Depression and APOEε4 Status in Individuals with Subjective Cognitive Decline: A Meta-Analysis

Article information

Psychiatry Investig. 2020;17(9):858-864
Publication date (electronic) : 2020 August 28
doi : https://doi.org/10.30773/pi.2019.0324
1Department of Gerontological Neurology, Heilongjiang Provincial Hospital, Harbin, China
2Department of Neurology, Hongqi Hospital, Mudanjiang Medical College, Mudanjiang, China
3Department of Experimental Diagnosis, Heilongjiang Provincial Hospital, Harbin, China
Correspondence: Peng-xiang Bi, MS Department of Neurology, Hongqi Hospital, Mudanjiang Medical College, No.5, Tongxiang Road, Mudanjiang, Heilongjiang 157011, China Tel: +86-453-6602051, Fax: +86-453-6602051, E-mail: pr5quz@163.com
*These authors contributed equally to this work.
Received 2020 January 20; Revised 2020 April 19; Accepted 2020 May 24.

Abstract

Objective

To evaluate the associative role of depression and apolipoprotein E epsilon 4 allele (APOEε4) in subjective cognitive decline (SCD) and its progression to objective cognitive decline.

Methods

After literature search in electronic databases, studies were selected by following precise eligibility criteria. Meta-analyses were performed to examine the role of APOEε4 and depression in SCD or its progression to mild cognitive impairment (MCI) or dementia.

Results

APOEε4 positivity was not different between SCD and normal individuals but was significantly higher in individuals with SCD plus than in normal individuals [odds ratio: 2.39 (95% CI: 1.87, 3.05); p<0.00001] and in SCD converters than in non-converters [odds ratio: 5.19 (95% CI: 2.36, 11.42); p<0.00001]. Depression was significantly higher in individuals with SCD [standardized mean difference: 0.63 (0.45, 0.82); p<0.00001] and SCD plus [standardized mean difference: 0.83 (0.43, 1.22); p<0.0001] than in normal individuals. However, depression was not different between SCD and MCI or between SCD converters and non-converters. Age of SCD converters was higher than non-converters [mean difference: 2.95 years (0.58, 5.31)].

Conclusion

Whereas APOEε4 positivity was higher in SCD plus and SCD converters, depression was higher in SCD and SCD plus but was not different between SCD and MCI.

INTRODUCTION

Subjective cognitive decline (SCD) is a self-perceived persistently declining cognitive function when compared to the individual’s previous state of normal cognitive performance on a standardized cognitive test score adjusted for age, sex, and education. SCD plus is a higher category of SCD that increases the likelihood of preclinical Alzheimer’s disease [1]. Presenting symptoms of SCD such as subjective memory complaints (individual informed memory problems) have a prevalence of 25% to 50% in community-dwelling elderly [2]. Individuals with SCD are at a greater risk of progression to any form of objective cognitive decline such as mild cognitive impairment (MCI) or Alzheimer’s disease [3-5]. The predictability is greater when a SCD-related complaint made by the individual is also endorsed by an informant (an individual who knows the patient well). A study of a multicenter cohort of elderly found that individuals were at a 4-fold risk of developing MCI or dementia if the SCD complaint was made by both the individual and the informant, whereas either the individual’s or the informant’s complaint posed 2-fold risk of progression [6].

Pathological changes associated with SCD and its progression include changes in both brain anatomy and biomarkers. In community-dwelling elderly, the severity of white matter lesions has been found to be associated with SCD and its worsening in the last five years [7]. The presence of thinner parietal and temporal cortices in individuals with SCD is associated with the later progression of SCD to dementia [8]. Increased amyloid beta deposition in the brain is also reported in older individuals with SCD [9]. Although, a significant proportion of older adults who report cognitive problems progress to objective cognitive impairment, the predictability is not straight forward and the link between SCD and objective cognitive impairment may be affected by the affective symptoms [10]. Moreover, the predictability of SCD for future objective cognitive impairment may also be confounded by many factors like depression, anxiety, physical health, and somatic problems [11,12].

The relationship between depression and SCD is not clear. Studies involving individuals with SCD have found associations of SCD with apolipoprotein E epsilon 4 allele (APOEε4) or with depression but the outcomes are not always consistent. In the present study, we undertake this issue by conducting a systematic review of these studies to perform a meta-analysis of important indices in order to seek a refined evidence of the relationship between APOEε4, depression and SCD.

