Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-24T19:33:04.774Z Has data issue: false hasContentIssue false

Depressive symptoms and cognitive impairment: A 10-year follow-up study from the Survey of Health, Ageing and Retirement in Europe

Published online by Cambridge University Press:  27 August 2021

Fei-Fei Han
Affiliation:
College of Public Health, Zhengzhou University, Zhengzhou, Henan, China
Hui-Xin Wang*
Affiliation:
Stress Research Institute, Department of Psychology, Stockholm University, Stockholm, Sweden
Jia-Jia Wu
Affiliation:
College of Public Health, Zhengzhou University, Zhengzhou, Henan, China
Wu Yao*
Affiliation:
College of Public Health, Zhengzhou University, Zhengzhou, Henan, China
Chang-Fu Hao
Affiliation:
College of Public Health, Zhengzhou University, Zhengzhou, Henan, China
Jin-Jing Pei
Affiliation:
Stress Research Institute, Department of Psychology, Stockholm University, Stockholm, Sweden
*
*Authors for Correspondence: Hui-Xin Wang, E-mail: [email protected] Wu Yao, E-mail: [email protected]
*Authors for Correspondence: Hui-Xin Wang, E-mail: [email protected] Wu Yao, E-mail: [email protected]

Abstract

Background

Depressive symptoms and cognitive impairment often coexisted in the elderly. This study investigates the effect of late-life depressive symptoms on risk of mild cognitive impairment (MCI).

Methods

A total of 14,231 dementia- and MCI free participants aged 60+ from the Survey of Health, Ageing, and Retirement in Europe were followed-up for 10 years to detect incident MCI. MCI was defined as 1.5 standard deviation (SD) below the mean of the standardized global cognition score. Depressive symptoms were assessed by a 12-item Europe-depression scale (EURO-D). Severity of depressive symptoms was grouped as: no/minimal (score 0–3), moderate (score 4–5), and severe (score 6–12). Significant depressive symptoms (SDSs) were defined as EURO-D score ≥ 4.

Results

During an average of 8.2 (SD = 2.4)-year follow-up, 1,352 (9.50%) incident MCI cases were identified. SDSs were related to higher MCI risk (hazard ratio [HR] = 1.26, 95% confidence intervals [CI]: 1.10–1.44) in total population, individuals aged 70+ (HR = 1.35, 95% CI: 1.14–1.61) and women (HR = 1.28, 95% CI: 1.08–1.51) in Cox proportional hazard model adjusting for confounders. In addition, there was a dose–response association between the severity of depressive symptoms and MCI incidence in total population, people aged ≥70 years and women (p-trend <0.001).

Conclusions

Significant depressive symptoms were associated with higher incidence of MCI in a dose–response fashion, especially among people aged 70+ years and women. Treating depressive symptoms targeting older population and women may be effective in preventing MCI.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of the European Psychiatric Association

Introduction

As life expectancy continues to rise, dementia incidence is exponentially increasing [Reference Raz, Knoefel and Bhaskar1]. It has reported that nearly 43.8 million people suffering from dementia worldwide in 2016 [2], this figure is anticipated to be tripled [Reference Emmady and Dementia3] and will cost $4 trillion by 2050 [Reference Iadecola, Duering, Hachinski, Joutel, Pendlebury and Schneider4], placing a heavy burden on individuals, families, and societies. Because of the long latent period before the clinical manifestation of dementia [Reference Petersen5], increasing attention is being paid to the prodromal stage of dementia-mild cognitive impairment (MCI) in recent years. MCI is characterized by subtle but measurable decline in cognitive abilities, whereas daily activities are not significantly affected [Reference Gauthier, Reisberg, Zaudig, Petersen, Ritchie and Broich6]. Studies have found that people with MCI are at greater risk of dementia, with the annual progression rates 3–5% in community-based populations [Reference Mitchell and Shiri-Feshki7] and 10–15% in clinical settings [Reference Demurtas, Schoene, Torbahn, Marengoni, Grande and Zou8]. Thus, identifying modifiable risk factors are essential because of the lack of effective treatment nowadays [Reference Diniz, Butters, Albert, Dew and Reynolds9].

A growing body of evidence support that depression is one of the modifiable risk factors for dementia [Reference Diniz, Butters, Albert, Dew and Reynolds9], which is characterized by progressive decline in cognitive function [Reference Steffens10,Reference Geraets, Schram, Jansen, Koster, Dagnelie and van Greevenbroek11]. Depressive symptom and cognitive impairment often co-occur in advanced age, leading to a variety of emotional and physical problems that affect the ability of individuals in work and life and further reduce the quality of life [Reference Goldberg and Harrow12,Reference Rapaport, Clary, Fayyad and Endicott13]. However, whether or not depressive symptom is a risk factor for MCI remains unclear. Most studies have reported that depression is common in patients with MCI [Reference Depression14,Reference Anderson15], being a predictor of MCI or progressive cognitive decline [Reference Ismail, Gatchel, Bateman, Barcelos-Ferreira, Cantillon and Jaeger16Reference Hu, Shu, Wu, Chen, Hu and Zhang18], whereas other studies have reported that depression is not associated with MCI [Reference Singh-Manoux, Dugravot, Fournier, Abell, Ebmeier and Kivimäki19,Reference Kwan, Leung, Yee, Lau, Xu and Dai20].

The occurrence of depression has been reported to increase with age, peaking at 60–64 years old, but declining among people over 80 years old [21]. However, in the existing studies, the study samples have been limited to either middle-aged [Reference Aguilera, Paz, Compañ, Medina and Feixas22] or clinical patients [Reference Egan, Laidlaw and Starkstein23], which are not representative to general older population. Second, some of the previous studies were cross-sectional [Reference Vloeberghs, Opmeer, De Deyn, Engelborghs and De Roeck24,Reference Aajami, Kazazi, Toroski, Bahrami and Borhaninejad25], and the existing longitudinal studies have either limited follow-up time [Reference Douglas, Gallagher, Robinson, Carter, VV and Frampton26] or limited sample size [Reference Tan, Abdin, Shahwan, Zhang, Sambasivam and Vaingankar27], which are insufficient to determine the association between depressive symptoms and MCI. Further, the potential dose–response relationship between depression severity and cognitive impairment from general population has rarely been investigated. Among them, two studies demonstrated that the higher the baseline depression severity, the greater the subsequent global cognitive impairment [Reference Raji, Reyes-Ortiz, Kuo, Markides and Ottenbacher28,Reference Köhler, van Boxtel, van Os, Thomas, O’Brien and Jolles29], and one study found that this dose–response relationship was retained in processing speed, not in episodic memory or executive function [Reference Comijs, Jonker, Beekman and Deeg30], whereas other two studies did not found such a relationship in global cognition [Reference Almeida, Hankey, Yeap, Golledge and Flicker31,Reference Comijs, van Tilburg, Geerlings, Jonker, Deeg and van Tilburg32].

