & Permissions [Opens in a new window]

Abstract

Objective:

The aim of the study was to explore the association between tuberculosis (TB) and common mental disorders (CMD), in an area with high prevalence of TB.

Methods:

We performed a case–control study of TB patients and unmatched healthy controls, from a demographic surveillance site in Guinea-Bissau. Screening for CMD was performed once for controls and at inclusion and follow-up for TB patients. Kessler 10 (K-10) and a brief version of Hopkins Symptom Checklist 25 (SCL-8d) were used as screening instruments.

Results:

571 controls were interviewed and 416 interviews were performed for 215 TB cases. Estimated CMD prevalence at the time of diagnosis of TB was 33.6 % (SCL-8d) and 46.2 % (K-10), compared with 6.8 % (SCL-8d) and 6.7 % (K-10) among controls; adjusted OR 7.18 (95 % CI 4.07 to 12.67) and 14.52 (95 % CI 8.15 to 25.84), respectively. No significant difference in CMD prevalence rates was observed between TB patients, after 6 months of treatment, and controls.

Conclusion:

Psychological distress and common mental disorders were more prevalent among TB patients at the time of diagnosis compared with the background population, but after completion of TB treatment no increased prevalence of psychological distress was found.

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 on behalf of Scandinavian College of Neuropsychopharmacology

Significant outcomes

  • TB patients had higher occurrence of CMD at the time of diagnosis compared with the background population.

  • CMD prevalence decreased during treatment.

  • Applied screening tools, K-10 and SCL-8d, estimated various prevalence of CMD.

Limitations

  • The number of controls eligible for CMD screening was 571 out of a randomised sample of 1500, and the distribution of sex was unequal between TB cases and controls.

  • We were not able to collect follow-up data for each TB patient at each time point of follow-up.

  • Although controls were screened for TB, there may be controls with TB in our cohort.

Background

Tuberculosis (TB) remains a major global health challenge. WHO has estimated 10 million new TB cases and 1.5 million deaths resulting from TB in 2020 (WHO 2021). It is estimated that mental disorder may be attributed to 418 million disability-adjusted life years (DALYs) in 2019 (16% of global DALYs) (Arias et al, Reference Arias and Verguet2022) Three-quarters occur in low-and middle-income countries (LMIC), where there is a substantial gap between disease burden and access to mental health care (Mental Health Atlas, 2020).

There has been a rising focus on the interplay between psychiatric comorbidities and TB (Sweetland et al., Reference Sweetland, Kritski, Oquendo, Sublette, Norcini Pala, Silva, Karpati, Silva, Moraes, Silva and Wainberg2017). Depression may cause immunosuppression, lower compliance and undernutrition, leading to increased of mortality and community transmission (Pachi et al., Reference Pachi, Bratis, Moussas and Tselebis2013; Ruiz-Grosso et al., Reference Ruiz-Grosso, Cachay, de la Flor, Schwalb and Ugarte-Gil2020), whereas chronic inflammation in TB patients and some anti-tuberculosis medication may increase the risk of psychiatric disease (Doherty et al., Reference Doherty, Kelly, McDonald, O’Dywer, Keane and Cooney2013).

Common mental disorders (CMD) is a term which contains anxiety and depression (Henningsen et al., Reference Henningsen, Zimmermann and Sattel2003). CMD is a useful concept due to the high degree of comorbidity and similarity of epidemiological profiles (Patel et al., Reference Patel, Simon, Chowdhary, Kaaya and Araya2009). Several studies have investigated the association between CMD and TB, but the results are diverse with observed prevalence rates, ranging between 28% and 80 % (Issa et al., Reference Issa, Yussuf and Kuranga2009; Deribew et al., Reference Deribew, Tesfaye, Hailmichael, Apers, Abebe, Duchateau and Colebunders2010; Peltzer et al., Reference Peltzer, Naidoo, Matseke, Louw, McHunu and Tutshana2012; van den Heuvel et al., Reference Van den Heuvel, Chishinga, Kinyanda, Weiss, Patel, Ayles, Harvey, Cloete and Seedat2013; de Araújo et al., Reference De Araújo, Pereira, dos Santos, Marinho, Rodrigues and Barreto2014; Hayward et al., Reference Hayward, Deal, Rustage, Nellums, Sweetland, Boccia, Hargreaves and Friedland2022). Comparability in-between studies may be complicated due to methodological differences, and very few studies have reported CMD prevalence in TB patients compared with the background population (Aghanwa and Erhabor, Reference Aghanwa and Erhabor1998; de Araújo et al., Reference De Araújo, Pereira, dos Santos, Marinho, Rodrigues and Barreto2014; Oh et al., Reference Oh, Choi, Kim, Kim and Cho2017; Cheng et al., Reference Cheng, Liao, Lin and Lai2017).

