Background
The contribution of structural brain changes to the prevalence, course and incidence of late-life depression is a key topic of psychiatric neuroscience. Neuroanatomical substrates of depression could play a major role in diagnosis, prognosis, stratification of depression subtypes and treatment monitoring. Although some robust associations have been identified previously, the field has not yet yielded information that is clinically applicable, and contributions to pathophysiological understanding have been limited. The most replicated finding among older adults has been an association between smaller hippocampus volume with depression.Reference Kempton, Salvador, Munafò, Geddes, Simmons and Frangou1–Reference Sexton, Le Masurier, Allan, Jenkinson, McDermott and Kalu4 This association may be especially noticeable with a longer depression duration or a larger number of depressive episodes.Reference Treadway, Waskom, Dillon, Holmes, Park and Chakravarty5–Reference Kronmüller, Pantel, Köhler, Victor, Giesel and Magnotta9 Little is known about the temporality of this association. Yet one study suggested that longer duration and severity of depression lead to faster development of hippocampal atrophy.Reference Taylor, McQuoid, Payne, Zannas, MacFall and Steffens10 Conversely, there is insufficient longitudinal data available to assess whether hippocampal atrophy may precede incident depression.Reference den Heijer, Tiemeier, Luijendijk, van der Lijn, Koudstaal and Hofman11
Further, given that the hippocampus is a heterogeneous structure, composed of several subfields, each of which is characterised by specific cellular composition and characteristic neurophysiology,Reference Fanselow and Dong12 one may expect that different hippocampal subfields might be differentially associated with depression pathophysiology. Whereas this has been explored previously,Reference Treadway, Waskom, Dillon, Holmes, Park and Chakravarty5,Reference Roddy, Farrell, Doolin, Roman, Tozzi and Frodl6,Reference Lim, Hong, Jung, Ahn, Won and Hahn13,Reference Ballmaier, Narr, Toga, Elderkin-Thompson, Thompson and Hamilton14 conflicting results have been presented, likely because of limited sample sizes and a lack of longitudinal data.
Aim
The aim of the present study was to investigate the associations of hippocampal subfield volumes with prevalence, course and incidence of depressive symptoms using a large neuroimaging sample. Specifically, we investigated the associations of hippocampal subfield volumes and depressive symptoms at baseline, and the associations of hippocampal subfields volumes at baseline with depressive symptoms during follow-up. In both cases we further subdivided the analysis according to the course of depression, i.e. chronic or transient, and corrected the analysis for demographic, cardiovascular and lifestyle risk factors.
Method
Study population and design
We used data from The Maastricht Study, an observational prospective population-based cohort study. The rationale and methodology have been described previously.Reference Schram, Sep, van der Kallen, Dagnelie, Koster and Schaper15 In brief, the study focuses on the aetiology, pathophysiology, complications and comorbidities of type 2 diabetes mellitus (T2DM), heart disease and other chronic conditions, and is characterised by an extensive phenotyping approach. All individuals aged between 40 and 75 years and living in the southern part of the Netherlands were eligible for participation. Participants were recruited through mass media campaigns, the municipal registries and the regional Diabetes Patient Registry via mailings. Recruitment was stratified according to known T2DM status, with an oversampling of individuals with T2DM, for reasons of efficiency. Baseline data were collected between November 2010 and January 2018. Lag time between magnetic resonance imaging (MRI) and depression assessment at baseline was 102 days (s.d. = 120).
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. All procedures involving human participants were approved by the institutional Medical Ethical Committee (NL31329.068.10) and the Minister of Health, Welfare and Sports of the Netherlands (Permit 131088-105234-PG). All participants gave written informed consent.
For the current analysis complete data was available from 4653 participants for cross-sectional analysis and 4154 participants for longitudinal analysis. Supplementary Figure 1 available at https://doi.org/10.1192/bjp.2023.143 shows the flow chart of the study population.