METHODS

Eligibility criteria

A study was included if it 1) investigated cohorts of individuals with SCD or surveyed community-dwelling individuals; 2) reported APOEε4 status and the prevalence of depression in individuals with SCD; and 3) reported an association between SCD and APOEε4, and/or between SCD and depression, and/or between SCD and depression in APOEε4 positive individuals. A study was excluded if it 1) reported the relationships between APOEε4 and/or depression in individuals with MCI or dementia but not in individuals with SCD; 2) or reported the outcomes of either APOEε4 status or depression prevalence but not both in individuals with SCD; or 3) reported the outcomes without differentiating stages/forms of cognitive impairment.

Literature survey and study selection

A comprehensive literature search was conducted in Google Scholar, PubMed, and Science Direct electronic databases by using the most relevant key terms including subjective cognitive decline, SCD, memory complaints, dementia risk, preclinical Alzheimer’s disease, apolipoprotein E ε4, APOEε4, depression, and depressive symptoms. The search strategy is given in the supporting information file (Supplementary Table 1 in the online-only Data Supplement). Additional searches included screening the bibliographic sections of important research and review articles as well as the software suggested records. The literature search was restricted to research articles published in English before November 2019.

Data and analyses

Data pertaining to demographics, study design, cognitive status/measures, APOEε4 positivity, depression prevalence and scale, SCD progression rates, and associational outcomes were extracted from the identified research articles. SCD was defined as the individual’s complaint of worsened cognitive function (not related to an acute event) in comparison with a previously normal state, where SCD plus was considered a higher category of SCD as identified by the authors of individual studies. SCD converters were defined as the individuals who progressed to objective cognitive decline (MCI, Alzheimer’s disease or any other type of dementia) during study followup period.

To attain overall estimates of the prevalence of APOEε4 or depression, meta-analyses of proportions were performed under a random-effects model with Stata software (Stata Corporation, TX, USA) using dichotomous data of individual studies. Meta-analyses of odds ratios (ORs) were performed to estimate the differences in the prevalence of APOEε4 between normal individuals and in individuals with SCD, SCD plus, or MCI. In a separate meta-analysis, the ORs reported by the included studies were pooled to obtain overall estimates.

To estimate the significance of difference between normal individuals and individuals with SCD or MCI in depression scores, age, and formal education, random-effects meta-analyses of mean differences (MD) or standardized MD (SMD) were performed with RevMan software (Nordic Cochrane Centre, Cochrane Community). The between-studies inconsistency in outcomes was estimated with the I2 index.

RESULTS

Twenty-five studies published in twenty-eight research articles were included in the meta-analysis (Figure 1) [13-40]. From these studies, data were available for 6247 individuals with SCD {55% [95% confidence interval (CI): 51, 59] females}, 10087 normal (cognitively) individuals [56% (95% CI: 51, 60) females], and 1165 individuals with MCI [58% (95% CI: 49, 68) females]. Of these, 13 were cross-sectional and 13 were longitudinal studies. The average follow-up duration of the longitudinal studies was 5.8 years (95% CI: 4.8, 6.9). Important characteristics of the included studies are presented in Supplementary Table 1 (in the online-only Data Supplement).

Figure 1.

A flowchart of the study screening and selection process. SCD: subjective cognitive decline

The percent positivity of APOEε4 (homozygote or heterozygote) was 23% (95% CI: 19, 27) in normal, 28% (95% CI: 23, 33) in SCD, 31% (95% CI: 16, 49) in SCD plus, and 39% (95% CI: 29, 49) in MCI individual. The odds of APOEε4 positivity were not different between individuals with SCD and normal individuals [OR: 1.03 (95% CI: 0.79, 1.35); p=0.52]. However, the odds of APOEε4 positivity were significantly higher for individuals with SCD plus than for normal individuals [OR: 2.39 (95% CI: 1.87, 3.05); p<0.00001]. The odds of APOEε4 positivity were also significantly higher for SCD converters than for non-converters [OR: 5.19 (95% CI: 2.36, 11.42); p<0.00001) (Figure 2).

Figure 2.

