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Open Access

Peer-reviewed

Research Article

Low Levels of Dehydroepiandrosterone Sulfate in Younger Burnout Patients

Correction

12 Nov 2015: Lennartsson AK, Theorell T, Kushnir MM, Jonsdottir IH (2015) Correction: Low Levels of Dehydroepiandrosterone Sulfate in Younger Burnout Patients. PLOS ONE 10(11): e0143192. https://doi.org/10.1371/journal.pone.0143192 View correction

Abstract

Objective

Dehydroepiandrosterone sulphate (DHEA-s) is an anabolic protective hormone of importance for maintenance of health. DHEA-s levels peak in young adults and decline thereafter with age. DHEA-s has previously been shown to be lower in individuals reporting prolonged stress. This study investigates DHEA-s levels in patients with clinical burnout, a disorder caused by long-term psychosocial stress.

Methods

122 patients (51% men) and 47 controls (51% men) in the age 25–54 years were included in the study. DHEA-s levels were compared between patients and controls in the whole sample and within each of the three 10-year-interval age groups.

Results

In the youngest age group (25–34 years), DHEA-s levels were on average 25% lower in the patients (p = 0.006). The differences in DHEA-s levels between patients and controls were more pronounced among female than male participants (on average 32% and 13% lower, respectively). There were no differences in DHEA-s levels between patients and controls in the age group 35–44 years (p = 0.927) or 45–54 years (p = 0.897) or when analyzing all age groups together (p = 0.187).

Conclusion

The study indicates that levels of the health promoting “youth” hormone DHEA-s are low in younger burnout patients. The fact that younger adults have much higher DHEA-s levels and more pronounced inter-subject variability in DHEA-s levels than older individuals might explain why burnout status differentiates patients from controls only among the youngest patients included in this study.

Citation: Lennartsson A-K, Theorell T, Kushnir MM, Jonsdottir IH (2015) Low Levels of Dehydroepiandrosterone Sulfate in Younger Burnout Patients. PLoS ONE 10(10): e0140054. https://doi.org/10.1371/journal.pone.0140054

Editor: Onno C. Meijer, Leiden University Medical Centre, NETHERLANDS

Received: March 19, 2015; Accepted: September 21, 2015; Published: October 6, 2015

Copyright: © 2015 Lennartsson et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited

Data Availability: All relevant data are within the paper and its Supporting Information files.

Funding: No external funding was used for the study. The study was funded by the ordinary resources within the Institute of Stress Medicine, Gothenburg, Sweden.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Burnout can be defined as a negative affective state consisting of emotional exhaustion, cognitive weariness and physical fatigue, which is caused by chronic psychosocial stress [1]. It leads to reduced work ability [2] and often also long-term sick leave [3]. Burnout is often accompanied with symptoms of depression and anxiety. Besides the fatigue and mental health burden, burnout is associated with increased risk of adverse physical health [4, 5]. The present study investigates the levels of dehydroepiandrosterone sulfate (DHEA-s) in patients with clinical burnout.

In addition to being a precursor to androgens and estrogens, DHEA-s is an active hormone with effects on its own [6]. DHEA-s has a regenerative and protective role important for maintenance and restoration of health. For example, DHEA-s enhances the activity of the body’s own antioxidant system, prevents atherosclerosis by stimulating the production of NO in the vessel and stimulates neurite growth, neurogenesis, and neural survival [6]. DHEA-s is produced in the zona reticularis area of the adrenal cortex in response to adrenocorticotrophic hormone (ACTH). The production peaks in young adulthood, thereafter the levels decline progressively [7] by 2–4% per year.

Low levels of DHEA-s have mostly been reported to be associated with, independently of age, both subjective perception of poor health [8] and different disease states [912]. We and others have previously reported that DHEA-s levels are lower in individuals reporting psychosocial stress [13, 14]. Since burnout is a consequence of long-term stress, and since it is a syndrome associated with both psychological and physiological adverse health, it would be of interest to investigate DHEA-s levels in burnout. Low DHEA-s levels in these patients could constitute one of the links between stress and adverse health associated with burnout. However, out of four previous publications on DHEA-s levels in burnout, three reported no difference between burnout subjects and controls [1517] and one publication reported higher DHEA-s levels in the individuals with burnout [18]. The present study aims to investigate DHEA-s levels in patients with clinical burnout compared to healthy controls without burnout symptoms. The relatively large sample of available patients in the study allows for separate analyses in different age groups, which is an advantage since DHEA-s is strongly age related.