Brain MRI
Brain images were acquired on a 3T clinical magnetic resonance scanner (MAGNETOM Prismafit, Siemens Healthineers GmbH) located at a dedicated scanning facility (Scannexus, Maastricht, the Netherlands) using a head/neck coil with 64 elements for parallel imaging. The MRI protocol included a three-dimensional T 1-weighted (T 1w) magnetisation-prepared rapid acquisition gradient echo (MPRAGE) sequence (repetition time/inversion time/echo time (TR/TI/TE) 2300/900/2.98 ms, 176 slices, 256 × 240 matrix size, 1.0 mm cubic reconstructed voxel size); and a fluid-attenuated inversion recovery (FLAIR) sequence (TR/TI/TE 5000/1800/394 ms, 176 slices, 512 × 512 matrix size, 0.49 × 0.49 × 1.0 mm reconstructed voxel size).
Brain segmentation was performed with FreeSurfer v6.0Reference Fischl16 using both T 1w and FLAIR images as input. The arguments ‘-FLAIRpial’ and ‘-3T’ were used to optimise segmentation quality. Brain segmentations with insufficient quality, i.e. Euler numbers below 1.5 quartile (−80 for left hemisphere and −68 for right hemisphere) were excluded.Reference Monereo-Sánchez, de Jong, Drenthen, Beran, Backes and Stehouwer17 Hippocampal subfieldsReference Iglesias, Augustinack, Nguyen, Player, Player and Wright18 were segmented using multispectral segmentation, yielding hippocampus total volume and 12 hippocampal subfields per hemisphere (Supplementary Table 1). All extracted volumes were z-transformed prior to statistical analysis with respect to the distribution in the complete sample (n = 4643). Results are depicted using hippocampal subfields maps, a legend for these maps can be found in Supplementary Figure 2.
Depression
Depressive symptoms were assessed by a validated Dutch version of the 9-item Patient Health Questionnaire (PHQ-9)Reference Kroenke, Spitzer and Williams19 both at baseline and follow-up. Follow-up data was collected annually over a period of 7 years, i.e. each participant was asked to complete the PHQ-9 questionnaire once every year, up to 7 years. The PHQ-9Reference Kroenke, Spitzer and Williams19 is a self-administered questionnaire that assesses the presence of the nine symptoms for the DSM-IV criteria for a major depressive disorder on a four-point Likert scale ranging from 0 ‘not at all’ to 4 ‘nearly every day’.20 When one or two items were missing, the total score was calculated as 9 × (total points/9 − number of missing items) and rounded to the nearest integer. When more items were missing, the total score was scored as missing. A cut-off score of ≥10 is most often used as a dichotomous scoring system for defining clinically relevant depressive symptoms, with a good sensitivity (88%) and specificity (78%).Reference Pettersson, Boström, Gustavsson and Ekselius21 The internal consistency of the PHQ-9 in The Maastricht Study was good (Cronbach's alpha = 0.82 without T2DM, and 0.87 with T2DM).Reference Janssen, Köhler, Stehouwer, Schaper, Dagnelie and Sep22
There was a time lag between the baseline data collection and the date of the MRI scan. Therefore, the PHQ-9 score obtained closest to the date of the MRI scan, regardless of whether the assessment was before or after the scan, was chosen as the baseline score for each individual. Subsequent assessments were labelled as follow-up 1, follow-up 2, and so forth, based on the order in which they occurred after the baseline assessment.
Here, we use the term ‘prevalent depressive symptoms’ to indicate the use of PHQ-9 scores as a continuum at baseline. We use the term prevalent depression to indicate clinically relevant depressive symptoms (PHQ-9 ≥ 10) at baseline. We subdivided prevalent depression according to its course as:
(a) ‘prevalent depression with a chronic course’ i.e. clinically relevant depressive symptoms (PHQ-9 ≥ 10) at baseline and clinically relevant depressive symptoms (PHQ-9 ≥ 10) at at least one follow-up time; and
(b) ‘prevalent depression with a transient course’ i.e. clinically relevant depressive symptoms (PHQ-9 ≥ 10) at baseline and no clinically relevant depressive symptoms (PHQ-9 < 10) during follow-up.