We aimed to describe the relationship between CMD and TB further, in an area with a high prevalence of TB. Our primary outcomes were the association between prevalence of CMD and pulmonary TB at the time of diagnosis, during treatment and once treatment was completed. Data were collected in 2013–2014 from a continuing cohort of TB patients and from a randomised sample of controls obtained from a surveillance database, in Guinea-Bissau.

Materials and methods

The Bandim Health Project has been a Health and Demographic Surveillance Site, located in Bissau, since 1978 (Gomes et al., Reference Gomes, Andersen, Wejse, Oliveira, Vieira, Joaquim, Vieira, Aaby and Gustafson2011). The study area consists of six suburban areas, and the population is followed by regular demographic surveys. All individuals in the area are registered with their id number, age, sex, ethnic group and socio-economic data. Guinea-Bissau has an incidence of pulmonary TB of 279/100 000 person-years (Lemvik et al., Reference Lemvik, Rudolf, Vieira, Sodemann, Østergaard, Rodrigues, Gomes, Aaby and Wejse2014). There are no previous data of CMD prevalence in this population.

Inclusion of cases and controls

A randomised sample of unmatched controls, ≥18 years, was obtained from surveillance data from the study area. The randomised sample of controls will be referred to as background population throughout the text. Controls were visited and interviewed at home by a trained field assistant and were paid three visits before the person was considered as non-eligible, as described by Virenfeldt (Virenfeldt et al., Reference Virenfeldt, Rudolf, Camara, Furtado, Gomes, Aaby, Petersen and Wejse2014). Standardised questionnaires were used to obtain information on sociodemographic characteristics and symptoms of TB and CMD. Controls with ≥1 symptoms of pulmonary TB, such as cough, haemoptysis, dyspnoea, chest pain and night sweats, were investigated for TB as described by Rudolf et al (Bjerregaard-Andersen et al., Reference Bjerregaard-Andersen, da Silva, Ravn, Ruhwald, Andersen, Sodemann, Gustafson, Aaby and Wejse2010; Porskrog et al., Reference Porskrog, Bjerregaard-Andersen, Oliveira, Joaquím, Camara, Andersen, Rabna, Aaby and Wejse2011; Rudolf et al., Reference Rudolf, Haraldsdottir, Mendes, Wagner, Gomes, Aaby, Østergaard, Eugen-Olsen and Wejse2014). Controls diagnosed with TB were excluded.

Since 1996, a surveillance system has detected all patients diagnosed with and treated for TB in the study area. The field assistant identified TB patient during daily visits at the TB treatment facilities. Patients’ diagnosis has been made according to WHO criteria (Gomes et al., Reference Gomes, Andersen, Lemvik, Wejse, Oliveira, Vieira, Carlos, Vieira, Aaby and Gustafson2013). TB cases were obtained from this continuous TB cohort, if diagnosed with pulmonary TB and ≥18 years. (Rudolf et al., Reference Rudolf, Haraldsdottir, Mendes, Wagner, Gomes, Aaby, Østergaard, Eugen-Olsen and Wejse2014). All TB patients were treated with ethambutol, isoniazid, rifampicin, and pyrazinamide for two months, followed by isoniazid and ethambutol for four months. When enrolled in the TB cohort, patients were clinically examined, interviewed regarding symptoms and background information, and tested for HIV, as described elsewhere (Rudolf et al., Reference Rudolf, Haraldsdottir, Mendes, Wagner, Gomes, Aaby, Østergaard, Eugen-Olsen and Wejse2014). Patients were followed up at two, four and six months to assess treatment outcome. Screening for CMD was performed when patients visited the healthcare centre at inclusion or at follow-up in the TB cohort. Due to the time frame of the study and the fact that some TB patients skipped controls, we were not able to screen each patient at all time points. In order to screen as many patients as possible at each time point, all TB patients coming to either inclusion or follow-up in the TB cohort were screened, whether they had been screened before or not. The TB patients were divided into four groups based on time point of screening; at inclusion, at two months, at four months and at six months. Some patients contributed to data in several groups, whereas some patients contributed to data in only one group. Our aim was to compare CMD among TB patients at the time of diagnosis, during treatment and once treatment was completed with a sample of randomly selected controls representing the background population; thus, TB patients were possibly screened at several time points during the inclusion period and controls only once. Screening for CMD in controls was performed continuously, parallel with the screening for CMD among TB patients. There was no available treatment for psychiatric disorders in Guinea-Bissau at the time of the study, and we were not able to offer treatment for patients screened positive for CMD.

All questionnaires, including CMD screening tools, were in written Portuguese and translated by the field assistant into the local language Creole. All screenings for CMD were performed by only one field assistant, and all interviews were regularly supervised by the primary investigator (LL).

Screening tools for CMD

We chose two screening tools in order to screen for CMD, designed to detect symptoms of psychological and emotional distress. Psychological distress (PD) will be used throughout the text to address psychological and emotional stress and the risk of having CMD.