Using data from a population-based investigation, the Survey of Health, Ageing and Retirement in Europe (SHARE), the current study aims to address: (a) the influence of significant depressive symptoms (SDSs) on incidence of MCI; (b) whether there exists a dose–response association between the severity of depressive symptoms and MCI; and (c) whether these relationships vary by age and gender.

Method

Study population

SHARE is a biennial longitudinal survey of the aging process in individuals aged 50+ from 11 European countries in 2004 and Israel in 2005. So far, it has conducted six panel waves (waves 1, 2, 4–7) and an ongoing wave (wave 8), with a retrospective data in wave 3 (SHARELIFE). The investigation was mainly focused on health, socio-economic status, and social and family networks, the detailed information could be found elsewhere (http://www.share-project.org/). Participants were interviewed using standardized computer-assisted personal interview by trained staff [Reference Bunce, Batterham, Mackinnon and Christensen33].

In the present study, we chose wave 2 [Reference Ganguli, Du, Dodge, Ratcliff and Chang34] as baseline survey and waves 4 [Reference Stijntjes, Aartsen, Taekema, Gussekloo, Huisman and Meskers35], 5 [Reference Hamilton36], 6 [Reference McGivney, Mulvihill and Taylor37], and 7 [Reference Thomas, Jones, Scarinci, Mehan and Brantley38] as follow-up surveys because dementia status was not accessed in waves 1 [Reference Colla, Kronenberg, Deuschle, Meichel, Hagen and Bohrer39] and cognitive tests were not performed in wave 3 [Reference Haapakoski, Mathieu, Ebmeier, Alenius and Kivimäki40]. Ethic permission of SHARE was approved by the University of Mannheim’s internal review board (IRB) and Ethics Council of the Max Planck Society. Each subject signed informed consent, including the storage and the use of relevant data [Reference Goldsmith, Rapaport and Miller41].

The SHARE wave 2 investigated 37,152 participants. Of these, we excluded those younger than 60 years (n = 12,887), with a diagnosis of dementia (n = 491) or MCI (n = 658), and those who developed dementia during follow-ups (n = 260). We further excluded those with missing information on baseline dementia diagnosis (n = 106), depressive symptoms (n = 548), educational attainment (n = 2155), cognitive function (n = 589), follow-up time (n = 6), and those who were lost to all follow-ups (n = 5,221). After the exclusion, 14,231 individuals were included in the analysis (Figure 1).

Figure 1. Flowchart of sample selection process.

Assessment of depressive symptoms

Depressive symptoms were assessed by a self-reported European-Depression (EURO-D) [Reference Prince, Reischies, Beekman, Fuhrer, Jonker and Kivela42] scale. The structured scale covers 12 emotional states: depressed mood, pessimism, suicidal tendencies, guilt, sleep, interest, irritability, appetite, fatigue, concentration, enjoyment, and tearfulness in the past month. Each item has a yes (score 1) or no (score 0) answers, the sum scores ranged from 0 to 12, with higher scores indicating greater severity of depressive symptoms. The EURO-D scale has good internal consistency [Reference Castro-Costa, Dewey, Stewart, Banerjee, Huppert and Mendonca-Lima43] (Cronbach’s alpha ranging from 0.78 to 0. 95) and external validity [Reference Guerra, Ferri, Llibre, Prina and Prince44]. SDSs were defined as EURO-D score ≥ 4 and used in the analysis as dichotomized variable (SDSs vs. non-SDSs) [Reference Kucera, Wolfová and Cermakova45]. This cut-off has been shown to have a reasonable sensitivity (63–83%) and specificity (49–95%) in 14 European countries [Reference Prince, Beekman, Deeg, Fuhrer, Kivela and Lawlor46]. To further explore the dose–response association between the severity of depressive symptoms and MCI incidence, the participants were divided into three groups: (a) no/minimal (score 0–3), (b) moderate (score 4–5), and (c) severe depressive symptoms (score 6–12).

Assessment of cognitive function

Assessments of cognitive function were performed at each wave including: episodic memory, executive function, and language. Episodic memory consists of immediate recall and delayed recall of a 10-word list based on a modified version of the Rey Auditory Verbal Learning Test [Reference Moradi, Hallikainen, Hänninen and Tohka47]. Two tests were required to recall in 1 and 5 min later with a full score of 10, respectively. Executive function and language were assessed with verbal fluency test, asking respondents to correctly name as many animals as possible within 1 min. For each domain, higher scores indicate better cognition.

Because of the heterogeneity among individuals, we used age- and education-standardized cognitive scores for the analysis. Step 1, the mean and standard deviation (SD) for immediate recall, delayed recall, and verbal fluency were calculated, respectively, according to the resulting 15 categories of the cross-tabulation of age- (60–64, 65–69, 70–74, 75–79, and over 80) and education- (low, middle and high). Step 2, to facilitate comparison, the z-score of each cognitive domain was calculated using the raw score subtracting the mean and dividing by the SD of the corresponding categories [Reference Wang, Jin, Hendrie, Liang, Yang and Cheng48]. To ensure the comparability across waves, the cognitive scores at follow-ups were also standardized using the same formula and grouping as in step 1. The global cognitive score was calculated as the average z-score of all the three cognitive domains. MCI was defined as 1.5 SD below the mean of the standardized global cognition score [Reference Hooghiemstra, Ramakers, Sistermans, Pijnenburg, Aalten and Hamel49].

Assessment of covariates

Information on age, gender, country, marital status and living arrangement, educational attainment, smoking, alcohol consumption, physical activity, body mass index (BMI), the number of chronic diseases, history of affective or emotional disorders, and anti-anxiety or depression medication were collected at baseline. Education attainment was ascertained following the International Standard Classification of Education-97 (ISCED-97) and divided into low (ISCED score 0–2), middle (ISCED score 3–4), and high (ISCED score 5–6) [50]. Missing information in baseline education was replaced with values from other waves because their levels of education should be constant. Marital status was obtained by asking the participants: “What is your marital status?” and living arrangement by the question: “Do you have a partner who lives outside this household?,” these two variables were integrated into one and was categorized into living with a partner (married and living with spouse or registered partnership in the same household) and living alone (married but not living with spouse, never married, divorced, or widowed) as in previous studies [Reference Qiao, Lu, Yan, Yao, Pei and Wang51].