We use the term ‘incident depression’ to indicate no clinically relevant depressive symptoms (PHQ-9 < 10) at baseline and presence of clinically relevant depressive symptoms (PHQ-9 ≥ 10) at at least one follow-up time. We subdivided incident depression according to its course as:
(a) ‘Incident depression with a chronic course’ i.e. no clinically relevant depressive symptoms (PHQ-9 < 10) at baseline and clinically relevant depressive symptoms (PHQ-9 ≥ 10) at two or more follow-up moments; or
(b) ‘incident depression with a transient course’, i.e. no clinically relevant depressive symptoms (PHQ-9 < 10) at baseline and clinically relevant depressive symptoms (PHQ-9 ≥ 10) at one follow-up.
We used the term, ‘no depression’ as the comparison group, and include those participants with no clinically relevant depressive symptoms (PHQ-9 < 10) at baseline and no clinically relevant depressive symptoms (PHQ-9 < 10) at follow-up.
General characteristics and covariates
General characteristics and covariates were measured at baseline. Educational level (low, intermediate, high), history of cardiovascular disease (CVD), smoking status (never, current, former), alcohol consumption (none, low, high) were assessed by questionnaires.Reference Schram, Sep, van der Kallen, Dagnelie, Koster and Schaper15 We measured, height, weight, waist circumference, office blood pressure, plasma lipid profile, and 24 h urinary albumin excretion (twice) as described elsewhere.Reference Schram, Sep, van der Kallen, Dagnelie, Koster and Schaper15
To determine T2DM status, all participants (except those who used insulin) underwent a standardised seven-point oral glucose tolerance test after an overnight fast. Glucose metabolism status was defined according to the World Health Organization 2006 criteria.23 Participants were considered to have T2DM if they had a fasting blood glucose ≥7.0 mmol/L or a 2 h post load blood glucose ≥11.1 mmol/L or used oral glucose-lowering medication or insulin. Cholesterol lowering medication, glucose-lowering medication and use of antidepressants was assessed in a medication interview at baseline where generic name, dose and frequency were registered.
Statistical analyses
General characteristics of the study population were evaluated using independent t-tests, or χ2-tests when appropriate.
A total of five research questions (RQs) were asked. Are hippocampal subfield volumes associated with:
(a) prevalent depressive symptoms (RQ1);
(b) clinically relevant depressive symptoms (RQ2);
(c) clinically relevant depressive symptoms according to its course (chronic and transient) (RQ3);
(d) incident clinically relevant depressive symptoms (RQ4); and
(e) incident clinically relevant depressive symptoms according to its course (chronic and transient) (RQ5)?
We used negative binomial regression on data from n = 4643 participants to answer RQ1; logistic regression on data from n = 4643 participants for RQ2; multimodal logistic regression on data from n = 4174 participants for RQ3; and Cox proportional hazards regression with time to event on the time axis on data from n = 4174 participants for RQ4 and RQ5. An overview of the research questions, participants and groups can be seen in Supplementary Figure 1.
Associations were adjusted for potential confounders in two different models: model 1, adjusted for total brain volume (when analysing total hippocampal volumes), or for total hippocampal volume (when analysing hippocampal subfields), MRI lag time, age and gender; and model 2, additionally adjusted for T2DM status, education level, waist circumference, history of CVD, total-to-high-density lipoprotein cholesterol ratio, use of alcohol and smoking status.
We studied the left and right hemispheres separately, and analysed 1 total hippocampal volume and 12 hippocampal subfields for each hemisphere. The hippocampal subfields are correlated with each other (Supplementary Table 2). For this reason, correction for multiple comparisons was done in accordance with the matrix spectral decomposition method.Reference Nyholt24 Based on the resulting eigenvalues, the obtained effective number was n = 13, therefore alpha was set at 0.05/13 = 0.0039.
Several sensitivity analyses were performed based on the fully adjusted model (model 2):
(a) we excluded individuals with type 2 diabetes to assess whether they drive the observed associations;
(b) we adjusted for antidepressant medication use;
(c) we excluded participants who used antidepressant medication;
(d) to restrict analyses to ‘de novo’ depression, we excluded participants who had a history of major depressive disorder diagnosis (assessed through the Mini-International Neuropsychiatric InterviewReference Sheehan, Lecrubier, Sheehan, Amorim, Janavs and Weiller25) before baseline;
(e) we additionally adjusted for cognitive status using Mini-Mental State Examination score.Reference Folstein, Folstein and McHugh26
Finally, we tested whether these associations differed according to gender, and T2DM status, by use of interaction analyses.