The Kessler 10 scale (K-10) contains 10 items regarding depression, tiredness, nervousness, restlessness, hopelessness and worthlessness, during 30 days prior to the survey. Each question is rated on a 5-point Likert scale (1–5), ranging from ‘never’ to ‘all the time’. K-10 has been validated in low-resource settings, with various recommendations of cut-off values (Stolk et al., Reference Stolk, Kaplan and Szwarc2014). Andrews et al estimated a sensitivity of 0.94 and a specificity of 0.63 for CMD at a cut-off at ≥14 (Andrews and Slade, Reference Andrews and Slade2001). In order to identify persons at risk of CMD, a cut-off of ≥14 was chosen to estimate prevalence of PD.

SCL-8 is an 8-item abbreviated version of Hopkins Symptom Check List (HSCL-25) containing questions concerning nervousness, fear, spells of panic, feeling blue, worrying, hopelessness, feeling everything is an effort and worthlessness (Fink et al., Reference Fink, Ørbøl, Hansen, Søndergaard and De Jonge2004a). It has been validated in a population with medical patients, psychiatric patients and in the background population (Fink et al., Reference Fink, Jensen, Borgquist, Brevik, Dalgard, Sandager, Engberg, Hansson, Holm and Joukamaa1995; Reference Fink, Ørnbøl, Huyse, De Jonge, Lobo, Herzog, Slaets, Arolt, Cardoso, Rigatelli and Hansen2004b). Each question has five response categories (0–4), ranging from ‘not at all’ to ‘extremely’, 30 days prior to the interview. In a validation study, items were dichotomised, in a way that the categories ‘not at all’ and ‘a little bit’ were categorised as negative responses and ‘moderately’, ‘quite a bit’ and ‘extremely’ as positive responses (Fink et al., Reference Fink, Ørnbøl, Huyse, De Jonge, Lobo, Herzog, Slaets, Arolt, Cardoso, Rigatelli and Hansen2004b). A cut-off of ≥1 on the dichotomised SCL-8 scale was used to identify cases at risk of having CMD, with a sensitivity of 0.73 and a specificity of 0.61 for a medical setting (Fink et al., Reference Fink, Ørnbøl, Huyse, De Jonge, Lobo, Herzog, Slaets, Arolt, Cardoso, Rigatelli and Hansen2004b). Described screening tool is referred to as SCL-8 dichotomised (SCL-8d) and is used to estimate PD prevalence.

Data handling

Data were entered using dBase V software and access 2007, and transferred to STATA (version 11) for analysis. To assess statistical differences in demographic characteristics at baseline, Pearson’s X2-test was used for categorical variables, and ANOVA table test for continuous variables. Sex, civil status, ethnicity, religion, education, employment, smoking, alcohol and civil state were entered as categorical variables, and age was entered as a continuous variable. Statistical differences in sex and age were assessed between eligible and non-eligible controls. Mean score for PD was calculated for K-10 and SCL-8, and prevalence of PD was estimated by using cut-off scores for K-10 and SCL-8d. Difference in PD prevalence between TB case and controls was estimated by odds ratio (OR), with 95% confidence interval (CI), using logistic regression. We observed significant difference in sociodemographic characteristics for sex, age, religion, education, employment, alcohol and smoking, but due to the setup of the study we were not able to define all of them as pre-exposure covariates. To assess statistical differences in sociodemographic characteristics with k-10 and SCL-8 outcome, crude logistic regression and adjusted OR were calculated for each of the sociodemographic characteristics at baseline. Sex, employment, alcohol and age, each respectively, changed the estimate ≥10%. A directed acyclic graph was drawn (Fig. 1) based on analyses and evidence from known risk factors for tuberculosis and common mental disorder (Bitew, Reference Bitew2014; Horton et al., Reference Horton, MacPherson, Houben, White and Corbett2016; Neyrolles and Quintana-Murci, Reference Neyrolles and Quintana-Murci2009; 2016; Silva et al, Reference Silva, Muñoz-Torrico, Duarte, Galvão, Bonini, Arbex, Arbex, Augusto, Rabahi and Mello2018; Steel et al., Reference Steel, Marnane, Iranpour, Chey, Jackson, Patel and Silove2014). Religion, education and smoking, only affected one of the main variables (TB) and were defined as potential mediators. To avoid unstable estimates, they were not included in the final model. Employment status was defined as a potential collider, due to the assumption that it may be affected by both main variables TB and PD. To avoid the risk of introducing bias, it was not included in the multivariate model. Sex, alcohol and age were assumed to affect both TB and PD and were included in the multivariable regression model as potential confounders. Cronbach’s alpha was used to evaluate internal consistency.

Figure 1. Directed acyclic graph to evaluate connections between variables.

Ethics

The project has been reviewed and approved by the National Ethics Committee in Guinea-Bissau (NoRef0406/CNES/INASA/2013). Before inclusion, TB patients were verbally informed in the common language Creole and written Portuguese. Informed consent was obtained by signature or by a fingerprint if illiterate. 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.