Smoking status was dichotomized as non/ex-smokers (never smoked or stopped smoking currently) and current-smokers (currently smoking). Alcohol assumption was classified into frequent-drinkers (five or more units of alcohol a week), usual-drinkers (more than twice a week), and nondrinkers (less than twice a month or not at all) during the last 3 months. Physical activity was dichotomized as inactive (never vigorous nor moderate physical activity) and active (participated in moderate or vigorous exercise at least once a week or 1–3 times a month). BMI was divided into four groups: underweight (<18.5 kg/m2), normal (18.5–24.9 kg/m2), overweight (25.0–29.9 kg/m2), and obese (≥ 30.0 kg/m2). The number of chronic diseases was the sum of these diseases: heart attack, hypertension, high blood cholesterol, stroke, diabetes, lung disease, asthma, osteoporosis, arthritis, cancer, peptic ulcer, Parkinson disease, cataracts, hip fracture, and femoral fracture, except dementia because it was related to the outcome (MCI), and it was grouped into four categories (0 = none, 1 = few, 2–3 = some, and 4 or above = many).

Statistical analyses

The differences in baseline characteristics between participants with different depression status were shown in frequency and percentage for categorical variables and median with interquartile range (IQR) for continuous variables. The baseline characteristics of the nonparticipants due to missing information were compared with the study sample in terms of N (%) for categorical variables and mean ± SD for continuous variables.

Multivariate Cox proportional hazard models were conducted to examine the association of baseline SDSs and the severity of depressive symptoms with incidence of MCI. The follow-up time (year) was calculated as the dates between the baseline interviews and the occurrence of MCI at the first time, or the last follow-up examination for participants with normal cognition during the follow-up period. The proportional hazard assumption in Cox regression models across all covariates was assessed, and the covariates that satisfy the assumption were retained in the models. In addition, we also performed stratified analyses by age groups (60–69 vs. 70 and over) and gender strata.

Finally, we performed two sensitivity analyses. First, in order to confirm the association of late-life depressive symptoms with MCI and to increase comparability with previous studies, we excluded participants below age of 65 (n = 4,423), leaving 9,808 subjects for the analysis. Second, to minimize reverse causality, we excluded participants who developed MCI during waves 2–4 (n = 205), leaving 14,026 participants for the analysis. Stata 14.0 was used for all analyses.

Results

Baseline characteristics of participants

Table 1 presents the prevalence of SDSs and baseline characteristics of the study population (n = 14,231). The median follow-up time of the study sample was 9.8 years, 55.95% were aged <70 years, 54.72% were women, and 22.87% had SDSs. In total population, the median z-score was 0.08 in immediate recall, 0.08 in delayed recall, 0.02 in verbal fluency, and 0.06 in global cognition. By contrast, the z-scores for all cognitive domains were negative in individuals with SDSs, and positive among those with non-SDSs.

Table 1. Baseline characteristics of the study population by depression status over the 10-year follow-up, N (%)/median (IQR).

Abbreviations: BMI, body mass index; IQR, interquartile range; N, numbers; SDSs, significant depressive symptoms.

1 Participants with missing values (n = 95 in marital status and living arrangement, 56 in smoking, 61 in alcohol assumption, 65 in physical activity, 334 in BMI, 5 in history of affective or emotional disorders, 7 in anti-anxiety or depression medication).

2 All cognitive scores are presented in standardized score.

In addition, compared with nonparticipants due to missing information, the study sample is significantly healthier as they were younger and had higher levels of education, less likely to be physically inactive and obese, less likely to have chronic diseases, history of affective or emotional disorders, and less likely to use anti-anxiety or depression medication, although more likely to drink alcohol and be overweight. Besides, they had lower EURO-D scores and better cognitive performance (Supplementary Table S1).

Depressive symptoms and incident MCI from the Cox Proportional Hazards model

After an average of 8.2-year follow-up (SD: 2.4 years, range: 2.7–11.3 years), 1,352 individuals developed MCI (9.50%). Table 2 displays the HRs for incident MCI in people with SDSs compared those with non-SDSs. In total population, people with SDSs were at a significantly higher risk of incident MCI (HR = 1.26) after adjusting for potential confounders (age, gender, country, marital status and living arrangement, educational attainment, smoking, alcohol consumption, physical activity, BMI, the number of chronic diseases, history of affective or emotional disorders, and anti-anxiety or depression medication). The significantly increased risk is only present among individuals aged 70+ (HR = 1.35) and among women (HR = 1.28). These results were also confirmed when excluding participants below age of 65 (n = 4,423; Supplementary Table S2).

Table 2. Hazard ratios (95% confidence intervals) for incident MCI according to baseline depressive symptoms, and stratified by age (under 70 and 70 and over) and gender.

Bold values indicate a significance level of p < 0.05.

HRs were obtained from Cox Proportional Hazards model adjusted for age, gender, country, marital status and living arrangement, educational attainment, smoking, alcohol consumption, physical activity, BMI, the number of chronic diseases, history of affective or emotional disorders and anti-anxiety or depression medication.

Abbreviations: CI, confidence intervals; BMI, body mass index; HR, hazard ratio; MCI, mild cognitive impairment; SDSs, significant depressive symptoms.

Dose–response association between the severity of depressive symptoms and MCI incidence

As shown in Figure 2, in total population, compared with no/minimal depressive symptoms (score 0–3), individuals with higher EURO-D scores had a significantly higher risk of incident MCI (p-trend <0.001) after adjustment for covariates, indicating a dose–response association. Stratified analyses by age and gender showed that the dose–response association was only observed among people aged ≥70 years and women. Among people aged ≥70 years, compared to those with no/minimal depressive symptoms, individuals with moderate depressive symptoms were at a significantly high risk of MCI (HR = 1.27) and this risk was even higher (HR = 1.50) among those with severe depressive symptoms. Among women, significant increased MCI risk were associated with moderate (HR = 1.25) and severe depressive symptoms (HR = 1.34) compared to no/minimal depressive symptoms. These results remained after excluding new MCI cases that were developed between waves 2 and 4 (n = 205; Supplementary Table S3).

Figure 2. HRs were obtained from Cox Proportional Hazards model adjusted for age, gender, country, marital status and living arrangement, educational attainment, smoking, alcohol consumption, physical activity, body mass index (BMI), the number of chronic diseases, history of affective or emotional disorders and anti-anxiety or depression medication.

