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Subjective, behavioural and physiological correlates of stress in women using hormonal contraceptives

Published online by Cambridge University Press:  13 June 2025

Zoé Bürger Open the ORCID record for Zoé Bürger [Opens in a new window] ,
Charlotte Kordowich ,
Julia Kübbeler ,
Carolin Müllerschön ,
Ann-Christin S. Kimmig Open the ORCID record for Ann-Christin S. Kimmig [Opens in a new window] ,
Min Su ,
Michael Lämmerhofer ,
Julia Sacher Open the ORCID record for Julia Sacher [Opens in a new window] ,
Melanie Henes  and
Erika Comasco Open the ORCID record for Erika Comasco [Opens in a new window]
...Show all authors
Zoé Bürger
Affiliation:
Department of Psychiatry and Psychotherapy, Tübingen Center for Mental Health (TüCMH), University of Tübingen, Tübingen, Germany Department of Women’s and Children’s Health, Science for Life Laboratory, Uppsala University, Uppsala, Sweden
Charlotte Kordowich
Affiliation:
Department of Psychiatry and Psychotherapy, Tübingen Center for Mental Health (TüCMH), University of Tübingen, Tübingen, Germany
Julia Kübbeler
Affiliation:
Department of Psychiatry and Psychotherapy, Tübingen Center for Mental Health (TüCMH), University of Tübingen, Tübingen, Germany
Carolin Müllerschön
Affiliation:
Department of Psychiatry and Psychotherapy, Tübingen Center for Mental Health (TüCMH), University of Tübingen, Tübingen, Germany
Ann-Christin S. Kimmig
Affiliation:
Department of Psychiatry and Psychotherapy, Tübingen Center for Mental Health (TüCMH), University of Tübingen, Tübingen, Germany German Center for Mental Health (DZPG), Partner Site Tübingen, Tübingen, Germany
Min Su
Affiliation:
Department of Pharmacy and Biochemistry, Institute of Pharmaceutical Sciences, Pharmaceutical (Bio-)Analysis, University of Tübingen, Tübingen, Germany
Michael Lämmerhofer
Affiliation:
Department of Pharmacy and Biochemistry, Institute of Pharmaceutical Sciences, Pharmaceutical (Bio-)Analysis, University of Tübingen, Tübingen, Germany
Julia Sacher
Affiliation:
Cognitive Neuroendocrinology, Max Planck Institute for Human Cognitive and Brain Sciences, Leipzig, Germany Clinic of Cognitive Neurology, University of Leipzig, Leipzig, Germany Center for Integrated Female Health and Gender Medicine, Medical Faculty, University of Leipzig, Leipzig, Germany Medical Department III – Endocrinology, Nephrology, Rheumatology, University of Leipzig, Leipzig, Germany
Melanie Henes
Affiliation:
Department of Women’s Health, University of Tübingen, Tübingen, Germany
Erika Comasco
Affiliation:
Department of Women’s and Children’s Health, Science for Life Laboratory, Uppsala University, Uppsala, Sweden
Birgit Derntl*
Affiliation:
Department of Psychiatry and Psychotherapy, Tübingen Center for Mental Health (TüCMH), University of Tübingen, Tübingen, Germany LEAD Graduate School & Research Network, University of Tübingen, Tübingen, Germany German Center for Mental Health (DZPG), Partner Site Tübingen, Tübingen, Germany
Lydia Kogler
Affiliation:
Department of Psychiatry and Psychotherapy, Tübingen Center for Mental Health (TüCMH), University of Tübingen, Tübingen, Germany German Center for Mental Health (DZPG), Partner Site Tübingen, Tübingen, Germany
*
Correspondence: Birgit Derntl. Email: birgit.derntl@med.uni-tuebingen.de.
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Abstract

Background

Stress, a major risk factor for mental health problems, is influenced by hormonal fluctuations from the menstrual cycle and hormonal oral contraceptives (OC). Despite widespread use, the impact of hormonal intrauterine devices (IUDs) on stress is limited to one study.

Aims

This study examines psychoendocrine stress responses in women using IUDs, OCs and women with a natural, regular menstrual cycle (NC) to better understand how endogenous and exogenous hormones influence stress.

Method

Using a repeated-measures design, we investigated stress responses in IUD and OC users and NC women. The Maastricht Acute Stress Task and its control task were applied twice within 4 months to assess subjective, endocrine and physiological stress correlates. Detailed endogenous and exogenous hormonal profiles were obtained, and women completed a 7-day diary (via ecological momentary assessment) after each appointment.

Results

Based on subjective, physiological and cortisol responses, stress induction was successful in all groups. IUD users reported higher subjective stress, negative affect and anxiety and lower positive affect compared to NC women. OC users exhibited a blunted cortisol response and higher heart rate but reported less acute stress and negative emotions than the other groups in the 7-day diary. Oestradiol and progesterone were suppressed in OC and IUD users compared with NC women. Progesterone, testosterone and oestradiol were differently associated with skin conductance, socio-emotional stress and negative affect.

Conclusions

IUD and OC use distinctly affect stress response, possibly because of their diverging metabolic pathways and hormone levels. IUD users showed higher emotional reactivity to stress in both lab and daily life, while OCs influenced physiological correlates. These findings highlight that exogenous hormone administration, previously thought to have limited systemic effects, affects women’s psychological well-being, underscoring the need for further research into stress-related disorders among women using hormonal contraceptives.