Results

From April 2013 to June 2014, 571 interviews were performed for controls and 416 for TB cases. A total number of 215 TB patients were interviewed; 119 at inclusion, 105 at two months, 92 at four months and 100 at six months (Fig. 2).

Figure 2. Flow chart of cases, with number of TB patients available for PD screening at each time point (LTFU: Lost To Follow Up) and flow chart of controls.

Out of the randomised sample of unmatched controls of 1500 people, 571 controls were eligible for screening (Fig. 2). The most frequent cause for being non-eligible was relocation and travelling. Non-eligible controls were more likely to be male, but no significant difference was observed in mean age between eligible and non-eligible controls (Data not shown).

Characteristics of cases and controls

Significant differences between cases at the different time points and controls were observed for several of the background characteristics (Table 1). At all time points, cases were more likely to be male and being smokers.

Table 1. Sociodemographic characteristics of cases at each time point in the TB cohort and randomised controls from background population

Smoking or stopped smoking within the last six months.

* Difference between cases and controls, p-value for cases at each time point compared with controls.

Variables with missing data. Education: two patients at inclusion, two patients at two months, one patient at four months, one control; employment: three controls, one patient at two months; smoking: one control; civil state: five controls.

PD and risk of having CMD

Mean scores and prevalence rates were significantly higher for TB patients at inclusion compared with controls, for both SCL-8 and K-10 (Table 2). For both scales, a decrease in mean score and prevalence rates during treatment was observed.

Table 2. Mean scores and unadjusted prevalence rates of psychological distress estimated by SCL-8 and K-10

* Based on SCL-8 scale (item score 0–4); items dichotomised (SCL-8d), 0–1 categorised as negative (0) and 2–4 categorised as positive (1).

TB patients at inclusion had significantly greater OR of PD compared with controls, estimated by both SCL-8d and K-10; OR 6.91 (95% CI 4.19 to 11.39) and OR 12.05 (95% CI 7.40 to 19.63) (Table 3). After adjusting for potential confounders, the significant difference in prevalence of PD for TB patients at inclusion compared with controls remained; OR = 7.18 (95% CI 4.07 to 12.67) and OR = 14.52 (95% CI 8.15 to 25.84). At two months of follow-up, TB patients co-infected with HIV had a significantly greater OR of PD for both scales, whereas no significant difference was observed for non-co-infected patients (Table 3). At six months, no significant difference in PD prevalence rates was observed between all TB patients and controls. For both cases and controls, most prevalent symptoms for SCL-8 were feeling blue and feeling nervousness, and for K-10, feeling depressed and feeling tired (Table 4). Cronbach’s alpha was calculated to 0.711 for SCL-8d and 0.803 for K-10 (Table 4).

Table 3. Association between psychological distress and tuberculosis at each time point, crude and adjusted odds ratio (OR) by logistic regression

* Based on SCL-8 scale (item score 0–4); items dichotomised, 0–1 categorised as negative (0) and 2–4 categorised as positive.

Numbers available for crude analyses: 571 controls, 119 cases at inclusion, 105 cases at 2 months, 92 cases at 4 months and 100 cases at 6 months.

Numbers available for adjusted analyses: 561 controls, 117 cases at inclusion, 103 cases at 2 months, 90 cases at 4 months and 100 cases at 6 months.

§ Adjusted for sex, age, and alcohol consumption.

Table 4. Prevalence of symptoms for controls and for TB patients at each time point

* Presence of symptoms is defined as item score >0, item scale 0–4.

Presence of symptoms is defined as item score >1, item scale 1–5.

There were no significant differences between TB patients available and non-available to follow-up in demographic background variables and PD score at baseline (Data not shown).

Discussion

The association between CMD and TB

We observed a significantly higher prevalence of PD and risk of CMD among TB patients at the time of diagnosis, compared with the background population. Only one African study, placed in Nigeria, has compared CMD prevalence between newly diagnosed TB patients and healthy controls and found CMD among 30% of TB patients and 5% of the controls (Aghanwa and Erhabor, Reference Aghanwa and Erhabor1998). A published study based on a large dataset from the World Health Survey from 48 LMIC, defining TB patients from self-reported symptoms (Koyanagi et al., Reference Koyanagi, Vancampfort, Carvalho, DeVylder, Haro, Pizzol, Veronese and Stubbs2017), and a Korean study using a nationwide database, found comparable results (Oh et al., Reference Oh, Choi, Kim, Kim and Cho2017). PD score declined during TB treatment, and no significant difference was observed after six months, which is consistent with observations from TB patients in Peru and TB co-infected HIV patients in Ethiopia (Ugarte-Gil et al., Reference Ugarte-Gil, Ruiz, Zamudio, Canaza, Otero, Kruger and Seas2013; Deribew et al., Reference Deribew, Deribe, Reda, Tesfaye, Hailmichael and Maja2013). Our observations of a decrease in PD score during treatment may indicate that active TB at diagnosis also displays symptoms of PD, which decrease upon treatment; however, it may also illustrate a decline in PD symptoms following improvement of TB.