Discussion

This study provided evidence of an independent negative effect of SDSs on risk of incident MCI over a 10-year follow-up in total population, older participants (≥70 years) and women. When the severity of depressive symptoms was considered, there was a dose–response relationship: the more severe the depressive symptoms, the higher the incidence of MCI. Further stratified analysis revealed that the dose–response relationship was only retained among older participants (≥70 years) and women.

The prevalence of SDSs among those without MCI in the current study was 23%, which is consistent with a recent systematic review reporting a range of 2.8–35% in older adults [Reference Beekman, Copeland and Prince52]. However, the value was 31.3% among aged over 45 years Chinese, which was higher but within the range [Reference Yang, Pan, Gong, Wen, Ye and Wu53]. Another study reported a prevalence of depression was 11.8% among people aged over 65 years in Portugal [Reference de Sousa, Rodrigues, Gregório, Branco, Gouveia and Canhão54]. Studies of the prevalence of SDSs differed greatly with regard to the characteristics of study population, rating scales, and diagnostic criteria [Reference Sjöberg, Karlsson, Atti, Skoog, Fratiglioni and Wang55]. In addition, the data in SHARE documented that there was a very strong heterogeneity among countries [Reference Castro-Costa, Dewey, Stewart, Banerjee, Huppert and Mendonca-Lima56].

Our result that baseline SDSs were associated with increasing subsequent MCI incidence is consistent with most previous studies [Reference Hu, Shu, Wu, Chen, Hu and Zhang18,Reference Steenland, Karnes, Seals, Carnevale, Hermida and Levey57,Reference Lara, Koyanagi, Domènech-Abella, Miret, Ayuso-Mateos and Haro58]. Conversely, a small number of studies have shown that depressive symptoms was not associated with cognitive impairment [Reference Yatawara, Lim, Chander, Zhou and Kandiah59,Reference Topiwala, Suri, Allan, Zsoldos, Filippini and Sexton60]. These inconsistent findings possibly due to the differences on the chosen cognitive tests and the definition of MCI. There are several possible interpretations for the relationship between depressive symptoms and cognitive impairment. First, SDSs may be a risk factor for cognitive impairment. Second, SDSs is a precursor of cognitive impairment. Third, SDSs and cognitive impairment simultaneously exist [Reference Muliyala and Varghese61]. To date, most studies support the hypothesis that depressive symptom is both a risk factor and a precursor of cognitive impairment [Reference Vinkers, Gussekloo, Stek, Westendorp and van der Mast62,Reference Bunce, Batterham, Christensen and Mackinnon63], our study confirmed the former.

Our finding demonstrated that there was a dose–response relationship between the severity of depressive symptoms and MCI incidence. This finding remained when excluding the new MCI cases developed during the first two waves’ follow-up and when excluding participants younger than 65 years. Similar findings were reported in a study showing that the risk of cognitive impairment increased for each 10-point increment on the Center for Epidemiologic Studies Depression Scale [Reference Saczynski, Beiser, Seshadri, Auerbach, Wolf and Au64], but this relationship was not found in another cohort study [Reference Almeida, Hankey, Yeap, Golledge and Flicker31]. Such inconsistence may be attributed to the differences in the assessment scales for depressive symptoms, follow-up time, study design, sample size, and sources of study population (population-based versus hospital-based).

Age-stratified analyses concerning the severity of depressive symptoms and MCI incidence are rare. Our results showed that a dose–response association was only observed among people aged 70+ years. These findings are in line with a study from Chilean, which reported that depressive symptoms were positively associated with incident MCI only among people older than 65 years [Reference Nazar, Ulloa, Martínez-Sanguinetti, Leiva, Petermann-Rocha and Martínez65]. In contrast, another previous study documented that this association was stronger and more stable among those <75 years [Reference Sekhon, Allali and Beauchet66]. These age specific associations need to be further studied because of variations in age cut-offs. This age-specific association observed in our study among those aged 70+ (or 65+) may be explained by the fact that retirees may face environmental changes, reduce the feelings of social participation, coupled with difficulty adapting to the life after retirement, are more susceptible to loneliness and emotional disorders, thus aggravating the effect of depressive symptoms on risk of MCI. In contrast, by the time of retirement transition (aged 60–65), people may aspire to retirement and have positive emotions to deal with their work and life, which may counteract the negative effect of depressive symptoms on risk of MCI.

Sex-stratified analyses of the link between the severity of depressive symptoms and MCI risk have yielded mixed results. Some studies found that the effect was specific to female [Reference Johnson, Gamboa, Vintimilla, Edwards, Hall and Weiser67], while others reported it was specific to male [Reference Nazar, Ulloa, Martínez-Sanguinetti, Leiva, Petermann-Rocha and Martínez65] or mild in men and severe in women [Reference Sundermann, Katz and Lipton68]. Our findings that an independent negative association was only observed among women and in a dose–response manner are plausible because men and women differ in their neural structure and system. It has been shown that women had less intelligence-related gray matter and are more susceptible to the pathology of white matter than men in the course of dementia [Reference Kim, Noh, Noh, Oh, Koh and Kim69]. Besides, women were more anxious and emotional when facing with retirement changes [Reference Asselmann and Specht70]. Further, women have weak stress resistance, lower stress threshold, and are more prone to suffer from SDSs. By contrast, men are less sensitive to changes in mood and have a higher stress threshold, which may reduce their risk of MCI after experienced depressive symptoms.

The potential mechanisms between depressive symptoms and the risk of cognitive impairment involve endocrine system, inflammatory processes, and comorbidities. Depressive symptoms stimulate the production of glucocorticoid or deposition of beta-amyloid by activating the hypothalamic–pituitary–adrenal axis, which in turn cause damage to the hippocampus and lead to cognitive impairment [Reference Colla, Kronenberg, Deuschle, Meichel, Hagen and Bohrer39]. Depressive symptoms may not only increase the secretion of pro-inflammatory cytokines [Reference Haapakoski, Mathieu, Ebmeier, Alenius and Kivimäki40,Reference Goldsmith, Rapaport and Miller41], such as interleukin-6 and high sensitive c-reactive protein [Reference Krogh, Benros, Jørgensen, Vesterager, Elfving and Nordentoft71], relating to microglial activation, blood–brain barrier dysfunction, and subsequent neuronal damage [Reference Alam, Hana, Jin, Suen and Ma72], but also decrease the release of neurotrophic factors [Reference Byers and Yaffe73], maintaining neuronal health and regulating synaptic plasticity, which in combination could lead to cognitive impairment [Reference Misiak, Beszłej, Kotowicz, Szewczuk-Bogusławska, Samochowiec and Kucharska-Mazur74]. Moreover, some evidence suggest that this association could potentially be mediated by other comorbidities, particularly cardiovascular diseases, according to the “vascular-depression-dementia hypothesis” [Reference Flicker75,Reference Alexopoulos, Meyers, Young, Campbell, Silbersweig and Charlson76]. Although these hypotheses have been proposed, the exact biological mechanism of the link between depressive symptoms and cognitive impairment remains unclear, further research is needed to provide more evidence.