Method

Participants

122 patients with clinical burnout (62 men; 60 women) and 47 healthy controls (24 men and 23 women with clear absence of burnout symptoms) in the age 25–54 years were included in the study.

The patients were recruited from a specialist clinic, which exclusively treats patients with stress-related mental disorders, in the region of Västra Götaland, Sweden. All the patients fulfilled the diagnostic criteria for stress-related exhaustion disorder as previously described [14]. Stress-related exhaustion disorder is a criteria-based diagnosis that has been used in Sweden since 2005 to define patients seeking health-care for clinical burnout. With the aim to study DHEA-s levels in these patients, selection of patients was performed among those who were between 25 and 54 years, had answered the questionnaire regarding burnout symptoms, depression and anxiety at all time-points up to one year after inclusion, thus at the initial visit and at the 3, 6 and 12 months follow up, and had available serum samples in the freezer. A total of 63 male patients fulfilled the criteria described above. Among the 141 females who fulfilled the criteria, 63 female patients were randomly selected in order to include an equal number of men and women. One of the male patients and three of the female patients had samples that were not successfully analyzed. In the present study, we report the DHEA-s levels at baseline for these 122 patients. 30% of the patients were taking antidepressants.

Blood samples and burnout scores from 198 individuals in the age 25–54 years were available from another study to be included as control subjects, which explains the age criteria for the patient group. These individuals were recruited with the aim of studying the relationship between biological markers of stress and perceived stress. Before inclusion, the subjects underwent a screening test, including anthropometric measurements and obtaining blood samples to ensure the following exclusion criteria; having a body mass index less than 18.5 kg/m2 or over 30 kg/m2, high blood pressure, infection, vitamin B–12 deficiency (high homocysteine), known systemic disease such as diabetes or thyroid disease, known psychiatric disease or alcohol abuse. Women taking estrogens as well as nursing, pregnant and postmenopausal women were not included. Subjects who were taking psychoactive medications or any medications that may affect the hypothalamus–pituitary–adrenal (HPA) axis function were not included. Among the 198 individuals available for this study to serve as control group, only individuals without symptoms of burnout identified using the Shirom-Melamed Burnout Questionnaire [1] (scores lower than 2.0) were included in the present study as controls (24 men; 23 women).

Fifteen percent of the controls and 20% of the patients were nicotine users. One of the controls and 11% of the patients had a risky high alcohol consumption according to the Alcohol Use Disorders Identification Test (AUDIT) (scores 8–15) [19]. None had scores indicating alcohol abuse (>15) since this was one of the exclusion criteria in the study from which the control subjects were drawn. Alcohol abuse according to AUDIT was also a differential diagnostic criterion for exhaustion and these patients were not accepted at the stress clinic and thus not included in this study. Both the patient group and the control group consisted of 51% men. Aiming on separate comparisons of DHEA-s between patients and controls in different ages (see statistical analyses section below), three 10-year-interval age groups were created. Age group 25–34 years included 29 patients (41% men) and 14 controls (57% men), age group 36–45 years, 49 patients (55% men) and 11 controls (46% men) and finally age group 46–54, 44 patients (52% men) and 22 controls (50% men). Time periods for recruitment were between 2004 and 2010 for the patients and between 2004 and 2008 for the controls. All participants gave written informed consent. The study was approved by the Regional Ethical Review Board in Göteborg, Sweden, and was conducted according to the Helsinki Declaration.

Hormone assay

Blood samples (in total 65.6 ml) were drawn in the morning between 7.30 and 10 from an antecubital vein. The participants had fasted overnight and were instructed to abstain from hard physical exercise for 24 hours prior to the blood sampling. The samples were collected in two different tubes; pre-chilled tubes containing EDTA and serum separator tubes. The serum separator tubes were centrifuged during 10 minutes in 20°C with a speed of 3500 rpm (with a Sigma 2–16 KC centrifuge) and the samples were thereafter stored at 80°C until assayed. Serum concentration of DHEA-s was measured by quantitative electro-chemiluminescent immunoassay (Roche Diagnostics Corporation). Inter-assay coefficient of variation was below 12%.