The evidence of an association between CMD and TB is growing (Hayward et al., Reference Hayward, Deal, Rustage, Nellums, Sweetland, Boccia, Hargreaves and Friedland2022), and a synergistic effect between CMD and TB has been suggested (Sweetland et al., Reference Sweetland, Kritski, Oquendo, Sublette, Norcini Pala, Silva, Karpati, Silva, Moraes, Silva and Wainberg2017). CMD may cause delayed healthcare seeking, compromised immune status and impaired compliance to TB treatment, leading to increased community transmission, drug resistance and mortality, whereas TB may be a risk factor for CMD due to stigmatisation and economic consequences such as inability to work (Sweetland et al., Reference Sweetland, Kritski, Oquendo, Sublette, Norcini Pala, Silva, Karpati, Silva, Moraes, Silva and Wainberg2017). Thus, screening and handling CMD in TB patients may be the next step to get on track with the goal of TB reduction.

CMD prevalence and different scales and cut-offs

Low-resource settings carry both the burden of a high prevalence of TB and a substantial gap between prevalence of CMD and access to mental health care (Mental Health Atlas, 2020; WHO 2021). To be able to find and treat CMD among TB patients, reliable CMD screening tools are needed. A cut-off at ≥16 suggested as lowest cut-off for K-10, by a validation study performed in a similar setting (Andersen et al., Reference Andersen, Grimsrud, Myer, Williams, Stein and Seedat2011), resulted in very low prevalence rates of PD in our population. SCL-8 was developed specifically for use in patients with physical disease, and hence, common somatic symptoms such as fatigue are not included in the scale. SCL-8d has not been validated in a low-resource setting but may be a useful CMD screening tool among TB patients that present with symptoms such as fatigue and weight loss. Our study underlines that there may be difficulties when using translated/adapted versions of screening tools, which are consistent with results from reviews on measuring depression and anxiety in sub-Saharan Africa (Sweetland et al., Reference Sweetland, Belkin and Verdeli2014), and the clinical use of the Kessler scales (Stolk et al., Reference Stolk, Kaplan and Szwarc2014).

Strengths and limitations

Strengths of our study include standardised diagnosis, treatment and follow-up of TB patients. We had the possibility of obtaining a randomised sample from the background population and to reproduce uniform interviews for both PD scales with no inter-individual variance, as all interviews were performed by only one field assistant. Screening for PD among controls has been performed parallel with the screening of PD among cases, thus potential season variability is considered as low. Our study is one of the few studies that have investigated the difference in PD prevalence between TB patients and the background population in Africa. and we contribute with the first data from Guinea-Bissau on PD in the background population. Our findings of PD and risk of CMD prevalence rates are within the realistic end of ranges compared with previously published studies from Africa, where CMD prevalence rates range from 3.1% to 77.7% among the background population and from 28 to 80% among TB patients (Issa et al., Reference Issa, Yussuf and Kuranga2009; Peltzer et al., Reference Peltzer, Naidoo, Matseke, Louw, McHunu and Tutshana2012; Steel et al., Reference Steel, Marnane, Iranpour, Chey, Jackson, Patel and Silove2014; Hayward et al., Reference Hayward, Deal, Rustage, Nellums, Sweetland, Boccia, Hargreaves and Friedland2022). Internal consistency was acceptable for SCL-8d with Cronbach’s alpha 0.711 and good for K-10 with Cronbach’s alpha 0.820.

Our study has a number of limitations. Firstly, the number of controls eligible for CMD screening was lower than we expected and the distribution of sex was unequal between TB cases and controls. However, it is well known that TB is more prevalent among males and CMD more prevalent among females (Neyrolles and Quintana-Murci, Reference Neyrolles and Quintana-Murci2009; Steel et al., Reference Steel, Marnane, Iranpour, Chey, Jackson, Patel and Silove2014), and the unequal sex distribution would cause a reduction of the association between TB and PD in our sample. This is consistent with our observations of an even higher OR of PD for TB patients, after adjusting for sex and other possible confounders.

Secondly, we were not able to collect follow-up data for each TB patient. Significant difference in background characteristics compared with the background population varied between TB patients at each time point. We investigated if TB patients with PD at baseline were less likely to show up to clinical controls and if their absence cause a reduction in mean PD score at follow-up. However, no such difference was observed. Furthermore, as we had a complete dataset at inclusion, our main finding of a clear association of TB and PD at the time of diagnosis was not influenced by the loss to follow-up.

Thirdly, although controls were screened for TB, there may be controls with TB in our cohort (Porskrog et al., Reference Porskrog, Bjerregaard-Andersen, Oliveira, Joaquím, Camara, Andersen, Rabna, Aaby and Wejse2011). Yet, this would cause a reduction in the association between TB and PD in our sample and would not have weakened our main findings of an association between TB and PD at inclusion.