All statistical analyses were performed in R 4.0.2 (2020-06-22); analytic code is available on request from the corresponding author.
Results
General characteristics of the study population
The cross-sectional study population (n = 4643) had a mean age of 60.0 years (s.d. = 8.6), and 51.8% were women, 229 participants had prevalent depression (PHQ-9 ≥ 10).
Table 1 shows the general characteristics of the study population for longitudinal analysis (n = 4174) stratified for depressive status. A total of 190 participants had prevalent depression, 141 of them had a chronic course during follow-up, and 49 had a transient course. Out of 3984 participants free of depression at baseline, 376 developed incident depression. Participants with no depression were more often men and had a better cardiovascular profile than those with prevalent or incident depression. Demographics of participants not included in this study because of missing data or bad segmentation quality can be seen in Supplementary Table 3.
Bold indicates P < 0.05. BMI, body mass index; CVD, cardiovascular disease; MMSE, Mini-Mental State Examination; PHQ-9, Patient Health Questionnaire; T2DM, type 2 diabetes mellitus.
a. No depressive symptoms is no clinically relevant depressive symptoms at baseline nor at follow-up. Prevalent depression is clinically relevant depressive symptoms at baseline. Incident depression is no clinically relevant depressive symptoms at baseline and clinically relevant depressive symptoms at follow-up .
b. Compared with no clinically relevant depressive symptoms at baseline and follow-up.
c. The study is oversampled with individuals with type 2 diabetes by design.
Hippocampal subfields and prevalent depression
We found no associations between total hippocampus volume and prevalent depressive symptoms (PHQ-9 score as a continuum; Supplementary Table 4). Larger volumes in bilateral molecular layer (left relative risk (RR) = 1.11, 95% CI 1.05–1.17 and right RR = 1.14, 95% CI 1.08–1.20) and right hippocampal fissure (RR = 1.06, 95% CI 1.02–1.11), and smaller volumes in right dentate gyrus (RR = 0.89, 95% CI 0.83–0.96) and right cornu ammonis (CA)2/3 (RR = 0.91, 95% CI 0.87–0.96) and CA4 (RR = 0.89, 95% CI 0.83–0.96) were significantly associated with depressive symptoms in model 1. The association between smaller volumes in CA4 and depressive symptoms remained significant (RR = 0.89, 95% CI 0.83–0.96) after full adjustment (model 2). Hippocampal subfields associations in model 2 are depicted in Supplementary Figure 3.
No association of total hippocampus volume with prevalent depression (PHQ-9 ≥ 10) was found (Supplementary Table 5). A larger right molecular layer (odds ratio (OR) = 1.46, 95% CI 1.18–1.81) and hippocampal fissure (OR = 1.32, 95% CI 1.13–1.53) and smaller CA2/3 (OR = 0.72, 95% CI 0.59–0.87) were associated with prevalent depression in model 1. The association with right hippocampal fissure remained significant (OR = 1.26, 95% CI 1.08–1.48) after full adjustment (model 2). Results are depicted in Figure 1.
Hippocampal subfields volumes and course of prevalent depression
A significant association between lower volumes in the right hippocampus total volume and chronic course of prevalent depression (OR = 0.68, 95% CI 0.52–0.87) was found after full adjustment (model 2). Larger bilateral hippocampal fissure (left OR = 1.42, 95% CI 1.18–1.70 and right OR = 1.46, 95% CI 1.21–1.77) and molecular layer (left OR = 1.45, 95% CI 1.13–1.85 and right OR = 1.66, 95% CI 1.27–2.19), as well as smaller left parasubiculum (OR = 0.73, 95% CI 0.59–0.90) and right CA3 (OR = 0.60, 95% CI 0.47–0.77) were associated with a higher risk ratio of chronic course of prevalent depression in model 1. After full adjustment (model 2), higher volumes in bilateral hippocampal fissure (left OR = 1.37, 95% CI 1.14–1.64 and right OR = 1.40, 95% CI 1.15–1.71) and right molecular layer (OR = 1.51, 95% CI 1.14–2.00), as well as smaller volumes in right CA3 (OR = 0.61, 95% CI 0.48–0.79) remained significantly associated with the chronic course of prevalent depression. Results are depicted in Fig. 2, and details can be found in Supplementary Table 6. No significant associations were found for the transient course of prevalent depression.