Statistical analyses

Pearson correlation analyses were performed between DHEA-s levels and age in the whole sample and in patients and controls separately. T-test was used to compare DHEA-s levels between men and women in the whole sample as well as in patients and controls separately. Partial correlation analyses were performed between DHEA-s levels and BMI separately in men and women, while adjusting for age. To compare DHEA-s levels between patients and controls, t-tests were performed first in the whole sample and then within each of the three age groups. In addition, the t-tests were redone without the patients that were taking antidepressants. Since drinking alcohol and smoking may affect DHEA-s levels [20, 21] the t-tests comparing DHEA-s levels between patients and controls were also performed without these individuals.

Results

DHEA-s in relation to age, sex and BMI

As expected, DHEA-s levels were negatively associated with age (total: r = -0.34, p < 0.001), although the correlation was stronger in controls than in patients (controls: r = -0.50, p <0.001; patients: r = -0.26, p = 0.004). Also as expected, DHEA-s levels were higher in males than in females (total group: 6.72 and 4.63, respectively, p < 0.001; patients: 6.52 μmol/L and 4.52 μmol/L, respectively, p < 0.001; controls: 7.23 μmol/L and 4.93 μmol/L, respectively, p = 0.004). DHEA-s levels were not associated with BMI after adjusting for age (men: p = 0.493; women: p = 0.409).

Comparisons of DHEA-s levels in patients and controls

In the youngest age group (25–34 years), DHEA-s levels were on average 25% lower in the group of the burnout patients than the controls (p = 0.006). The difference in DHEA-s levels between patients and controls were more pronounced among female than among male subjects (on average 32% and 13% lower, respectively). There were no differences in DHEA-s levels between patients and controls in the age groups 35–44 years (p = 0.927) and 45–54 years (p = 0.897). The DHEA-s levels in burnout patients and controls in the different age groups are displayed in Fig 1. When the three age groups were analysed together, there was no significant difference in DHEA-s levels between the patients and controls (5.54 vs 6.10 μmol/L, p = 0.187). Excluding the patients that were taking antidepressants did not change the results (data not shown).

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Fig 1. Mean (95% confidence intervals) DHEA-s levels in patients and controls in the three age groups.

https://doi.org/10.1371/journal.pone.0140054.g001

Since alcohol consumption and smoking may affect DHEA-s levels additional comparisons without these individuals were performed. Restricting the analyses to non-nicotine users (patients = 92, 51% men, mean age = 40.7 years; controls = 39, 51% men, mean age 40.3 years) did not change the results (data not shown). Restricting the analyses to participants without risky alcohol consumption (< 8 on AUDIT) (patients = 103, 48% men, mean age = 40.9 years; controls = 46, 50% men, mean age 40.5 years) showed a trend to lower DHEA-s levels in the patient group than in controls (p = 0.058), but otherwise the same results, thus, lower DHEA-s in patients only in the youngest age-group when analyzing age groups separately (data not shown).

Discussion

The results showed that, in the youngest group (25–35 years), DHEA-s levels were significantly lower in the patients than in the healthy controls, but among the other age groups (36–45 and 46–54 years) there were no differences in DHEA-s levels between patients and controls. When restricting the analysis to only participants without high-risk alcohol consumption, a trend to difference between patients and controls in the whole group was revealed, thus lower DHEA-s in the patients. However, this difference was still due to the large difference between patients and controls among the younger participants. It is likely that low DHEA-s levels are primarily observed in younger adults with clinical burnout since the DHEA-s levels are much higher and the inter-subject variability is larger in younger individuals. Thus, a plausible interpretation is that depressed DHEA-s levels in patients with clinical burnout are more likely among younger individuals although changes in these hormonal levels could be present even among older patients.

Four previous publications report DHEA-s level comparisons between individuals with and without burnout. These studies include both clinically diagnosed patients [16] and “high burnouts” defined using burnout scales [15, 17, 18]. Three of these studies found no difference in DHEA-s levels between burnout-subjects and controls [1517] while one study found higher DHEA-s levels in the burnout group [18]. One plausible explanation why no differences were seen between the groups in some of the previous studies could be that there were large variations in age among the study subjects. For instance, in one of the studies age ranged from 27 to 65 years [18] and in another from 19 to 59 years [16]. In the present study, the number of burnout subjects included was larger than in the previous studies. The relatively large number of patients allows for separate analyses in different age groups. Our age specific analysis revealed a difference only in the youngest age group. Low DHEA-s levels in these patients are likely an effect of long-term stress exposure. During prolonged psychosocial stress, steroid biosynthesis may be shifted from synthesis of adrenal androgens to corticosteroid pathways to ensure maintenance of cortisol production [22, 23].