Strengths of the present study include: first, this is a prospective cohort study, with a 10-year follow-up, which may yield more reliable results. Second, the study population is a representative sample of older Europeans, which increased the generalizability of the findings. Third, we included those who participated in any of the follow-ups, which greatly increased the sample size and minimized selection bias. Fourth, Cox proportional hazard model was used to take into account the influence of follow-up time and the proportional hazard assumption was assessed, so that it would lead to better accurate and more reliable results than methods that do not consider the time influence or studies that used Cox regression models but did not examine the proportional hazard assumption. Fifth, we explored the influence of depressive symptoms on MCI, the stage of early cognitive decline, which has profound implications for the prevention of cognitive impairment. Finally, sensitivity analysis revealed similar results, which further enhanced the authenticity and reliability of the study.

Nonetheless, this study has several limitations. One notable drawback is lost to follow-up, people with severe cognitive impairments often drop out of the survey early, resulting in underestimating the association. In addition, depressive symptoms were ascertained by self-reported questionnaires rather than structured clinical diagnoses or objective measures, which may lead to informational bias. Another limitation is that we only considered the baseline depressive symptoms, but did not take into account the dynamic changes in depressive symptoms, which may influence the observed results. Although a number of confounders have been taken into account, other unmeasured confounders, such as genetic factors, inflammatory markers, and other unknown diseases may influence the results. Finally, compared with nonparticipants due to missing information, the study sample was healthier, which may underestimate the observed association between depressive symptoms and MCI incidence.

Conclusions

Individuals with significant depressive symptoms were at significantly increased risk of subsequent MCI in a dose–response manner, especially among those aged 70+ years and women. These findings suggest that well-managed depressive symptoms treatment among people aged 70+ years and women may be effective to prevent MCI.

Supplementary Materials

To view supplementary material for this article, please visit http://dx.doi.org/10.1192/j.eurpsy.2021.2230.

Data Availability Statement

This study used data from the Survey of Health, Ageing and Retirement in Europe, which is freely available to academic researchers (http://www.share-project.org).

Acknowledgments

We thank Dr. Axel Börsch-Supan and other team members of the Survey of Health, Ageing and Retirement in Europe (SHARE) for their great contribution to the questionnaire design, data collection, management, imputations, etc. This study used data from SHARE Wave 1 (Data set. DOI: 10.6103/SHARE.w1.710), Wave 2 (Data set. DOI: 10.6103/SHARE.w2.710), Wave 3 (Data set. DOI: 10.6103/SHARE.w3.710), Wave 4 (Data set. DOI: 10.6103/SHARE.w4.710), Wave 5 (Data set. DOI: 10.6103/SHARE.w5.710), Wave 6 (Data set. DOI: 10.6103/SHARE.w6.710), and Wave 7 (Data set. DOI: 10.6103/SHARE.w7.711). We also thank all participants of the SHARE.

Financial Support

This work was supported by the Swedish Research Council (grant number 2018-02998), the Swedish Research Council for Health, Working Life and Welfare (grant number 2019-01120 and 2020-00313, Wang), the European Commission through FP5 (grant number QLK6-CT-2001-00360), FP6 (SHARE-I3: RII-CT-2006-062193, COMPARE: CIT5-CT-2005-028857, SHARELIFE: CIT4-CT-2006-028812), FP7 (SHAREPREP: GA N°211909, SHARE-LEAP: GA N°227822, SHARE M4: GAN°261982), and Horizon 2020 (SHARE-DEV3: GA N°676536, SERISS: GA N°654221), and by DG Employment, Social Affairs & Inclusion for the SHARE data collection. Additional funding from the German Ministry of Education and Research, the U.S. National Institute on Aging (grant numbers U01_AG09740-13S2, P01_AG005842, P01_AG08291, P30_AG12815, R21_AG025169, Y1-AG-4553-01, IAG_BSR06–11, OGHA_04–064, and HHSN271201300071C), and from various national funding sources is gratefully acknowledged. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Conflicts of Interest

The authors have no conflicts of interest to disclose.

Ethical Standards

Ethics Committee of the University of Manheim, Ethics Council of the Max Planck Society.

Author Contributions

Data curation: H.-X.W. and F.-F.H.; Formal analysis: F.-F.H.; Validation: H.-X.W., F.-F.H., J.-J.W., W.Y., C.H., J.-J.P.; Writing-review & editing: H.-X.W., F.-F.H., J.-J.W., W.Y., C.H., J.-J.P.