Keywords

Stresshormonesintrauterine devicehormonal contraceptionmenstrual cycle

Information

Type
Original Article
Information
The British Journal of Psychiatry , Volume 226 , Special Issue 6: Themed issue: Psychiatric Symptoms on the Ovarian Hormone Roller Coaster , June 2025 , pp. 392 - 400
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Creative Commons
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://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), 2025. Published by Cambridge University Press on behalf of Royal College of Psychiatrists

Facing stressful situations is a natural part of life, and physical and emotional responses to these stressors shape the overall stress response. Sex and gender differences have been reported for stress responses, with sex hormones potentially playing a significant role. Reference Heck and Handa1 Two important pathways for the stress response are the hypothalamic–pituitary–adrenal (HPA) axis and the autonomic nervous system (ANS). While the latter is a rapid response system, upregulating bodily activity to prepare for potential threats (e.g. through increased cardiac output Reference Smeets, Cornelisse, Quaedflieg, Meyer, Jelicic and Merckelbach2 ), the HPA axis reacts more slowly, releasing cortisol, which typically peaks within 20–30 minutes after stress onset. Reference Spencer and Deak3 The hypothalamic–pituitary–gonadal (HPG) axis, responsible for regulating sex hormones, is closely connected to the HPA axis and can influence its activity. Reference Heck and Handa1 Not only do cortisol responses vary throughout the menstrual cycle, Reference Kirschbaum, Kudielka, Gaab, Schommer and Hellhammer4 but women using (combined) oral contraceptives (OCs) show a blunted cortisol response compared to natural, regular menstrual cycle (NC) women in the luteal phase, according to a meta-analysis of 14 studies involving over 1000 participants. Reference Gervasio, Zheng, Skrotzki and Pachete5 Despite the relevance of stress for women’s mental health, research on stress, hormonal transitions and hormonal contraception remains scarce, especially concerning methods other than OCs, such as hormonal intrauterine devices (IUDs). Although IUDs are used by millions of women worldwide, 6 only one study has investigated stress responses in women using IUDs so far. Contrary to the blunted cortisol in women using OCs, women using IUDs showed a highly potentiated cortisol response to acute stress and a heightened heart rate. Reference Aleknaviciute, Tulen, De Rijke, Bouwkamp, van der Kroeg and Timmermans7 Altered stress processing, as observed in IUD users, could affect several physiological and psychological outcomes including emotion regulation and mood. Reference Heck and Handa1 While women with IUDs show altered emotion regulation processes, Reference Zelionkaitė, Gaižauskaitė, Uusberg, Uusberg, Ambrasė and Derntl8 findings on mood effects have been inconsistent (as shown in two reviews Reference Bürger, Magdalena Bucher, Comasco, Henes, Hübner and Kogler9,Reference Elsayed, Dardeer, Khehra, Padda, Graf and Soliman10 ). Recent research suggests an increased risk for depression and a higher likelihood of antidepressant prescription among IUD users, Reference Stenhammar, Wikman, Gemzell Danielsson, Kopp-Kallner and Sundström Poromaa11 particularly at higher hormone doses. Reference Larsen, Mikkelsen, Ozenne, Munk-Olsen, Lidegaard and Frokjaer12

Importantly, the differences in stress responses between hormonal contraception methods may stem from variations in hormone composition and metabolic pathways. Combined OCs contain both ethinyl oestradiol (EE) and a progestin, while IUDs contain only the progestin levonorgestrel (LNG). OCs undergo hepatic first-pass metabolism, whereas LNG from IUDs directly enters the bloodstream through the uterine lining. This difference allows IUDs to achieve similar (contraceptive) efficacy with a lower hormone dose than OCs. However, LNG levels are rarely assessed in women using IUDs and OCs, and the interactions between hormone concentrations, both endogenous and exogenous, and stress responses, remain largely unexplored, despite the great need to better understand women’s increased vulnerability to stress-related disorders such as depression and anxiety. Here the assessment of endogenous and exogenous hormones may provide insight into mechanistic actions. Further, investigating how variations in hormonal composition and delivery methods influence different dimensions of the stress response (i.e. stress correlates) is needed.

In the present study, we therefore compared subjective, endocrine and physiological stress responses among women with different hormonal status: women using IUDs, women using OCs and NC women in the luteal phase. An acute psychosocial stress induction paradigm was implemented within a longitudinal design to assess intra-individual variability in stress responses over several months. Following stress induction, we expected (a) a potentiated cortisol response in women using IUDs and a blunted response in women using OCs, Reference Aleknaviciute, Tulen, De Rijke, Bouwkamp, van der Kroeg and Timmermans7 and (b) a higher heart rate in women using IUDs. Reference Aleknaviciute, Tulen, De Rijke, Bouwkamp, van der Kroeg and Timmermans7 Regarding group differences for subjective stress (including the 7-day diary) and skin conductance, as well as the direct impact of exogenous hormone concentrations, we had no directed a priori hypotheses because of lacking and inconsistent data in the existing literature.

Method

Participants

Healthy premenopausal women aged 18–40 years were recruited using flyers in gynaecological practices and email services of the University of Tübingen. We recruited three groups of women: (a) women using the LNG-IUD (IUD, n = 27), (b) women using OCs (n = 30) and (c) NC women (n = 29). Based on a priori power analyses (three groups, two measurement timepoints, error rate of 0.5, power of 0.95) and accounting for participants possibly dropping out, we aimed to recruit 25 women/group completing both timepoints. Reference Faul, Erdfelder, Lang and Buchner13 The women used their respective method for birth control for at least 6 months; details on the hormonal contraception are found in Supplement Table S1 available at https://doi.org/10.1192/bjp.2025.7. As all participants in our study were of female sex and identified as cisgender, we use the term ‘women’ throughout this paper when referring to our sample. Reference Heidari, Babor, De Castro, Tort and Curno14,15 A detailed description of inclusion and exclusion criteria can be found in the supplement. All women gave written informed consent. 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 2013. All procedures involving human participants were approved by the University Hospital of Tübingen (approval 067/2020).