Hippocampal subfields and incident depression
No significant associations were found between hippocampal volumes and incident depression (Supplementary Table 7).
Hippocampal subfields and course of incident depression
A statistically significant association between lower volume in left HATA and the chronic course of incident depression was found (hazard ratio (HR) = 0.70, 95% CI 0.55–0.89), whereas we found no associations with the transient course of incident depression (Supplementary Table 8).
Sensitivity analysis
Sensitivity analysis show results with preserved direction of effect and higher P-values when (a) excluding participants with T2DM, (b) adjusting for antidepressant medication, (c) excluding participants using antidepressant medication, (d) excluding participants with a lifetime of major depressive disorder diagnosis and (e) adjusting for cognition.
Results are detailed for prevalent depressive symptoms (Supplementary Table 9), prevalent depression (Supplementary Table 10) and prevalent depression with a chronic course (Supplementary Table 11). No interactions with gender or T2DM were found in the associations of depression and hippocampal volumes (data not shown).
Discussion
Main findings
In this middle-to-older-aged population, we studied the associations between hippocampal subfield volumes and prevalence, course and incidence of depressive symptoms. We show that specific hippocampal subfields are associated with prevalent depression, especially with a chronic course. One subfield was also associated with incident depression, yet only when the course was chronic. To our knowledge, this is the first study that has investigated the association of specific hippocampal subfield volumes with depressive symptoms in a population-based sample.
Comparison with findings from other studies
Larger right hippocampal fissure and bilateral molecular layer, as well as smaller right dentate gyrus, and CA3 and CA4, were associated with prevalent depressive symptoms (PHQ-9 score as a continuum). Larger right fissure and molecular layer, as well as smaller right CA3 were associated with prevalent depression (PHQ-9 ≥ 10), independently of age, gender and total hippocampal volume. The associations between hippocampal subfields and depression severity have been previously explored among patients with major depressive disorder (MDD) in small clinical samples (n = 41 to 163). In line with our results, Hu et al (2019)Reference Hu, Zhang, Hu, Lu, Tang and Li27 found that lower CA3 and CA4/dentate gyrus volumes were associated with more severe depressive symptoms. However, we could not replicate their findings of a significant association with lower volumes in the subiculum. In addition, our results are in line with previous studies in clinical samples that compared patients with MDD with controls,Reference Roddy, Farrell, Doolin, Roman, Tozzi and Frodl6,Reference Ballmaier, Narr, Toga, Elderkin-Thompson, Thompson and Hamilton14,Reference Han, Won, Sim and Tae28 who found smaller volumes in CA structures, the subiculum and tail associated with MDD. A main difference is, however, that we found these associations more often in the right hemisphere, whereas the previous studies reported differences in both hemispheres.
These differences may be explained by the differences in study samples (clinical versus population based) and difference in instruments to assess depression (MDD diagnosis versus depressive symptoms). Although our definition of depression status is a reliable approach for MDD screening,Reference Janssen, Köhler, Stehouwer, Schaper, Dagnelie and Sep22,Reference Muñoz-Navarro, Cano-Vindel, Medrano, Schmitz, Ruiz-Rodríguez and Abellán-Maeso29 our study sample likely includes less severely affected individuals. This might mean that CA1, the subiculum and tail have more subtle or later roles in depression pathophysiology, being only detectable in more severe depression, in line with results from Roddy et al.Reference Roddy, Farrell, Doolin, Roman, Tozzi and Frodl6
Further, we found an association with the hippocampal fissure volume, which has not been reported before. The hippocampal fissure is not a tissue structure per se, but a cerebrospinal fluid filled cavity, defined as a space between the dentate gyrus and the molecular layer.Reference Iglesias, Augustinack, Nguyen, Player, Player and Wright18 The possibility of a larger fissure volume being driven by the general atrophy of the hippocampus was considered. However, our findings, in agreement with Roddy et al,Reference Roddy, Farrell, Doolin, Roman, Tozzi and Frodl6 revealed an increase in volume specifically within the molecular layer, which does not align with this hypothesis. As an alternative explanation, we propose that the observed larger volume of the hippocampal fissure might be attributed to the reshaping of the hippocampus.