References

Raz, L, Knoefel, J, Bhaskar, K. The neuropathology and cerebrovascular mechanisms of dementia. J Cereb Blood Flow Metab 2016;36:172–86.CrossRefGoogle ScholarPubMed
GBD 2016 Dementia Collaborators. Burden of Alzheimer’s disease and other dementias, 1990–2016: a systematic analysis for the global burden of disease study 2016. Lancet Neurol. 2019;18:88106.CrossRefGoogle Scholar
Emmady, PD, Dementia, Tadi P.. StatPearls. Treasure Island, FL: StatPearls Publishing LLC; 2020.Google Scholar
Iadecola, C, Duering, M, Hachinski, V, Joutel, A, Pendlebury, ST, Schneider, JA, et al. Vascular cognitive impairment and dementia: JACC scientific expert panel. J Am Coll Cardiol 2019;73:3326–44.CrossRefGoogle ScholarPubMed
Petersen, RC. Mild cognitive impairment. Continuum (Minneap Minn). 2016;22:404–18.Google ScholarPubMed
Gauthier, S, Reisberg, B, Zaudig, M, Petersen, RC, Ritchie, K, Broich, K, et al. Mild cognitive impairment. Lancet 2006;367:1262–70.CrossRefGoogle ScholarPubMed
Mitchell, AJ, Shiri-Feshki, M. Rate of progression of mild cognitive impairment to dementia—meta-analysis of 41 robust inception cohort studies. Acta Psychiatr Scand 2009;119:252–65.CrossRefGoogle ScholarPubMed
Demurtas, J, Schoene, D, Torbahn, G, Marengoni, A, Grande, G, Zou, L, et al. Physical activity and exercise in mild cognitive impairment and dementia: an umbrella review of intervention and observational studies. J Am Med Dir Assoc 2020;21:1415–22.e6.CrossRefGoogle ScholarPubMed
Diniz, BS, Butters, MA, Albert, SM, Dew, MA, Reynolds, CF, 3rd. Late-life depression and risk of vascular dementia and Alzheimer’s disease: systematic review and meta-analysis of community-based cohort studies. Br J Psychiatry J Ment Sci 2013;202:329–35.CrossRefGoogle ScholarPubMed
Steffens, DC. Late-life depression and the prodromes of dementia. JAMA Psychiat 2017;74:673–4.CrossRefGoogle ScholarPubMed
Geraets, AFJ, Schram, MT, Jansen, JFA, Koster, A, Dagnelie, PC, van Greevenbroek, MMJ, et al. The relation of depression with structural brain abnormalities and cognitive functioning: the Maastricht study. Psychol Med. 2021;14:110.CrossRefGoogle Scholar
Goldberg, JF, Harrow, M. Subjective life satisfaction and objective functional outcome in bipolar and unipolar mood disorders: a longitudinal analysis. J Affect Disord. 2005;89:7989.CrossRefGoogle ScholarPubMed
Rapaport, MH, Clary, C, Fayyad, R, Endicott, J. Quality-of-life impairment in depressive and anxiety disorders. Am J Psychiatry 2005;162:1171–8.CrossRefGoogle ScholarPubMed
Depression, ML. Anxiety, and apathy in mild cognitive impairment: current perspectives. Front Aging Neurosci. 2020;12:9.Google Scholar
Anderson, ND. State of the science on mild cognitive impairment (MCI). CNS Spectr. 2019;24:7887.CrossRefGoogle Scholar
Ismail, Z, Gatchel, J, Bateman, DR, Barcelos-Ferreira, R, Cantillon, M, Jaeger, J, et al. Affective and emotional dysregulation as pre-dementia risk markers: exploring the mild behavioral impairment symptoms of depression, anxiety, irritability, and euphoria. Int Psychogeriatr 2018;30:185–96.CrossRefGoogle ScholarPubMed
Freire, ACC, Pondé, MP, Liu, A, Caron, J. Anxiety and depression as longitudinal predictors of mild cognitive impairment in older adults. Can J Psychiatr 2017;62:343–50.CrossRefGoogle ScholarPubMed
Hu, M, Shu, X, Wu, X, Chen, F, Hu, H, Zhang, J, et al. Neuropsychiatric symptoms as prognostic makers for the elderly with mild cognitive impairment: a meta-analysis. J Affect Disord 2020;271:185–92.CrossRefGoogle ScholarPubMed
Singh-Manoux, A, Dugravot, A, Fournier, A, Abell, J, Ebmeier, K, Kivimäki, M, et al. Trajectories of depressive symptoms before diagnosis of dementia: a 28-year follow-up study. JAMA Psychiat 2017;74:712–8.CrossRefGoogle ScholarPubMed
Kwan, RYC, Leung, AYM, Yee, A, Lau, LT, Xu, XY, Dai, DLK. Cognitive frailty and its association with nutrition and depression in community-dwelling older people. J Nutr Health Aging 2019;23:943–8.CrossRefGoogle ScholarPubMed
World Health Organization. Depression and other common mental disorders: global health estimates.[J]. World Health Organization, Geneva Licence: CC BY-NC-SA 3.0 IGO. 2017.Google Scholar
Aguilera, M, Paz, C, Compañ, V, Medina, JC, Feixas, G. Cognitive rigidity in patients with depression and fibromyalgia. Int J Clin Health Psychol 2019;19:160–4.CrossRefGoogle ScholarPubMed
Egan, SJ, Laidlaw, K, Starkstein, S. Cognitive behaviour therapy for depression and anxiety in Parkinson’s disease. J Parkinsons Dis 2015;5:443–51.CrossRefGoogle ScholarPubMed
Vloeberghs, R, Opmeer, EM, De Deyn, PP, Engelborghs, S, De Roeck, EE. Apathy, depression and cognitive functioning in patients with MCI and dementia. Tijdschr Gerontol Geriatr. 2018;49:95102.CrossRefGoogle ScholarPubMed
Aajami, Z, Kazazi, L, Toroski, M, Bahrami, M, Borhaninejad, V. Relationship between Depression and cognitive impairment among elderly: a cross-sectional study. J Caring Sci 2020;9:148–53.CrossRefGoogle ScholarPubMed
Douglas, KM, Gallagher, P, Robinson, LJ, Carter, JD, VV, McIntosh, Frampton, CM, et al. Prevalence of cognitive impairment in major depression and bipolar disorder. Bipolar Disord 2018;20:260–74.CrossRefGoogle ScholarPubMed
Tan, JH, Abdin, E, Shahwan, S, Zhang, Y, Sambasivam, R, Vaingankar, JA, et al. Happiness and cognitive impairment among older adults: investigating the mediational roles of disability, depression, social contact frequency, and loneliness. Int J Environ Res Public Health. 2019;16:4954–68.CrossRefGoogle ScholarPubMed
Raji, MA, Reyes-Ortiz, CA, Kuo, YF, Markides, KS, Ottenbacher, KJ. Depressive symptoms and cognitive change in older Mexican Americans. J Geriatr Psychiatry Neurol 2007;20:145–52.CrossRefGoogle ScholarPubMed
Köhler, S, van Boxtel, MP, van Os, J, Thomas, AJ, O’Brien, JT, Jolles, J, et al. Depressive symptoms and cognitive decline in community-dwelling older adults. J Am Geriatr Soc 2010;58:873–9.CrossRefGoogle ScholarPubMed