Study design

After a screening session to check inclusion and exclusion criteria, participants came in twice within 4 months (121 ± 37.4 days, timepoints T1 and T2) to assess intra-individual variability. They followed a strict protocol 24 h before each appointment to control influences on stress response, including refraining from caffeine consumption, exercise, etc. (Fig. 1 provides a description). Appointments were scheduled on weekday afternoons to account for diurnal cortisol fluctuations. Participants underwent the Maastricht Acute Stress Task (MAST Reference Smeets, Cornelisse, Quaedflieg, Meyer, Jelicic and Merckelbach2 ) and its non-stressful control (placebo) in a counterbalanced order (Supplement Table S6), with relaxation periods in between (for details on the MAST, see supplement). Cortisol/cortisone, subjective mood, heart rate, skin conductance and steroid hormones in blood were measured at specific times during the sessions (Fig. 1). The second timepoint T2 was identical to the first, with the exception that the task presentation order was reversed.

Fig. 1

Detailed study design of one measurement day (T1), repeated after approximately 4 months (T2). Participants had to forgo taking medication in the 24 h prior to the appointment, refrain from consuming caffeine or exercising 3 h before, and from food and drinks, except water, for 1 h prior to testing. All appointments were scheduled on weekdays, starting between 13.00 h and 14.00 h. In the first 30 min after arrival, participants filled out self-report questionnaires. After applying electrodes for skin conductance and pulse-oximeter for heart rate measures, participants gave the first saliva sample, then underwent a 40 min relaxation phase watching non-arousing documentaries. A second saliva sample was given with a short subjective mood questionnaire. In a randomised fashion, either the stress or placebo task of the MAST was applied, followed by another saliva sample and subjective mood questionnaire. During a second 40 min relaxation phase, saliva was collected 15 min after the previous sample. Participants underwent the second part of the MAST (stress or placebo), and before and after, a saliva sample and a subjective mood questionnaire was collected. Participants watched a final 40 min relaxing documentary, and saliva samples were collected at 15 min and 40 min post-task. For 7 days, a daily mood and stress diary was filled out (7-day diary via ecological momentary assessment (EMA)). The second measurement day had the same timeline, was counter-balanced for task order (Supplement Table S2 for details) and was scheduled on average 4 months after the first time point. Created with BioRender.com. IUD, intrauterine device.

General self-report questionnaires

Demographic information and questionnaire data assessing depressive symptoms (Beck Depression Inventory-II (BDI-II) Reference Kühner, Bürger, Keller and Hautzinger16 ), trait anxiety (State-Trait Anxiety Inventory - Trait version (STAI-T) Reference Laux17 ), childhood trauma (Childhood Trauma Questionnaire (CTQ) Reference Wingenfeld, Spitzer, Mensebach, Grabe, Hill and Gast18 ) and life stressors (Life Stressor Checklist-Revised (LSC-R) Reference Ungerer, Deter, Fikentscher and Konzag19 ), overall quality of life (World Health Organisation Quality of Life (WHOQOL) Reference Angermeyer, Kilian and Matschinger20 ) and stress- and hormonal status-related questionnaires were collected to assess and control for between-group inhomogeneity and exclude influences other than hormonal contraception use (see supplement).

Task-related subjective stress and affect

Before and after each task, participants completed self-report questions (Presentation® Version 23.0, used in Windows; Neurobehavioral Systems, Inc., Berkeley, CA, USA; www.neurobs.com) assessing subjective stress (visual-analogue scale: from not at all stressed to extremely stressed), affect (Positive and Negative Affect Schedule (PANAS) Reference Krohne, Egloff, Kohlmann and Tausch21 ), state anxiety (State-Trait Anxiety Inventory - State version (STAI-S) Reference Laux17 ) and emotions (emotional self rating (ESR) Reference Schneider, Gur, Gur and Muenz22 ) (see supplement).

Steroid hormones in plasma and salivary cortisol/cortisone

Plasma obtained from blood drawn at the end of each measurement day was analysed at the Institute of Pharmaceutical Sciences, University of Tübingen, Germany. Liquid chromatography-tandem mass spectrometry (LC-MS/MS) was used to determine hormone levels of testosterone, progesterone, oestradiol and cortisol, as well as EE and LNG, among others (see supplement). Saliva samples were collected using a synthetic fibre swab (Salivette® Cortisol, Sarstedt, Nümbrecht, Germany) and analysed at the Institute of Pharmaceutical Sciences, University of Tübingen. Salivary cortisol and cortisone were determined by a micro-flow liquid chromatography-mass spectrometry assay. Reference Aydin, Drotleff, Noack, Derntl and Lämmerhofer23

Detailed analysis procedures for plasma and saliva are described in the supplement.

Physiological stress

Heart rate and skin conductance were recorded using a BIOPAC MP160 (Biopac Systems, Inc., Goleta, CA, USA). For detailed recording and processing methods, see the supplement.

Seven-day diary (ecological momentary assessment)

After both measurement days, participants filled in a 7-day diary each evening, starting the day after the measurement, containing questionnaires pertaining to their well-being (PANAS, Reference Krohne, Egloff, Kohlmann and Tausch21 STAI-T, Reference Laux17 ESR Reference Schneider, Gur, Gur and Muenz22 ) and various stressors they might have encountered each day (Supplement Table S7).