Fourthly, the study was limited by the lack of referral options for those screening out with mental disorders. This is a general ethical challenge in global mental health, and it is very suboptimal to uncover conditions for which the local standard of care is no care. Yet, we have seen within the field of HIV that describing the burden of disease may be a first step towards changing this situation and opening pathways for future care options.

Public health importance and future directions

Screening for and treating CMD in TB patients may be an important element in strategies to reduce the burden of TB. Further studies are needed to find reliable CMD screening tools, easy to use for trained healthcare providers, and to explore CMD treatment options and interventions among TB patients in LMIC.

Conclusion

Screening for psychological distress revealed a significantly higher prevalence of risk of common mental disorder among TB patients at the time of diagnosis compared with the background population, with a decrease in prevalence rates among TB patients during treatment.

Funding

The paper was first presented at the INDEPTH International Scientific Conference 2015, in Addis Ababa, Ethiopia. We acknowledge the funding received from Lundbeck Foundation, Fonden af 17-12-1981, Direktør Jacob Madsen og Olga Madsens Fond and Ulla og Mogens Folmer Andersens Fond. EDCTP (European Union/European and Developing Countries Clinical Trials Partnership (grant code IP.2007.32080.001) supported data collection during the time of the study.

Author’s contributions

CW and LL conceived the study. LL analysed and interpreted the data and wrote the first draft of the manuscript. LL and FR were responsible for materials and supervision. VFG took part in the data collection and data entering. AS contributed to the choice of screening instruments and interpretation of data. All authors contributed to and approved the final version of the manuscript.