Comijs, HC, Jonker, C, Beekman, AT, Deeg, DJ. The association between depressive symptoms and cognitive decline in community-dwelling elderly persons. Int J Geriatr Psychiatry 2001;16:361–7.CrossRefGoogle ScholarPubMed
Almeida, OP, Hankey, GJ, Yeap, BB, Golledge, J, Flicker, L. Depression as a risk factor for cognitive impairment in later life: the health in men cohort study. Int J Geriatr Psychiatry 2016;31:412–20.CrossRefGoogle ScholarPubMed
Comijs, HC, van Tilburg, T, Geerlings, SW, Jonker, C, Deeg, DJ, van Tilburg, W, et al. Do severity and duration of depressive symptoms predict cognitive decline in older persons? Results of the longitudinal aging study Amsterdam. Aging Clin Exp Res 2004;16:226–32.CrossRefGoogle ScholarPubMed
Bunce, D, Batterham, PJ, Mackinnon, AJ, Christensen, H. Depression, anxiety and cognition in community-dwelling adults aged 70 years and over. J Psychiatr Res 2012;46:1662–6.CrossRefGoogle ScholarPubMed
Ganguli, M, Du, Y, Dodge, HH, Ratcliff, GG, Chang, CC. Depressive symptoms and cognitive decline in late life: a prospective epidemiological study. Arch Gen Psychiatry 2006;63:153–60.CrossRefGoogle ScholarPubMed
Stijntjes, M, Aartsen, MJ, Taekema, DG, Gussekloo, J, Huisman, M, Meskers, CGM, et al. Temporal relationship between cognitive and physical performance in middle-aged to oldest old people. J Gerontol A Biol Sci Med Sci 2017;72:662–8.Google ScholarPubMed
Hamilton, M. Development of a rating scale for primary depressive illness. Br J Soc Clin Psychol 1967;6:278–96.CrossRefGoogle ScholarPubMed
McGivney, SA, Mulvihill, M, Taylor, B. Validating the GDS depression screen in the nursing home. J Am Geriatr Soc 1994;42:490–2.CrossRefGoogle ScholarPubMed
Thomas, JL, Jones, GN, Scarinci, IC, Mehan, DJ, Brantley, PJ. The utility of the CES-D as a depression screening measure among low-income women attending primary care clinics. The Center for Epidemiologic Studies-Depression. Int J Psychiatry Med. 2001;31:2540.CrossRefGoogle ScholarPubMed
Colla, M, Kronenberg, G, Deuschle, M, Meichel, K, Hagen, T, Bohrer, M, et al. Hippocampal volume reduction and HPA-system activity in major depression. J Psychiatr Res 2007;41:553–60.CrossRefGoogle ScholarPubMed
Haapakoski, R, Mathieu, J, Ebmeier, KP, Alenius, H, Kivimäki, M. Cumulative meta-analysis of interleukins 6 and 1β, tumour necrosis factor α and C-reactive protein in patients with major depressive disorder. Brain Behav Immun 2015;49:206–15.CrossRefGoogle ScholarPubMed
Goldsmith, DR, Rapaport, MH, Miller, BJ. A meta-analysis of blood cytokine network alterations in psychiatric patients: comparisons between schizophrenia, bipolar disorder and depression. Mol Psychiatry 2016;21:1696–709.CrossRefGoogle ScholarPubMed
Prince, MJ, Reischies, F, Beekman, AT, Fuhrer, R, Jonker, C, Kivela, SL, et al. Development of the EURO-D scale—a European, union initiative to compare symptoms of depression in 14 European centres. Br J Psychiatry J Ment Sci 1999;174:330–8.CrossRefGoogle ScholarPubMed
Castro-Costa, E, Dewey, M, Stewart, R, Banerjee, S, Huppert, F, Mendonca-Lima, C, et al. Ascertaining late-life depressive symptoms in Europe: An evaluation of the survey version of the EURO-D scale in 10 nations. The SHARE project. Int J Methods Psychiatr Res. 2008;17:1229.CrossRefGoogle ScholarPubMed
Guerra, M, Ferri, C, Llibre, J, Prina, AM, Prince, M. Psychometric properties of EURO-D, a geriatric depression scale: a cross-cultural validation study. BMC Psychiatry. 2015;15:12.CrossRefGoogle ScholarPubMed
Kucera, M, Wolfová, K, Cermakova, P. Changes in depressive symptoms of older adults in the Czech Republic. J Affect Disord 2020;261:139–44.CrossRefGoogle ScholarPubMed
Prince, MJ, Beekman, AT, Deeg, DJ, Fuhrer, R, Kivela, SL, Lawlor, BA, et al. Depression symptoms in late life assessed using the EURO-D scale. Effect of age, gender and marital status in 14 European centres. Br J Psychiatry J Ment Sci 1999;174:339–45.CrossRefGoogle ScholarPubMed
Moradi, E, Hallikainen, I, Hänninen, T, Tohka, J. Rey’s auditory verbal learning test scores can be predicted from whole brain MRI in Alzheimer’s disease. Neuroimage Clin 2017;13:415–27.CrossRefGoogle ScholarPubMed
Wang, HX, Jin, Y, Hendrie, HC, Liang, C, Yang, L, Cheng, Y, et al. Late life leisure activities and risk of cognitive decline. J Gerontol A Biol Sci Med Sci 2013;68:205–13.CrossRefGoogle ScholarPubMed
Hooghiemstra, AM, Ramakers, I, Sistermans, N, Pijnenburg, YAL, Aalten, P, Hamel, REG, et al. Gait speed and grip strength reflect cognitive impairment and are modestly related to incident cognitive decline in memory clinic patients with subjective cognitive decline and mild cognitive impairment: Findings from the 4C study. J Gerontol A Biol Sci Med Sci 2017;72:846–54.CrossRefGoogle ScholarPubMed
Innovation CfERa. Classifying educational programmes: manual for ISCED-97 implemention in oecd countries—1999 Edition. OECD Edu Skills 1999;1999:170.Google Scholar
Qiao, YM, Lu, YK, Yan, Z, Yao, W, Pei, JJ, Wang, HX. Reciprocal associations between job strain and depression: a 2-year follow-up study from the survey of health, ageing and retirement in Europe. Brain Behav 2019;9:e01381.CrossRefGoogle ScholarPubMed
Beekman, AT, Copeland, JR, Prince, MJ. Review of community prevalence of depression in later life. Br J Psychiatry J Ment Sci 1999;174:307–11.CrossRefGoogle ScholarPubMed
Yang, X, Pan, A, Gong, J, Wen, Y, Ye, Y, Wu, JH, et al. Prospective associations between depressive symptoms and cognitive functions in middle-aged and elderly Chinese adults. J Affect Disord 2020;263:692–7.CrossRefGoogle ScholarPubMed
de Sousa, RD, Rodrigues, AM, Gregório, MJ, Branco, JDC, Gouveia, MJ, Canhão, H, et al. Anxiety and depression in the Portuguese older adults: prevalence and associated factors. Front Med (Lausanne). 2017;4:196.CrossRefGoogle ScholarPubMed