Statistical analysis

Data analysis, visualisation and statistics were done using RStudio (version 2023.9.1.494, used in Windows; Posit Software, PBC, Boston, MA, USA; R version 4.3.1); the packages are described in the supplement.

For the sample description, univariate analyses of variance (ANOVAs) with the between-subject factor group (IUD/OC/NC) were performed. All other variables were analysed using linear mixed models (LMMs) with a random intercept for each subject. Assumptions were checked and outliers identified via Cook’s distance; models excluding outliers are reported. When the main predictor group was included, models were run twice, with different reference groups: NC or IUD. The second model with IUD as the reference group was used to ascertain effects within hormonal contraception (i.e. IUD versus OC) and only effects pertaining to this difference were extracted from the second model.

Steroid hormones in plasma

Plasma levels of steroid hormones were measured in picogram per millilitre and converted to nanomole per litre (nmol/L), then log-transformed for statistical analysis, except for oestradiol, which was approximately normally distributed. Hormones were analysed with LMMs using the between-subjects factor group and the within-subject factor timepoint (T1/T2).

Salivary cortisol and cortisone

For analysis, cortisol and cortisone levels were transformed from ng/mL to nmol/L and the area under the curve with regard to increase (AUCi, Reference Pruessner, Kirschbaum, Meinlschmid and Hellhammer24 reference: second saliva sample; three timepoints of 15, 30 and 55 min after task onset) was calculated for each participant and each task separately. In addition, the cortisol-to-cortisone ratio was calculated. LMMs with the between-subjects factor group and the within-subject factors task (placebo/MAST) and timepoint (T1/T2) and the interaction group-by-task were fitted.

Task-related subjective stress and affect

Ratings were measured before and after both the MAST and placebo task and the pre-values were added as continuous within-subject factor to account for baseline variations, with the post-values as dependent variable. The between-subjects factor group and the within-subject factors task (placebo/MAST) and timepoint (T1/T2) and the interaction group-by-task were added.

Physiological stress

Mean heart rate during stress and placebo tasks, the frequency of skin conductance responses (SCRs), tonic mean values and a global mean representing both phasic and tonic components of skin conductance were used as dependent variables, with the between-subjects factor group and the within-subject factors task (placebo/MAST) and timepoint and the interaction group-by-task.

Seven-day diary

The area under the curve (AUC) Reference Pruessner, Kirschbaum, Meinlschmid and Hellhammer24 over the 7 days was computed for each question and used as a dependent variable in the LMMs. The between-subjects factor group and the within-subject factor timepoint (T1/T2) were used.

Exploratory hormone associations with stress correlates

Additional exploratory analyses were performed to assess whether sex hormones were predictive of stress correlates or 7-day diary-variables. We ran LMMs for all stress correlates, using only the stress and not placebo data, and significant 7-day diary variables, separated by group and sex hormones (as they were highly correlated). Models for oestradiol, progesterone and testosterone were run in all three groups, and additionally LNG models in IUD and OC users, and EE models in OC users. Timepoint was added as an additional factor but regarded as a covariate-of-no-interest in these analyses, as timepoint effects are already reported. To account for multiple testing in these exploratory analyses, false-discovery-rate (FDR) correction was applied within each group for each stress correlate separately (e.g. correction in women using IUDs for cortisol AUCi).

Results

Study population

Groups were comparable in age, depression score and trait anxiety at screening and chronic and perceived stress as well as further measures at timepoint T1 (see Supplement Table S2). However, life stressors weighted by affect within the past year were higher in women using IUDs than NC women (post hoc: t(83) = 2.59, p bonferroni = 0.034, η Reference Smeets, Cornelisse, Quaedflieg, Meyer, Jelicic and Merckelbach2 = 0.08), although the number of life stressors experienced did not differ between groups (p = 0.420). To better characterise the groups, we compared baseline endogenous and exogenous sex hormone and cortisol levels in blood. For oestradiol and progesterone, NC women had the highest plasma concentrations, followed by IUD users, with OC users having the lowest concentrations (all ps < 0.026; Fig. 2; Supplement Table S3 for full statistics). Plasma cortisol showed the reverse pattern, with OC users having higher levels of cortisol compared with the other two groups (all ps < 0.001). Testosterone levels did not differ between the groups (p > 0.0662). LNG was significantly higher in OC users compared with IUD users (p < 0.001). Further, timepoint effects could be seen for testosterone, progesterone and LNG, with higher values at the second timepoint compared with the first (all ps < 0.002). Hormonal levels in our sample were consistent with those reported in previous studies examining hormonal levels in OC users and NC women Reference Kimmig, Wildgruber, Gärtner, Drotleff, Krylova and Lämmerhofer25,Reference Rodriguez, Casey, Crossley, Williams and Dhaher26 and with normative ranges (Supplement Table S4).

Fig. 2

Endogenous and exogenous hormone levels in plasma across IUD users (dark blue), OC users (light blue) and NC women (grey) for both measurement timepoints (T1: first measurement; T2: ca. 4 months later; only task presentation order was switched). Sample sizes for T1 (IUD/OC/NC): Oestradiol: 27/13/29; Progesterone, Testosterone, Cortisol: 27/30/29; Levonorgestrel: 27/17/0; Ethinyl Oestradiol: 0/29/0. * indicates significance at P = 0.05. Created with BioRender.com. nmol/L, nanomole per litre; IUD, intrauterine device; OC, oral contraceptive; NC, natural, regular menstrual cycle.