There are several factors that may affect DHEA-s levels and all cannot be controlled for. This limits the interpretation of the results in this study. The well-known and important factors age and sex are controlled in this study since the participants are divided into age groups and since there is equal distribution of men and women in the groups. Factors that may affect DHEA-s levels such as alcohol consumption [21], nicotine use [20], body mass index and use of medication such as antidepressants have been taken into consideration in this study. Furthermore, many factors that could affect DHEA-s levels are also considered since they were exclusion criteria for both patients and controls. This includes diseases such as thyroid disease, obesity and alcohol abuse.

In conclusion, the present study indicates that levels of the health promoting “youth” hormone DHEA-s are low in younger burnout patients. The fact that younger adults have much higher DHEA-s levels and more pronounced inter-subject variability in DHEA-s levels than older individuals might explain why burnout status differentiates patients from controls only among the youngest. The results should be confirmed by other studies. Low DHEA-s levels in these patients could constitute one of the links between stress and adverse health associated with burnout.

Supporting Information

S1 Dataset. DHEA-s levels in clinical burnout.

https://doi.org/10.1371/journal.pone.0140054.s001

(SAV)

Acknowledgments

The research nurses Karin Nygren and Anna Palmgren performed data collection.

Author Contributions

Conceived and designed the experiments: AKL TT IHJ. Analyzed the data: AKL. Wrote the paper: AKL. Performed hormone assays: MMK. Contributed to and have approved the final manuscript: AKL MMK TT IHJ.