We further studied the association of hippocampal subfields with the course of prevalent depression. We found some hippocampal subfields were associated with a chronic course but none was associated with a transient course. Specifically, the larger bilateral fissure and molecular layer, and smaller volumes of left parasubiculum, right CA3 and right total hippocampal volume were associated with a chronic course. Previous studies found an association between depression recurrence and total hippocampal atrophy,Reference Roddy, Farrell, Doolin, Roman, Tozzi and Frodl6,Reference Campbell, Marriott, Nahmias and MacQueen7,Reference Kronmüller, Pantel, Köhler, Victor, Giesel and Magnotta9 yet only one study explored this association with hippocampal subfields, finding smaller volumes in dentate gyrus.Reference Treadway, Waskom, Dillon, Holmes, Park and Chakravarty5
The different patterns of hippocampal morphology in patients with transient or chronic depression may suggest that hippocampus atrophy is of importance in the pathophysiology of chronic depression but is not in transient depression. Some studies have also explored the utility of hippocampal subfields in the measurement of treatment response, with promising results finding an increase in hippocampal volumes after some treatments, and remission of depression.Reference Hu, Zhang, Hu, Lu, Tang and Li27,Reference Kraus, Seiger, Pfabigan, Sladky, Tik and Paul30,Reference Cao, Luo, Fu, Du, Qiu and Yang31 Overall, our results suggest that the different subfields of the hippocampus might have a different sensitivity to depression. Cytology studies suggest that a deficiency in neurotrophic support might be the cause,Reference Stockmeier, Mahajan, Konick, Overholser, Jurjus and Meltzer32 and that the compensation of neurotrophic factors through pharmacological therapy could reverse the pathological process of depression.Reference Nestler, Barrot, DiLeone, Eisch, Gold and Monteggia33
We found no significant associations between hippocampal subfield volumes and risk of incident depression, in line with a previous smaller population-based study.Reference den Heijer, Tiemeier, Luijendijk, van der Lijn, Koudstaal and Hofman11 Yet, when we subdivided this analysis according to the course, we found lower volumes in left HATA to be associated with incident depression with a chronic course. This might indicate that there is a different aetiology in incident depression with a chronic course versus a transient course. Replication of our findings is needed, and future studies should clarify whether changes in hippocampal volumes are specific for subtypes of depression.
Strengths and limitations
Strengths of this study include the large sample size and population-based design, the extensive assessment of potential confounders that reduces the chance of residual confounding and the annual assessment of depressive symptoms over a 7-year period. To assess robustness of observed associations we performed a range of sensitivity analyses. Results remained similar after additionally adjusting for antidepressant medication, cognition and limiting the sample to de novo depression. Potential selection and/or attrition bias, which is inherent to prospective population-based studies, may have resulted in underestimation of the observed associations. In addition, depression was measured with the PHQ-9 questionnaire, which is a reliable and valid tool for the measurement of depressive symptoms, but is not equal to a clinical diagnosis of MDD.Reference Kroenke, Spitzer and Williams19,Reference Martin, Rief, Klaiberg and Braehler34,Reference Negeri, Levis, Sun, He, Krishnan and Wu35 Additionally, the progression of depression was evaluated annually during follow-up sessions. This approach allows for the possibility that a person may have experienced depression at some point during the year but it might not have been present at the time of assessment. As a result, there is a chance of encountering false negatives in some participants.
Our study utilises a population-based cohort with an intentional oversampling of individuals with T2DM. In the general population, the lifetime prevalence of depression stands between 10% and 25% for women and from 5% to 12% for men,Reference Siddiqui36 whereas within our sample it was 30% (1349 participants out of 4643 participants with cross-sectional data). This observed difference can be attributed to the deliberate oversampling of people with T2DM, as individuals with T2DM are almost twice as likely to experience depression.Reference Siddiqui36 Consequently, the prevalence of depression is elevated within our sample. We corrected our analysis for T2DM, and excluded participants with T2DM in a sensitivity analysis. Yet, it is imperative to consider these aspects carefully when generalising the results of our study.