Successful stress induction

Stress induction was successful across multiple correlates of stress. Across all groups, negative affect, subjective stress and anxiety were higher after stress than after placebo (respectively: b = 0.57; b = 40.07; b = 12.12; all ps < 0.001; Figs. 3(a) and 3(b)). Cortisol response showed increased AUCi for stress, indicating higher cortisol values after stress induction compared with placebo (b = 103.23, p < 0.001). Physiologically, mean heart rate and all skin conductance measures increased during stress compared with placebo (mean heart rate: b = 6.27; SCR frequency: b = 5.18; tonic: b = 1.79; global: b = 1.98; all ps < 0.001).

Fig. 3

Stress correlates across IUD users (dark blue), OC users (light blue) and NC women (grey) for both measurement timepoints (T1 first measurement; T2 four months later). Top: subjective affect after placebo versus stress. (a) negative affect and (b) subjective stress. Bottom: physiological stress correlates. (c) cortisol response during stress task, stress onset at time 0, dots and bars indicate mean and s.e. (d) mean heart rate (HR) during placebo versus stress. * indicates significance at P = 0.05. Created with BioRender.com. IUD, intrauterine device; OC, oral contraceptive; NC, natural, regular menstrual cycle; nmol/L, nanomole per litre; HR, heart rate.

Repeated measures matter for the ANS but not cortisol or subjective stress

We assessed stress correlates twice across all women to assess intra-individual variability in stress responses over several months. From the first to the second timepoint (T1 to T2), only the task presentation order was reversed (Fig. 1). We found that repeated measures did not change subjective nor cortisol stress response (all ps > 0.101). Physiological stress response was affected by timepoint in all groups, as mean heart rate decreased from T1 to T2 (b = −2.55, p < 0.001; 95%CI and t-values in supplement). A similar pattern emerged for skin conductance, with lower frequency of SCRs and lower tonic and global skin conductance at the second timepoint compared with the first (respectively: b = −1.53, b = −1.88, b = −1.94; all ps < 0.001).

Subjective stress altered in IUD users versus cortisol in OC users

Following stress induction, IUD users reported lower positive affect and higher negative affect, subjective stress and anxiety than NC women (respectively: b = −0.37, p = 0.008; b = 0.43, p < 0.001; b = 13.28, p = 0.003; b = 7.40, p = 0.003; Figs. 3(a) and 3(b)). In addition, negative affect was higher in IUD users than in OC users (b = −0.31, p = 0.009). IUD users did not differ from OC users for positive affect, subjective stress or anxiety (all ps > 0.758).

OC users compared with both other groups showed a blunted salivary cortisol response, with lower AUCi in the stress task (NC versus OC: b = −80.14, p = 0.007; OC versus IUD: b = −62.54; p = 0.033, Fig. 3(c), supplement Fig. S1). IUD users did not differ from NC women in their cortisol AUCi (p > 0.412). Cortisone AUCi and the cortisone-to-cortisol-ratio AUCi revealed the same pattern as cortisol AUCi (Supplement Figs. S2 and S3). Further, OC users exhibited a higher mean heart rate compared to NC women during both stress and placebo tasks (b = 6.52, p = 0.018). No group differences were found for any of the skin conductance measures (all ps > 0.113).

Seven-day diary shows lower negative affect and stress in OC users

In the week following the lab visits, OC users reported lower levels of negative affect, negative emotions, acute work stress, anger and sadness than IUD users (all ps < 0.023; see Supplement Table S5 for full statistics) and fewer negative emotions and less acute socio-emotional stress than NC women (all ps < 0.023). No other assessed 7-day diary variable emerged as significant.

Sex hormones affect stress response

We conducted exploratory analyses to investigate whether levels of sex hormones at the two timepoints could predict stress correlates and 7-day diary outcomes. Across all groups, progesterone negatively predicted tonic skin conductance and global mean skin conductance, although this was only significant in NC women (respectively: b = −0.52, p FDR values = 0.031; b = −0.54, p FDR values = 0.034, Fig. 4(a), see supplement for full statistics). For the 7-day diary variables that showed significant group differences, associations with sex hormones emerged. In NC women, testosterone was positively associated with acute socio-emotional stress (b = 37.34, p FDR = 0.0456), which, however, was not the case for the other two groups (IUD: b = −28.07, p = 0.202; OC = −20.79, p = 0.37; Fig. 4(b)). In IUD users, oestradiol negatively predicted negative affect (b = −3.38, p fdr = 0.01). In OC users, this association was also negative but not significant (b = −0.69, p = 0.839), while in NC women, it was slightly positive (b = 0.79, p = 0.491), although not significant (Fig. 4(c)). No other association between the endogenous and exogenous (LNG, EE) sex hormones and the stress correlates or 7-day diary variables emerged (all ps > 0.05).

Fig. 4

Sex hormone associations with stress correlates and 7-day diary across IUD users (dark blue), OC users (light blue) and NC women (grey) for both measurement timepoints (T1 first measurement; T2 four months later). (a) progesterone predicting tonic skin conductance, significant only for NC women but not IUD users or OC users. (b) testosterone positively predicts acute socio-emotional (soc.-emo) stress in 7-day diary among NC women but not IUD users or OC users. (c) oestradiol negatively predicts negative affect in 7-day diary among IUD users, but not OC users or NC women. Created with BioRender.com. soc.-emo., socio-emotional; IUD, intrauterine device; OC, oral contraceptive; NC, natural, regular menstrual cycle; AUC, area under the curve.