References

  1. 1. Melamed S, Kushnir T, Shirom A. Burnout and risk factors for cardiovascular diseases. Behavioral medicine. 1992;18(2):53–60. Epub 1992/01/01. pmid:1392214.
  2. 2. Glise K, Hadzibajramovic E, Jonsdottir IH, Ahlborg G Jr. Self-reported exhaustion: a possible indicator of reduced work ability and increased risk of sickness absence among human service workers. International archives of occupational and environmental health. 2010;83(5):511–20. pmid:19943058.
  3. 3. Peterson U, Bergstrom G, Demerouti E, Gustavsson P, Asberg M, Nygren A. Burnout levels and self-rated health prospectively predict future long-term sickness absence: a study among female health professionals. Journal of occupational and environmental medicine / American College of Occupational and Environmental Medicine. 2011;53(7):788–93. pmid:21691218.
  4. 4. Melamed S, Shirom A, Toker S, Berliner S, Shapira I. Burnout and risk of cardiovascular disease: evidence, possible causal paths, and promising research directions. Psychological bulletin. 2006;132(3):327–53. pmid:16719565.
  5. 5. Melamed S, Shirom A, Toker S, Shapira I. Burnout and risk of type 2 diabetes: a prospective study of apparently healthy employed persons. Psychosomatic medicine. 2006;68(6):863–9. pmid:17132837.
  6. 6. Traish AM, Kang HP, Saad F, Guay AT. Dehydroepiandrosterone (DHEA)—a precursor steroid or an active hormone in human physiology. The journal of sexual medicine. 2011;8(11):2960–82; quiz 83. pmid:22032408.
  7. 7. Orentreich N, Brind JL, Rizer RL, Vogelman JH. Age changes and sex differences in serum dehydroepiandrosterone sulfate concentrations throughout adulthood. J Clin Endocrinol Metab. 1984;59(3):551–5. Epub 1984/09/01. pmid:6235241.
  8. 8. Berr C, Lafont S, Debuire B, Dartigues JF, Baulieu EE. Relationships of dehydroepiandrosterone sulfate in the elderly with functional, psychological, and mental status, and short-term mortality: a French community-based study. Proc Natl Acad Sci U S A. 1996;93(23):13410–5. Epub 1996/11/12. pmid:8917605.
  9. 9. Barrett-Connor E, von Muhlen D, Laughlin GA, Kripke A. Endogenous levels of dehydroepiandrosterone sulfate, but not other sex hormones, are associated with depressed mood in older women: the Rancho Bernardo Study. Journal of the American Geriatrics Society. 1999;47(6):685–91. pmid:10366167.
  10. 10. Voznesensky M, Walsh S, Dauser D, Brindisi J, Kenny AM. The association between dehydroepiandosterone and frailty in older men and women. Age and ageing. 2009;38(4):401–6. pmid:19276095; PubMed Central PMCID: PMC2720687.
  11. 11. Ghebre MA, Hart DJ, Hakim AJ, Kato BS, Thompson V, Arden NK, et al. Association between DHEAS and bone loss in postmenopausal women: a 15-year longitudinal population-based study. Calcified tissue international. 2011;89(4):295–302. pmid:21789637; PubMed Central PMCID: PMC3175043.
  12. 12. Schell E, Theorell T, Hasson D, Arnetz B, Saraste H. Stress biomarkers' associations to pain in the neck, shoulder and back in healthy media workers: 12-month prospective follow-up. European spine journal: official publication of the European Spine Society, the European Spinal Deformity Society, and the European Section of the Cervical Spine Research Society. 2008;17(3):393–405. pmid:18075764; PubMed Central PMCID: PMC2270377.
  13. 13. Lennartsson AK, Theorell T, Rockwood AL, Kushnir MM, Jonsdottir IH. Perceived stress at work is associated with lower levels of DHEA-S. PloS one. 2013;8(8):e72460. pmid:24015247; PubMed Central PMCID: PMC3756071.
  14. 14. Jeckel CM, Lopes RP, Berleze MC, Luz C, Feix L, Argimon II, et al. Neuroendocrine and immunological correlates of chronic stress in 'strictly healthy' populations. Neuroimmunomodulation. 2010;17(1):9–18. pmid:19816052.
  15. 15. Grossi G, Perski A, Evengard B, Blomkvist V, Orth-Gomer K. Physiological correlates of burnout among women. Journal of psychosomatic research. 2003;55(4):309–16. pmid:14507541.
  16. 16. Moch SL, Panz VR, Joffe BI, Havlik I, Moch JD. Longitudinal changes in pituitary-adrenal hormones in South African women with burnout. Endocrine. 2003;21(3):267–72. pmid:14515012.
  17. 17. Langelaan S, Bakker AB, Schaufeli WB, van Rhenen W, van Doornen LJ. Do burned-out and work-engaged employees differ in the functioning of the hypothalamic-pituitary-adrenal axis? Scandinavian journal of work, environment & health. 2006;32(5):339–48. pmid:17091201
  18. 18. Mommersteeg PM, Heijnen CJ, Kavelaars A, van Doornen LJ. Immune and endocrine function in burnout syndrome. Psychosomatic medicine. 2006;68(6):879–86. pmid:17079708.
  19. 19. Bradley KA, McDonell MB, Bush K, Kivlahan DR, Diehr P, Fihn SD. The AUDIT alcohol consumption questions: reliability, validity, and responsiveness to change in older male primary care patients. Alcoholism, clinical and experimental research. 1998;22(8):1842–9. pmid:9835306.
  20. 20. Baron JA, Comi RJ, Cryns V, Brinck-Johnsen T, Mercer NG. The effect of cigarette smoking on adrenal cortical hormones. The Journal of pharmacology and experimental therapeutics. 1995;272(1):151–5. pmid:7815328.
  21. 21. Sierksma A, Sarkola T, Eriksson CJ, van der Gaag MS, Grobbee DE, Hendriks HF. Effect of moderate alcohol consumption on plasma dehydroepiandrosterone sulfate, testosterone, and estradiol levels in middle-aged men and postmenopausal women: a diet-controlled intervention study. Alcoholism, clinical and experimental research. 2004;28(5):780–5. pmid:15166654.
  22. 22. Mason JW. Organization of the multiple endocrine responses to avoidance in the monkey. Psychosomatic medicine. 1968;30(5):Suppl:774–90. Epub 1968/09/01. pmid:4974240.
  23. 23. Hechter O, Grossman A, Chatterton RT Jr. Relationship of dehydroepiandrosterone and cortisol in disease. Med Hypotheses. 1997;49(1):85–91. pmid:9247914.