References

Aghanwa, HS and Erhabor, GE (1998) Demographic/socioeconomic factors in mental disorders associated with tuberculosis in southwest Nigeria. Journal of Psychosomatic Research 45(4), 353360.CrossRefGoogle ScholarPubMed
Andersen, LS, Grimsrud, A, Myer, L, Williams, DR, Stein, DJ and Seedat, S (2011) The psychometric properties of the K10 and K6 scales in screening for mood and anxiety disorders in the South African Stress and Health study. International Journal of Methods in Psychiatric Research 20(4), 215223.CrossRefGoogle ScholarPubMed
Andrews, G and Slade, T (2001) Interpreting scores on the Kessler Psychological Distress Scale (K10). Australian and New Zealand Journal of Public Health 25(6), 494497.CrossRefGoogle ScholarPubMed
Arias, DSand Verguet, S (2022) Quantifying the global burden of mental disorders and their economic value. eClinicalMedicine 54, 101675.CrossRefGoogle ScholarPubMed
Bitew, T (2014) Prevalence and risk factors of depression in Ethiopia: a review. Ethiopian Journal of Health Sciences 24(2), 161169. DOI: 10.4314/ejhs.v24i2.9.CrossRefGoogle ScholarPubMed
Bjerregaard-Andersen, M, da Silva, ZJ, Ravn, P, Ruhwald, M, Andersen, PL, Sodemann, M, Gustafson, P, Aaby, P and Wejse, C (2010) Tuberculosis burden in an urban population: a cross sectional tuberculosis survey from Guinea Bissau. BMC Infectious Diseases 10(1), 96.CrossRefGoogle Scholar
Cheng, KC, Liao, KF, Lin, CL and Lai, SW (2017) Increased risk of pulmonary tuberculosis in patients with depression: a cohort study in Taiwan. Frontiers in Psychiatry 8, 235.CrossRefGoogle ScholarPubMed
De Araújo, GS, Pereira, SM, dos Santos, DN, Marinho, JM, Rodrigues, LC and Barreto, ML (2014) Common mental disorders associated with tuberculosis: a matched case-control study. PloS One 9(6), e99551.CrossRefGoogle ScholarPubMed
Deribew, A, Tesfaye, M, Hailmichael, Y, Apers, L, Abebe, G, Duchateau, L and Colebunders, R (2010) Common mental disorders in TB/HIV co-infected patients in Ethiopia. BMC Infectious Diseases 10(1), 201.CrossRefGoogle ScholarPubMed
Deribew, A, Deribe, K, Reda, AA, Tesfaye, M, Hailmichael, Y and Maja, T (2013) Do common mental disorders decline over time in TB/HIV co-infected and HIV patients without TB who are on antiretroviral treatment? BMC Psychiatry 13(1), 174.CrossRefGoogle ScholarPubMed
Doherty, AM, Kelly, J, McDonald, C, O’Dywer, AM, Keane, J and Cooney, J (2013) A review of the interplay between tuberculosis and mental health. General Hospital Psychiatry 35(4), 398406.CrossRefGoogle ScholarPubMed
Fink, P, Jensen, J, Borgquist, L, Brevik, JI, Dalgard, OS, Sandager, I, Engberg, M, Hansson, L, Holm, M and Joukamaa, M (1995) Psychiatric morbidity in primary public health care: a Nordic multicentre investigation. Part I: method and prevalence of psychiatric morbidity. Acta Psychiatrica Scandinavica 92(6), 409418.CrossRefGoogle Scholar
Fink, P, Ørnbøl, E, Huyse, FJ, De Jonge, P, Lobo, A, Herzog, T, Slaets, J, Arolt, V, Cardoso, G, Rigatelli, M and Hansen, MS (2004a) A brief diagnostic screening instrument for mental disturbances in general medical wards. Journal of Psychosomatic Research 57(1), 1724.CrossRefGoogle ScholarPubMed
Fink, P, Ørbøl, E, Hansen, MS, Søndergaard, L and De Jonge, P (2004b) Detecting mental disorders in general hospitals by the SCL-8 scale. Journal of Psychosomatic Research 56(3), 371375.CrossRefGoogle ScholarPubMed
Gomes, VF, Andersen, A, Wejse, C, Oliveira, I, Vieira, FJ, Joaquim, LC, Vieira, CS, Aaby, P and Gustafson, P (2011) Impact of tuberculosis exposure at home on mortality in children under 5 years of age in Guinea-Bissau. Thorax 66(2), 163167.CrossRefGoogle ScholarPubMed
Gomes, VF, Andersen, A, Lemvik, G, Wejse, C, Oliveira, I, Vieira, FJ, Carlos, LJ, Vieira, C, Aaby, P and Gustafson, P (2013) Impact of isoniazid preventive therapy on mortality from tb among children less than 5 years old following exposure to tuberculosis at home in Guinea-Bissau: a prospective cohort study. BMJ Open 3(3), e001545.CrossRefGoogle ScholarPubMed
Hayward, SE, Deal, A, Rustage, K, Nellums, LB, Sweetland, AC, Boccia, D, Hargreaves, S and Friedland, JS (2022) The relationship between mental health and risk of active tuberculosis: a systematic review. BMJ Open 12(1), e048945.CrossRefGoogle ScholarPubMed
Henningsen, P, Zimmermann, T and Sattel, H (2003) Medically unexplained physical symptoms, anxiety, and depression: a meta-analytic review. Psychosomatic Medicine 65(4), 528533.CrossRefGoogle ScholarPubMed
Horton, KC, MacPherson, P, Houben, RM, White, RG and Corbett, EL (2016) Sex differences in tuberculosis burden and notifications in low- and middle-income countries: a systematic review and meta-analysis. PloS Medicine 13(9), e1002119.CrossRefGoogle ScholarPubMed
Issa, BA, Yussuf, AD and Kuranga, SI (2009) Depression comorbidity among patients with tuberculosis in a university teaching hospital outpatient clinic in Nigeria. Mental Health in Family Medicine 6(3), 133138.Google Scholar
Koyanagi, A, Vancampfort, D, Carvalho, AF, DeVylder, JE, Haro, JM, Pizzol, D, Veronese, N and Stubbs, B (2017) Depression comorbid with tuberculosis and its impact on health status: cross-sectional analysis of community-based data from 48 low- and middle-income countries. BMC Medicine 15(1), 209.CrossRefGoogle ScholarPubMed
Lemvik, G, Rudolf, F, Vieira, F, Sodemann, M, Østergaard, L, Rodrigues, A, Gomes, V, Aaby, P and Wejse, C (2014) Decline in overall, smear-negative and HIV-positive TB incidence while smear-positive incidence stays stable in Guinea-Bissau 2004-2011. Tropical Medicine & International Health 19(11), 13671376.CrossRefGoogle ScholarPubMed