Discussion

The present study investigated multidimensional stress responses in women using hormonal IUDs and OCs and NC women in the mid-luteal phase at two timepoints. To the best of our knowledge, it is the first study to investigate the association between IUD use and stress responses in a repeated manner, while also assessing exogenous hormone levels. Stress was successfully induced in all groups of women, as indicated by subjective ratings, cortisol and cortisone responses, heart rate and skin conductance. Women using hormonal contraceptives differed on distinct dimensions in comparison to NC women: IUD users exhibited elevated subjective stress, negative affect and anxiety and lower positive affect compared with NC women. OC users showed a blunted salivary cortisol and cortisone response to stress compared to both other groups and a stress-independent heightened heart rate. Using the 7-day diary, OC users reported less acute stress and fewer negative emotions than either IUD users or NC women.

Increased emotional but not physiological stress response in IUD users

Women using IUDs reported higher negative affect after stress induction than the other two groups, and more subjective stress and anxiety and lower positive affect after stress than NC women, indicating an increased negative response to stress. This trend continued in the 7-day diary, in which IUD users reported more negative affect and emotions, acute work stress, anger and sadness than OC users. Women using IUDs also reported the highest current affect of life stressors, although they did not experience more life stressors than the other groups. Hence, our data suggest that IUD users have a higher emotional reactivity following stress induction both in the laboratory and in their daily lives over the following days. IUD users seem to have a higher subjective susceptibility to stressors and report a more negative stress experience compared with NC women and OC users. Zelionkaitė et al Reference Zelionkaitė, Gaižauskaitė, Uusberg, Uusberg, Ambrasė and Derntl8 found that IUD users, compared with OC users and NC women, showed a higher N2 amplitude in event-related potentials (ERPs) when instructed to upregulate negative emotions, suggesting greater recruitment of attention and cognitive control. This increased engagement during emotion regulation may also contribute to increased subjective stress in IUD users in our study. Notably, this heightened emotional response is not reflected in any of the physiological parameters, including the cortisol and cortisone responses. This contrasts with the only other study that investigated stress responses in women using IUDs: Aleknaviciute et al Reference Aleknaviciute, Tulen, De Rijke, Bouwkamp, van der Kroeg and Timmermans7 reported a potentiated cortisol response and increased heart rate in IUD users compared to NC women and copper IUD users. These discrepancies might be explained by a dose–response relationship, as the previous study only included women using the high-dose IUD. Our sample consisted mainly of women using lower-dose preparations, with only one participant using the high-dose IUD (Supplement Table S1). Presumably, the higher dosage of LNG could lead to a higher cortisol response. In line with this, results from a recent Danish registry study showed a higher risk of antidepressant prescription with the high-dose compared to the low-dose LNG-IUD. Reference Larsen, Mikkelsen, Ozenne, Munk-Olsen, Lidegaard and Frokjaer12 In addition, women who use progestin-only OCs (which contain higher concentrations of progestins than IUDs) seem at higher risk of mental health symptoms than women who do not use them, Reference Kraft, Rojczyk, Weiss, Derntl, Kikinis and Croy27 suggesting that progestin-only hormonal contraceptives need to be investigated, taking into account their dosage.

Blunted cortisol, lower 7-day diary stress but increased heart rate in women using OCs

Women using OCs in our sample exhibited a blunted cortisol and cortisone stress response, as previously indicated. Reference Gervasio, Zheng, Skrotzki and Pachete5,Reference Aleknaviciute, Tulen, De Rijke, Bouwkamp, van der Kroeg and Timmermans7 Interestingly, OC users also had the highest serum cortisol levels. This paradox can be explained by the role of cortisol binding globulin (CBG), which is increased by EE and binds free cortisol. Reference Kumsta, Entringer, Hellhammer and Wüst28 Consequently, the blunted cortisol response in OC users may result from the binding of cortisol by CBG, rendering it inactive and undetectable in saliva, while serum measures reflect both bound and unbound cortisol. When controlling for CBG levels, total serum cortisol did not significantly differ among women using IUDs, OCs and NC women after adrenocorticotropic hormone (ACTH) administration. Reference Aleknaviciute, Tulen, De Rijke, Bouwkamp, van der Kroeg and Timmermans7 Thus, assessing CBG levels in future hormonal contraception studies is essential to better understand how hormonal contraceptives affect stress responses.

The stress-independent heart rate increase among OC users aligns with data indicating a slightly higher heart rate with OC use in 24-h measurements. Reference Reinberg, Touitou, Soudant, Bernard, Bazin and Mechkouri29,Reference Cagnacci, Ferrari, Napolitano, Piacenti, Arangino and Volpe30 EE is known to increase angiotensin II, leading to increased blood pressure Reference Oelkers31 and possibly affecting heart rate. Reference Cagnacci, Zanin, Napolitano, Arangino and Volpe32 Contrary to the increased physiological responses, women using OCs reported the lowest negative emotions, acute work and socio-emotional stress in the 7-day diary compared with the two other groups. The assessment of NC women in their premenstrual phase and differing hormonal environments may explain these differences, with OC use presumably stabilising mood in daily life. Reference Oinonen and Mazmanian33