A forest graph showing the ORs between SCD and normal/MCI individuals or between converters and non-converters from SCD to MCI in the presence of APOEε4. Diamonds show the overall ORs where the thicknesses represent summary point and the spread shows the 95% CI of the summary point. For individual studies, the central box represents the OR and lines show the 95% CI. The size of the box represents the weight of the study relative to other studies. BDI: Beck Depression Inventory, GDS: Geriatric Depression Scale, HDRS: Hamilton Depression Rating Scale, Met: methionine allele carriers, Val: valine allele carriers, OR: odds ratios, SCD: subjective cognitive decline, MCI: mild cognitive impairment, CI: confidence interval.

A pooled analysis of ORs reported by the individual studies also showed similar outcomes. In this meta-analysis, 1) the prevalence of APOEε4 was not different between SCD and normal individuals [pooled OR: 1.13 (95% CI: 0.86, 1.40)]; 2) the prevalence of depression was higher in individuals with SCD [pooled OR: 1.79 (95% CI: 0.33, 3.25)]; 3) the co-existence of APOEε4 and depression was also higher in individuals with SCD [pooled OR: 3.32 (95% CI: 0.04, 6.61)]; and 4) the risk of progression in individuals with SCD was higher in APOEε4 carriers [pooled OR: 1.94 (95% CI: 1.04, 2.84)] (Supplementary Figure 1 in the online-only Data Supplement).

A meta-analysis of depression scores indicated that depression was significantly higher in individuals with SCD [SMD: 0.63 (95% CI: 0.45, 0.82); p<0.00001] and SCD plus [SMD: 0.83 (95% CI: 0.43, 1.22); p<0.0001] in comparison with normal individuals. However, depression was not statistically significantly different between individuals with SCD and individuals with MCI [SMD: 0.12 (95% CI: -0.31, 0.54); p=0.70] or between SCD converters and non-converters [SMD: 0.21 (95% CI: -0.09, 0.51; p=0.17] (Figure 3).

Figure 3.

A forest graph showing the SMDs between SCD and normal/MCI individuals or between converters and non-converters from SCD to MCI in the levels of depression measured with validated tools. SCD: subjective cognitive decline, MCI: mild cognitive impairment, CI: confidence interval, SMD: standardized mean difference.

The age of individuals with SCD or SCD plus were not different from those of normal individuals [mean difference (MD): 0.25 years (95% CI: 0.03, 0.46) and 1.07 years (95% CI: -1.55, 3.69) respectively]. However, the age of SCD converters was approximately 3 years higher than that of non-converters [MD: 2.95 years (95% CI: 0.58, 5.31); p=0.01] (Supplementary Figure 2 in the online-only Data Supplement). Formal education was not different between the groups (Supplementary Figure 3 in the online-only Data Supplement).

DISCUSSION

In this meta-analysis we found that, in comparison with normal individuals, APOEε4 prevalence was not significantly higher in individuals with SCD but was significantly higher in individuals with SCD plus than in normal individuals and in SCD converters than in non-converters. On the other hand, the level of depression was significantly higher in individuals with SCD or SCD plus than in normal individuals but was not significantly different between individuals with SCD and individuals with MCI or between SCD converters and non-converters.

In older adults, depression is found to be associated with altered cognitive function including attention deficits, memory impairment, decreased information processing speed, poor responsiveness, problems in visual and spatial performance and lower performance in complex mental tasks [41-44]. In addition to the outcomes of the present study, a review of 47 crosssectional studies found depressive symptoms to be positively associated with SCD [45]. In a study of more than 13000 cognitively normal individuals over 50-years old of which 10% had depression and 27% had SCD at baseline, 11% developed MCI or dementia during 7 years of follow-up. The risk of developing MCI or dementia was significant with SCD (hazard ratio; HR: 2) as well as with depression (HR: 1.4) but the risk was highest when both depression and SCD (HR: 2.8) coexisted at baseline [46]. Thus, at least some of the SCD symptoms may stem from depression or depression may substantiate the symptoms of cognitive worsening arising from neurodegenerative processes.

In a longitudinal community-based study of elderly, a positive association was observed between APOEε4 and depression during 5 years of follow-up. This relationship persisted even after the exclusion of individuals who developed dementia within 9 years of follow-up and after controlling for the Mini-Mental State Examination score which showed that depression was not a prodromal symptom of dementia [47]. A meta-analysis of 9 studies also found that APOEε4 was positively associated with depression in individuals aged 23 to 83 years [48]. In the present study, we found that the odds of the coincidence of APOEε4 and depression were also higher in individuals with SCD. A study that used data of 11453 cognitively asymptomatic individuals from the National Alzheimer’s Coordinating Center, found that the hazard of developing Alzheimer’s disease was 10 times higher (HR: 10.1) among APOEε4 carriers with clinician-verified depression [49].