Mental Health Atlas (2020) Licence: CC BY-NC-SA 3.0 IGO. Geneva:: World Health Organization (accessed 28 February 2022).Google Scholar
Neyrolles, O and Quintana-Murci, L (2009) Sexual inequality in tuberculosis. PloS Medicine 6(12), e1000199.CrossRefGoogle ScholarPubMed
Oh, KH, Choi, H, Kim, EJ, Kim, HJ and Cho, SI (2017) Depression and risk of tuberculosis: a nationwide population-based cohort study. The International Journal of Tuberculosis and Lung Disease: the Official Journal of the International Union against Tuberculosis and Lung Disease 21(7), 804809.CrossRefGoogle ScholarPubMed
Pachi, A, Bratis, D, Moussas, G and Tselebis, A (2013) Psychiatric morbidity and other factors affecting treatment adherence in pulmonary tuberculosis patients. Tuberculosis Research and Treatment 2013, 137.CrossRefGoogle ScholarPubMed
Patel, V, Simon, G, Chowdhary, N, Kaaya, S and Araya, R (2009) Packages of care for depression in low- and middle-income countries. PloS Medicine 6(10), e1000159.CrossRefGoogle ScholarPubMed
Peltzer, K, Naidoo, P, Matseke, G, Louw, J, McHunu, G and Tutshana, B (2012) Prevalence of psychological distress and associated factors in tuberculosis patients in public primary care clinics in South Africa. BMC Psychiatry 12(1), 89.CrossRefGoogle ScholarPubMed
Porskrog, A, Bjerregaard-Andersen, M, Oliveira, I, Joaquím, LC, Camara, C, Andersen, PL, Rabna, P, Aaby, P and Wejse, C (2011) Enhanced tuberculosis identification through 1-month follow-up of smear-negative tuberculosis suspects. The International Journal of Tuberculosis and Lung Disease: the Official Journal of the International Union against Tuberculosis and Lung Disease 15(4), 459464.CrossRefGoogle ScholarPubMed
Ruiz-Grosso, P, Cachay, R, de la Flor, A, Schwalb, A and Ugarte-Gil, C (2020) Association between tuberculosis and depression on negative outcomes of tuberculosis treatment: a systematic review and meta-analysis. PloS One 15(1), e0227472.CrossRefGoogle ScholarPubMed
Rudolf, F, Haraldsdottir, TL, Mendes, MS, Wagner, AJ, Gomes, VF, Aaby, P, Østergaard, L, Eugen-Olsen, J and Wejse, C (2014) Can tuberculosis case finding among health-care seeking adults be improved? Observations from Bissau. The International Journal of Tuberculosis and Lung Disease: the Official Journal of the International Union against Tuberculosis and Lung Disease 18(3), 277285.CrossRefGoogle ScholarPubMed
Silva, DR, Muñoz-Torrico, M, Duarte, R, Galvão, T, Bonini, EH, Arbex, FF, Arbex, MA, Augusto, VM, Rabahi, MF and Mello, FCQ (2018) Risk factors for tuberculosis: diabetes, smoking, alcohol use, and the use of other drugs. Jornal brasileiro de pneumologia: publicacao official da Sociedade Brasileira de Pneumologia e Tisilogia 44(2), 145152.CrossRefGoogle ScholarPubMed
Steel, Z, Marnane, C, Iranpour, C, Chey, T, Jackson, JW, Patel, V and Silove, D (2014) The global prevalence of common mental disorders: a systematic review and meta-analysis 1980-2013. International Journal of Epidemiology 43(2), 476493.CrossRefGoogle ScholarPubMed
Stolk, Y, Kaplan, I and Szwarc, J (2014) Clinical use of the Kessler psychological distress scales with culturally diverse groups. International Journal of Methods in Psychiatric Research 23(2), 161183.CrossRefGoogle ScholarPubMed
Sweetland, AC, Belkin, GS and Verdeli, H (2014) Measuring depression and anxiety in sub-saharan Africa. Depression and Anxiety 31(3), 223232.CrossRefGoogle ScholarPubMed
Sweetland, AC, Kritski, A, Oquendo, MA, Sublette, ME, Norcini Pala, A, Silva, L, Karpati, A, Silva, EC, Moraes, MO, Silva, J and Wainberg, ML (2017) Addressing the tuberculosis-depression syndemic to end the tuberculosis epidemic. The International Journal of Tuberculosis and Lung Disease: The Official Journal of the International Union against Tuberculosis and Lung Disease 21(8), 852861.CrossRefGoogle ScholarPubMed
Ugarte-Gil, C, Ruiz, P, Zamudio, C, Canaza, L, Otero, L, Kruger, H and Seas, C (2013) Association of major depressive episode with negative outcomes of tuberculosis treatment. PloS One 8(7), e69514.CrossRefGoogle ScholarPubMed
Van den Heuvel, L, Chishinga, N, Kinyanda, E, Weiss, H, Patel, V, Ayles, H, Harvey, J, Cloete, KJ and Seedat, S (2013) Frequency and correlates of anxiety and mood disorders among TB- and HIV-infected Zambians. Aids Care-psychological and Socio-medical Aspects of AIDS/HIV 25(12), 15271535.Google ScholarPubMed
Virenfeldt, J, Rudolf, F, Camara, C, Furtado, A, Gomes, V, Aaby, P, Petersen, E and Wejse, C (2014) Treatment delay affects clinical severity of tuberculosis: a longitudinal cohort study. BMJ Open 4(6), e004818e004818.CrossRefGoogle ScholarPubMed
WHO (2023) Global tuberculosis report 2023, Geneva: World Health Organisation. Available at https://www.who.int/teams/global-tuberculosis-programme/tb-reports/global-tuberculosis-report-2023.Google Scholar
Figure 0

Figure 1. Directed acyclic graph to evaluate connections between variables.

Figure 1

Figure 2. Flow chart of cases, with number of TB patients available for PD screening at each time point (LTFU: Lost To Follow Up) and flow chart of controls.

Figure 2

Table 1. Sociodemographic characteristics of cases at each time point in the TB cohort and randomised controls from background population

Figure 3

Table 2. Mean scores and unadjusted prevalence rates of psychological distress estimated by SCL-8 and K-10

Figure 4

Table 3. Association between psychological distress and tuberculosis at each time point, crude and adjusted odds ratio (OR) by logistic regression

Figure 5

Table 4. Prevalence of symptoms for controls and for TB patients at each time point