Endogenous and exogenous sex hormones influence stress responses

This study is the first to report on both exogenous and endogenous hormones in relation to the stress response. Few studies have examined exogenous hormones and affect processing, Reference Kimmig, Wildgruber, Gärtner, Drotleff, Krylova and Lämmerhofer25,Reference Kimmig, Friedrich, Drotleff, Lämmerhofer, Sundström-Poromaa and Weis34Reference Brouillard, Davignon, Turcotte and Marin36 although the hormonal contraception literature suggests interactions of exogenous and endogenous sex hormones with stress. Reference Gervasio, Zheng, Skrotzki and Pachete5 Our exploratory analyses for exogenous and endogenous hormones revealed no direct association of the exogenous (EE, LNG) hormones with stress correlates or 7-day diary variables. Progesterone negatively predicted skin conductance during acute stress, consistent with its role in reducing postmenopausal symptoms such as night sweats. Reference Prior37 Nevertheless, a positive correlation with skin conductance during exposure to negative images found in another study Reference Gamsakhurdashvili, Antov and Stockhorst38 suggests a complex relationship potentially influenced by cyclical variations in bound progesterone. Reference Evans39 Testosterone was positively predictive for acute socio-emotional stress in the 7-day diary among NC women, suggesting a link with social competition, Reference Casto and Edwards40 whereas oestradiol negatively predicted negative affect in the 7-day diary among IUD users, potentially indicating a protective effect of oestradiol on mood through modulation of and interaction with various neurotransmitter pathways. Reference Lokuge, Frey, Foster, Soares and Steiner41,Reference Del Río, Alliende, Molina, Serrano, Molina and Vigil42

In our sample, exogenous hormones were EE for OC users and the progestin LNG for IUD users and more than half of OC users. As our data show, the use of exogenous hormones affects endogenous hormone levels (Fig. 2). Oestradiol and progesterone were differently suppressed in OC and IUD users when compared with NC women. EE can upregulate sex hormone binding globulin (SHBG) (binding oestrogens and androgens Reference Iqbal, Dalton and Sawers43 ) and CBG (binding cortisol and progesterone Reference Dunn, Nisula and Rodbard44 ) as well as progesterone receptors, providing more progesterone receptors for circulating progesterone to act upon. Reference Sundström-Poromaa, Comasco, Sumner and Luders45 Progestins can bind to progesterone receptors and other steroid receptors and competitively inhibit or activate them to different extents. Reference Birkhäuser46 Importantly, serum endogenous hormone levels reflect both bound (to SHBG/CBG) and unbound quantities Reference Iqbal, Dalton and Sawers43 and exogenous hormones can be bound with varying affinities, highlighting the need to measure SHBG and CBG levels in future stress research. These explanations illustrate how hormonal contraception effects on stress result from a complex interaction of both endogenous and exogenous sex hormones and their bioavailability.

Although direct associations of stress correlates with exogenous hormones were not found in our sample, the inclusion of both endogenous and exogenous hormones may elucidate the interaction of sex hormones with the HPA axis and stress processing brain areas with high steroid receptor densities Reference McEwen and Milner47 that influence stress response. The differential effects of combined exogenous hormone administration on endogenous hormone levels and stress in our data suggest systemic and mechanistic influences that warrant further investigation. In addition, individual physiological and subjective sensitivities to sex hormone variations may explain the observed differences in stress responses and should be considered in future research.

Methodological considerations

As strengths, the current study assessed multiple stress correlates to disentangle the impact of hormonal contraception on cortisol and cortisone and physiological and subjective stress responses, as well as their association with exogenous and endogenous sex hormones. The longitudinal study design (two repeated measurements) confirmed the robustness of stress responses, specifically cortisol and subjective stress. Physiological measures of heart rate and skin conductance are more susceptible to habituation, which has also been shown previously for heart rate, Reference Bullock, MacLean, Santander, Boone, Babenko and Dundon48 and should be considered in future research. Levels of testosterone, progesterone and LNG were higher at the second timepoint, which is to be expected, as sex hormones have high inter-individual variability Reference Schmalenberger, Tauseef, Barone, Owens, Lieberman and Jarczok49 and anticipation of a challenging situation may lead to higher testosterone levels Reference Khosravi, Kogler, Khosrowabadi, Hashemi, Derntl and Heysieattalab50 at the second measurement.

Future research should consider analyses based on the classification of progestins, taking into account their (anti-)estrogenic and androgenic properties. Reference Birkhäuser46,Reference Dickey51 The sample size of our study limited such analyses but assessing the steroid receptor affinity of different progestins may clarify the effects of hormonal contraception on stress responses. Because of irregular bleeding, determination of the cycle phase in IUD users was not feasible and potentially introduced additional variability into the data, as most women using IUDs still ovulate. Reference Xiao, Zeng, Wu, Sun and Xiao52 In addition, LNG-IUDs are often chosen by women with gynaecological and/or mood-related problems (e.g. endometriosis, menorrhagia, adverse effects of oral contraceptive use Reference Bürger, Magdalena Bucher, Comasco, Henes, Hübner and Kogler9 ). Although we excluded women with known mental health or gynaecological disorders, subclinical or undiagnosed symptoms could confound our results. Therefore, future research should not only assess the reason for use and cycle phase in IUD users but also extend this research to clinical populations. Reference Bale and Epperson53

Our sample consisted of heterosexual, cisgender women (students from Germany). To generalise the results to a broader, more diverse population, future studies should include a more diverse sample.

Implications

In this study, stress responses were repeatedly assessed in women using hormonal IUDs and OCs and NC women. The results indicate that IUDs and OCs affect stress responses differently, providing initial insights into the mechanisms of exogenous, locally administered, sex hormones. Women using IUDs were more susceptible to subjective stress without alterations in cortisol response, whereas women using OCs showed a blunted salivary cortisol stress response but stress-independent higher levels of serum cortisol and heart rate. The increased susceptibility to stress and negative mood in IUD users warrants further investigation, especially in light of recent reports of associations between IUD use and depression. Reference Stenhammar, Wikman, Gemzell Danielsson, Kopp-Kallner and Sundström Poromaa11,Reference Larsen, Mikkelsen, Ozenne, Munk-Olsen, Lidegaard and Frokjaer12 Future research should explore the vulnerabilities related to natural hormonal fluctuations and the oral and intrauterine administration of exogenous hormones. This research could clarify the higher prevalence rates of stress-related disorders such as depression and anxiety in women using hormonal contraceptives.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1192/bjp.2025.7

Data availability statement

The data, analytic code and research material that support the findings of this study are available from the corresponding author, B.D., upon reasonable request.