In the present study, the expression of APOEε4 increased from 23% in normal to 28% in SCD, 31% in SCD plus, and 39% MCI individuals. Our prevalence estimate resembles that of Zhang et al. [50] who reported the prevalence of APOEε4 at 32% in individuals with SCD after reviewing 28 studies. Moreover, in our study, APOEε4 positivity was significantly higher in SCD converters than in non-converters. A study of individuals with MCI found that the expression of APOEε4 was 62% in individuals who progressed from MCI to Alzheimer’s dementia [51]. Homozygous carriers of APOEε4 are reported to have a faster rate of cognitive decline between the age of 40 and 70 years [52]. Moreover, whereas heterozygous APOEε4 poses 3-fold risk of sporadic Alzheimer’s disease, APOEε4 homozygosity poses a 14-fold risk [53]. A probable mechanism of APOEε4 action appears to be related to amyloid beta clearance from the brain. It has been demonstrated that whereas APOEε2 enhances amyloid beta clearance from the brain, APOEε4 remains inefficient in this clearance [53].

Although the present study and the literature cited above indicate a relationship between depression and SCD, several caveats need to be addressed in future research. Whether depression develops because of persistent cognitive problems in individuals with SCD or whether depression causes, coexists, or worsens cognitive decline should be delineated. The relationship between APOEε4 and SCD can be better understood in SCD plus individuals but the relationship with depression in manifesting objective cognitive decline is not as clear. This study and some others suggest that the presence of both depression and APOEε4 increases the risk of progression among individuals with SCD more than either factor alone.

Some limitations of the present study should be noted. Firstly, less data were available with regards to the prevalence or measures of depression in APOEε4 positive vs APOEε4 negative individuals with SCD which could better portray a relationship between depression and SCD or its progression. Secondly, less binary data were available in individual studies pertaining to the prevalence of depression which could further clarify the outcomes of the present study. Thirdly, although in most of the analyses I2 remained moderate, statistical heterogeneity was high in some meta-analyses which represented high between-studies inconsistency in the outcomes. The use of various scales to measure depression, and study design features could have contributed to the heterogeneity.

Supplementary Materials

Acknowledgements

None.

Notes

The authors have no potential conflicts of interest to disclose.

Author Contributions

Conceptualization: Yue-ping Huang, Ju-jun Xue. Data curation: Chao Li, Xi Chen. Formal analysis: Chao Li, Xi Chen. Funding acquisition: Peng-xiang Bi. Investigation: Hong-juan Fu. Methodology: Teng Fei. Project administration: Peng-xiang Bi. Resources: Peng-xiang Bi. Sofware: Chao Li, Xi Chen. Supervision: Peng-xiang Bi. Validation: Peng-xiang Bi. Visualization: Peng-xiang Bi. Writing—original draf: Yue-ping Huang, Ju-jun Xue. Writing—review & editing: Peng-xiang Bi.

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Article information Continued

Figure 1.

A flowchart of the study screening and selection process. SCD: subjective cognitive decline

Figure 2.

A forest graph showing the ORs between SCD and normal/MCI individuals or between converters and non-converters from SCD to MCI in the presence of APOEε4. Diamonds show the overall ORs where the thicknesses represent summary point and the spread shows the 95% CI of the summary point. For individual studies, the central box represents the OR and lines show the 95% CI. The size of the box represents the weight of the study relative to other studies. BDI: Beck Depression Inventory, GDS: Geriatric Depression Scale, HDRS: Hamilton Depression Rating Scale, Met: methionine allele carriers, Val: valine allele carriers, OR: odds ratios, SCD: subjective cognitive decline, MCI: mild cognitive impairment, CI: confidence interval.

Figure 3.

A forest graph showing the SMDs between SCD and normal/MCI individuals or between converters and non-converters from SCD to MCI in the levels of depression measured with validated tools. SCD: subjective cognitive decline, MCI: mild cognitive impairment, CI: confidence interval, SMD: standardized mean difference.