Finally, hippocampal volumes were extracted using the FreeSurfer v6.0 automated tool. FreeSurfer v6.0 has proven to be a reliable method for hippocampal subfields volume's measurement, showing a good agreement with manual segmentation.Reference Tae, Kim, Lee, Nam and Kim37 It also shows a good test–retest reliability, especially in the tail, subiculum, presubiculum, CA1–4, dentate gyrus and molecular layer.Reference Brown, Pierce, Clark, Fischl, Iglesias and Milberg38,Reference Quattrini, Pievani, Jovicich, Aiello, Bargalló and Barkhof39 Moreover, its use has previously proved useful to provide insight into the neurobiological underpinnings of several brain-related traits and disorders.Reference Sämann, Iglesias, Gutman, Grotegerd, Leenings and Flint40 In this study, the hippocampal segmentation was implemented with the additional use of a FLAIR image (multispectral segmentation) which has shown to additionally improve subfields segmentation reliability.Reference Iglesias, Augustinack, Nguyen, Player, Player and Wright18,Reference Seiger, Hammerle, Godbersen, Reed, Spurny-Dworak and Handschuh41 Further, all FreeSurfer output used in The Maastricht Study undergoes quality control through the exclusion of outliers based on Euler numbers, a technique that shows similar quality control benefits to visual inspection for hippocampal subfields segmentation,Reference Monereo-Sánchez, de Jong, Drenthen, Beran, Backes and Stehouwer17 reinforcing the solidity of the data. However, it is crucial to interpret the results with caution, especially concerning the smaller subfields such as the hippocampal fissure. Despite utilising diverse techniques to improve the accuracy of hippocampal subfield segmentation, the inherent complexity and intricacies of these smaller subfields present challenges that demand careful consideration.
Implications
In conclusion, differences in hippocampal volumes of specific subfields, indicating hippocampal atrophy, were associated with prevalent depression, in particular with a chronic course. In longitudinal analyses we found some evidence that smaller volume in the left HATA was associated with a risk of incident depression with a chronic course. Our results indicate that changes in hippocampus subfield volumes may co-occur or follow the onset of depressive symptoms, rather than precede it. We found limited evidence to support that specific volume changes could precede the onset of (chronic) depressive symptoms. Therefore, our results could be capturing a biological foundation for the development of chronic depression, and further stresses the need to discriminate between subtypes of depression to unravel its biological underpinnings.
Supplementary material
Supplementary material is available online at https://doi.org/10.1192/bjp.2023.143
Data availability
The data used in this project is part of The Maastricht Study and is available on formal request from the corresponding author, M.T.S. Please visit https://www.demaastrichtstudie.nl/data-guidelines for more information.
Author contributions
J.M.-S., J.F.A.J., D.E.J.L., M.T.S. contributed to the study concept and design; J.M.-S. performed the data analysis, results interpretation, and drafted the manuscript; J.F.A.J., D.E.J.L., M.T.S. supervised the project; J.F.A.J., M.P.J.v.B., W.H.B., S.K., C.D.A.S., D.E.J.L., M.T.S. contributed to the results interpretation and revision of the manuscript.
Funding
This study was supported by the European Regional Development Fund via OP-Zuid, the Province of Limburg, the Dutch Ministry of Economic Affairs (grant 31O.041), Stichting De Weijerhorst (Maastricht, the Netherlands), the Pearl String Initiative Diabetes (Amsterdam, the Netherlands), the Cardiovascular Center (CVC, Maastricht, the Netherlands), CARIM School for Cardiovascular Diseases (Maastricht, the Netherlands), CAPHRI Care and Public Health Research Institute (Maastricht, the Netherlands), NUTRIM School for Nutrition and Translational Research in Metabolism (Maastricht, the Netherlands), Stichting Annadal (Maastricht, the Netherlands), Health Foundation Limburg (Maastricht, the Netherlands), School for Mental Health & Neuroscience (Maastricht, the Netherlands) and by unrestricted grants from Janssen-Cilag B.V. (Tilburg, the Netherlands), Novo Nordisk Farma B.V. (Alphen aan den Rijn, the Netherlands) and Sanofi-Aventis Netherlands B.V. (Gouda, the Netherlands).
Declaration of interest
None.
eLetters
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