Sjöberg, L, Karlsson, B, Atti, AR, Skoog, I, Fratiglioni, L, Wang, HX. Prevalence of depression: comparisons of different depression definitions in population-based samples of older adults. J Affect Disord 2017;221:123–31.CrossRefGoogle ScholarPubMed
Castro-Costa, E, Dewey, M, Stewart, R, Banerjee, S, Huppert, F, Mendonca-Lima, C, et al. Prevalence of depressive symptoms and syndromes in later life in ten European countries: the SHARE study. Br J Psychiatry J Ment Sci. 2007;191:393401.CrossRefGoogle ScholarPubMed
Steenland, K, Karnes, C, Seals, R, Carnevale, C, Hermida, A, Levey, A. Late-life depression as a risk factor for mild cognitive impairment or Alzheimer’s disease in 30 US Alzheimer’s disease centers. J Alzheimers Dis 2012;31:265–75.CrossRefGoogle ScholarPubMed
Lara, E, Koyanagi, A, Domènech-Abella, J, Miret, M, Ayuso-Mateos, JL, Haro, JM. The impact of depression on the development of mild cognitive impairment over 3 years of follow-up: a population-based study. Dement Geriatr Cogn Disord 2017;43:155–69.CrossRefGoogle ScholarPubMed
Yatawara, C, Lim, L, Chander, R, Zhou, J, Kandiah, N. Depressive symptoms influence global cognitive impairment indirectly by reducing memory and executive function in patients with mild cognitive impairment. J Neurol Neurosurg Psychiatry 2016;87:1375–83.CrossRefGoogle ScholarPubMed
Topiwala, A, Suri, S, Allan, C, Zsoldos, E, Filippini, N, Sexton, CE, et al. Subjective cognitive complaints given in questionnaire: Relationship with brain structure, cognitive performance and self-reported depressive symptoms in a 25-year retrospective cohort study. Am J Geriatr Psychiatry 2021;29:217–26.CrossRefGoogle Scholar
Muliyala, KP, Varghese, M. The complex relationship between depression and dementia. Ann Indian Acad Neurol. 2010;13:S69–73.Google ScholarPubMed
Vinkers, DJ, Gussekloo, J, Stek, ML, Westendorp, RG, van der Mast, RC. Temporal relation between depression and cognitive impairment in old age: prospective population based study. BMJ. 2004;329:881.CrossRefGoogle ScholarPubMed
Bunce, D, Batterham, PJ, Christensen, H, Mackinnon, AJ. Causal associations between depression symptoms and cognition in a community-based cohort of older adults. Am J Geriatr Psychiatry 2014;22:1583–91.CrossRefGoogle Scholar
Saczynski, JS, Beiser, A, Seshadri, S, Auerbach, S, Wolf, PA, Au, R. Depressive symptoms and risk of dementia: the Framingham heart study. Neurology. 2010;75:3541.CrossRefGoogle ScholarPubMed
Nazar, G, Ulloa, N, Martínez-Sanguinetti, MA, Leiva, AM, Petermann-Rocha, F, Martínez, XD, et al. Association between cognitive impairment and depression in Chilean older adults. Rev Med Chil 2020;148:947–55.CrossRefGoogle ScholarPubMed
Sekhon, H, Allali, G, Beauchet, O. The association of anxio-depressive disorders and depression with motoric cognitive risk syndrome: results from the baseline assessment of the Canadian longitudinal study on aging. Geroscience 2019;41:409–18.CrossRefGoogle ScholarPubMed
Johnson, LA, Gamboa, A, Vintimilla, R, Edwards, M, Hall, J, Weiser, B, et al. A depressive endophenotype for predicting cognitive decline among Mexican American adults and elders. J Alzheimers Dis 2016;54:201–6.CrossRefGoogle ScholarPubMed
Sundermann, EE, Katz, MJ, Lipton, RB. Sex differences in the relationship between depressive symptoms and risk of amnestic mild cognitive impairment. Am J Geriatr Psychiatry. 2017;25:1322.CrossRefGoogle ScholarPubMed
Kim, H, Noh, J, Noh, Y, Oh, SS, Koh, SB, Kim, C. Gender difference in the effects of outdoor air pollution on cognitive function among elderly in Korea. Front Public Health. 2019;7:375.CrossRefGoogle ScholarPubMed
Asselmann, E, Specht, J. Personality maturation and personality relaxation: differences of the big five personality traits in the years around the beginning and ending of working life. J Pers. 2021;00:117.Google ScholarPubMed
Krogh, J, Benros, ME, Jørgensen, MB, Vesterager, L, Elfving, B, Nordentoft, M. The association between depressive symptoms, cognitive function, and inflammation in major depression. Brain Behav Immun 2014;35:70–6.CrossRefGoogle ScholarPubMed
Alam, A, Hana, Z, Jin, Z, Suen, KC, Ma, D. Surgery, neuroinflammation and cognitive impairment. EBioMedicine 2018;37:547–56.CrossRefGoogle ScholarPubMed
Byers, AL, Yaffe, K. Depression and risk of developing dementia. Nat Rev Neurol 2011;7:323–31.CrossRefGoogle ScholarPubMed
Misiak, B, Beszłej, JA, Kotowicz, K, Szewczuk-Bogusławska, M, Samochowiec, J, Kucharska-Mazur, J, et al. Cytokine alterations and cognitive impairment in major depressive disorder: From putative mechanisms to novel treatment targets. Prog Neuro-Psychopharmacol Biol Psychiatry 2018;80:177–88.CrossRefGoogle ScholarPubMed
Flicker, L. Cardiovascular risk factors, cerebrovascular disease burden, and healthy brain aging. Clin Geriatr Med. 2010;26:1727.CrossRefGoogle ScholarPubMed
Alexopoulos, GS, Meyers, BS, Young, RC, Campbell, S, Silbersweig, D, Charlson, M.Vascular depression’ hypothesis. Arch Gen Psychiatry 1997;54:915–22.CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Flowchart of sample selection process.

Figure 1

Table 1. Baseline characteristics of the study population by depression status over the 10-year follow-up, N (%)/median (IQR).

Figure 2

Table 2. Hazard ratios (95% confidence intervals) for incident MCI according to baseline depressive symptoms, and stratified by age (under 70 and 70 and over) and gender.

Figure 3

Figure 2. HRs were obtained from Cox Proportional Hazards model adjusted for age, gender, country, marital status and living arrangement, educational attainment, smoking, alcohol consumption, physical activity, body mass index (BMI), the number of chronic diseases, history of affective or emotional disorders and anti-anxiety or depression medication.

Supplementary material: File

Han et al. supplementary material

Han et al. supplementary material

Download Han et al. supplementary material(File)
File 25 KB
Submit a response

Comments

No Comments have been published for this article.