Acknowledgements

The authors thank Emmy Hofmeister, cand. med. of the University Clinic Tübingen, Tübingen, Germany, for providing support for data collection. All figures were created using BioRender.com.

Author contributions

Z.B.: conceptualisation, funding acquisition, project administration, methodology, supervision, visualisation, data curation, investigation, formal analysis, writing – original draft; C.K.: formal analysis, writing – review and editing, investigation; J.K.: writing – review and editing, investigation; C.M.: formal analysis, writing – review and editing, investigation; A.-C.S.K.: formal analysis, software, writing – review and editing; M.S.: writing – review and editing, resources, methodology; M.L.: writing – review and editing, resources, methodology; J.S.: funding acquisition, writing – review and editing; M.H.: supervision, writing – review and editing; E.C.: supervision, writing – review and editing; B.D.: funding acquisition, project administration, supervision, conceptualisation, methodology, writing – review and editing; L.K.: project administration, supervision, validation, conceptualisation, methodology, formal analysis, writing – review and editing.

Declaration of interest

E.C. is part of the guest editorial team and did not take part in the review or decision-making process of this paper. All other authors: none.

Funding

This work was supported by the Fonds National de la Recherche, Luxembourg (Z.B., project code 13568859) and the DFG-funded International Research Training Group IRTG 2804 (Z.B., A.-C.S.K., E.C., B.D., L.K.). E.C. receives funds from the Science for Life Laboratory.

Transparency declaration

The authors affirm that the manuscript is an honest, accurate and transparent account of the study being reported, no important aspects of the study have been omitted and any discrepancies from the study as planned have been explained.

Footnotes

*

These authors contributed equally.

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Figure 0

Fig. 1 Detailed study design of one measurement day (T1), repeated after approximately 4 months (T2). Participants had to forgo taking medication in the 24 h prior to the appointment, refrain from consuming caffeine or exercising 3 h before, and from food and drinks, except water, for 1 h prior to testing. All appointments were scheduled on weekdays, starting between 13.00 h and 14.00 h. In the first 30 min after arrival, participants filled out self-report questionnaires. After applying electrodes for skin conductance and pulse-oximeter for heart rate measures, participants gave the first saliva sample, then underwent a 40 min relaxation phase watching non-arousing documentaries. A second saliva sample was given with a short subjective mood questionnaire. In a randomised fashion, either the stress or placebo task of the MAST was applied, followed by another saliva sample and subjective mood questionnaire. During a second 40 min relaxation phase, saliva was collected 15 min after the previous sample. Participants underwent the second part of the MAST (stress or placebo), and before and after, a saliva sample and a subjective mood questionnaire was collected. Participants watched a final 40 min relaxing documentary, and saliva samples were collected at 15 min and 40 min post-task. For 7 days, a daily mood and stress diary was filled out (7-day diary via ecological momentary assessment (EMA)). The second measurement day had the same timeline, was counter-balanced for task order (Supplement Table S2 for details) and was scheduled on average 4 months after the first time point. Created with BioRender.com. IUD, intrauterine device.

Figure 1

Fig. 2 Endogenous and exogenous hormone levels in plasma across IUD users (dark blue), OC users (light blue) and NC women (grey) for both measurement timepoints (T1: first measurement; T2: ca. 4 months later; only task presentation order was switched). Sample sizes for T1 (IUD/OC/NC): Oestradiol: 27/13/29; Progesterone, Testosterone, Cortisol: 27/30/29; Levonorgestrel: 27/17/0; Ethinyl Oestradiol: 0/29/0. * indicates significance at P = 0.05. Created with BioRender.com. nmol/L, nanomole per litre; IUD, intrauterine device; OC, oral contraceptive; NC, natural, regular menstrual cycle.

Figure 2

Fig. 3 Stress correlates across IUD users (dark blue), OC users (light blue) and NC women (grey) for both measurement timepoints (T1 first measurement; T2 four months later). Top: subjective affect after placebo versus stress. (a) negative affect and (b) subjective stress. Bottom: physiological stress correlates. (c) cortisol response during stress task, stress onset at time 0, dots and bars indicate mean and s.e. (d) mean heart rate (HR) during placebo versus stress. * indicates significance at P = 0.05. Created with BioRender.com. IUD, intrauterine device; OC, oral contraceptive; NC, natural, regular menstrual cycle; nmol/L, nanomole per litre; HR, heart rate.

Figure 3

Fig. 4 Sex hormone associations with stress correlates and 7-day diary across IUD users (dark blue), OC users (light blue) and NC women (grey) for both measurement timepoints (T1 first measurement; T2 four months later). (a) progesterone predicting tonic skin conductance, significant only for NC women but not IUD users or OC users. (b) testosterone positively predicts acute socio-emotional (soc.-emo) stress in 7-day diary among NC women but not IUD users or OC users. (c) oestradiol negatively predicts negative affect in 7-day diary among IUD users, but not OC users or NC women. Created with BioRender.com. soc.-emo., socio-emotional; IUD, intrauterine device; OC, oral contraceptive; NC, natural, regular menstrual cycle; AUC, area under the curve.

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