Abstract
Objectives
To explore the pathogenetic hypothesis provided to explain the comorbidity of anxious and depressive symptomatology and AD and to assess the association between anxious and depressive symptoms and the AD-related cognitive impairment.
Methods
In October 2020 and March 2021, PsycINFO, Embase, Ovid, and CINAHL were searched for peer-reviewed original articles investigating anxiety and/or depression in AD.
Results
A total of 14,760 studies were identified and 34 papers on AD patients were included in the review. Suggested biological causes of depression and anxiety in AD include higher strychnine-sensitive glycine receptor (GlyRS) functioning and selective reduction of N-methyl-d-aspartate (NMDA) receptor NR2A density, cortical and limbic atrophy, lower resting cortical metabolism, lower CSF Aβ42 and higher t-tau and p-tau levels, and neuritic plaques. At the same time, dysthymia arises in the early stages of AD as an emotional reaction to the progressive cognitive decline and can cause it; anxiety can appear as an initial compensating behaviour; and depression might be related to AD awareness and loss of functional abilities. Affective symptoms and the expression of the depressive symptoms tend to reduce as AD progresses.
Conclusion
The neurodegeneration of areas and circuits dealing with emotions can elicit anxiety and depression in AD. In the early stages of the disease, anxiety and depression could arise as a psychological reaction to AD and due to coping difficulties. In late AD stages, the cognitive impairment reduces the emotional responses and their expression. Anxiety and depression are more intense in early-onset AD, due to the major impact of AD on the individual.
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Introduction
Alzheimer’s disease (AD) is a primary neurodegenerative dementia and one of the leading causes of disability in older people [1]. AD is clinically characterized by a progressive, global cognitive impairment that affects a person’s ability to perform everyday activities and is associated with brain changes that involve the extracellular accumulation of beta-amyloid plaques outside neurons and intraneuronal deposition of tau tangles inside neurons [2].
Although the core symptoms of AD are memory impairment and deficits in other cognitive domains [3], neuropsychiatric symptoms such as anxiety and depression are commonly observed during the clinical course of the illness [4, 5]. In AD, the prevalence of anxiety ranges from 9.4% (preclinical phase) to 39% (from mild to severe decline) [6, 7] and the prevalence of depression in mild-to-moderate AD varies from 14.8% [8] to 40% [9]. Anxiety is generally characterized by excessive worry, tenseness, irritability, wandering, and decreased engagement in once pleasurable activities [10]. Anxious symptoms seem to be associated with more severe impairments in activities of daily living and worse behavioural concerns [11], and anxiety could be considered a psychological response to AD diagnosis [12]. Typical depressive symptoms in AD are insomnia, social withdrawal, reduced purpose-oriented behaviour, loss of interest in once-enjoyable activities and hobbies, guilt, hopelessness, and sadness [13]. Anxiety and depression often overlap, especially in patients with mild AD [14].
Nevertheless, despite this evidence, due to progressive cognitive deterioration and to diagnostic and methodological difficulties in assessing anxiety and depression in AD patients, it is not easy to evaluate their role with respect to the progression of the disease.
Anxiety and depression in AD have been largely studied. Nevertheless, the pathogenetic explanations of the relationship of anxiety and depression with AD are still not so clear. On the one hand, a history of anxiety and depressive disorders, as well as their presence at the first stages of AD, represents a risk factor for the development of dementia [15, 16]. On the other hand, it is well-known that neuropsychiatric symptoms and AD share some common biological bases. Moreover, to our knowledge, to date, no studies proposed summary explanations of the various reasons why anxiety and depression can appear in comorbidity with AD and during its progression.
It is known that anxiety and depression can manifest during AD, and there are always causes explaining psychological symptoms. Thus, why AD patients can suffer from anxiety and depression? Which are the causes for the occurrence of these symptoms in patients with AD?
Research on the theme is heterogeneous relatively to the aims and the methodology of the studies. Most of the published studies on this theme had different aims but presented suggestions that answer to this clinical question in comment to their evidence. Moreover, singly consulted, they offer partial explanations to this clinical phenomenon that, instead, is complex. Furthermore, other reviews on anxiety and depression in AD did not specifically deal with the pathogenetic hypothesis on their comorbidity and suggest the analysis of the basic mechanisms explaining the prevalence of anxiety and depression in AD [6, 17, 18].
Therefore, according to these considerations, it could be useful to analyse deeper and resume literature evidence on this topic, combining different data and providing a bio-psycho-social frame to explain why AD patients can suffer from anxiety and depression. Hence, this systematic review had the aim to collect the evidence published to date that answer the above-presented clinical question. This question can be declined into two sub-hypotheses: anxiety and depression in AD could be due to pathogenetic mechanisms and there could be a relationship between them and cognitive decline. Thus, the purposes of this systematic review were to explore the pathogenetic hypothesis provided to explain the comorbidity of anxious and depressive symptomatology and AD and to assess the association between anxious and depressive symptoms and the AD-related cognitive impairment.
Methods
The systematic review (PROSPERO registration n. CRD42019126592) was conducted according to the recommendations of the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) criteria [19]. The study was approved by “Comitato Etico Interaziendale A.O.U. San Giovanni Battista di Torino A.O. C.T.O./Maria Adelaide di Torino”: protocol number 0034410, procedure number CS2/1179, date of approval: 29/03/19.
Search strategy
The literature search was performed in October 2020 on PsycINFO, Embase, MEDLINE, and CINAHL databases. Then, a search update followed in March 2021 on the same databases. The search was conducted by L.C., a librarian expert in data extraction from databases, using keywords including the following terms (MeSH and free words): (“Alzheimer’s disease” [MeSH] OR (Alzheimer disease) OR (Alzheimer) OR Dementia [MeSH]) AND (“Anxiety” [MeSH] OR (Anxiety Disorder) OR (anx) OR “Depression” [MeSH] OR (Depressive Disorders) OR (Stress, Psychological)). See online resource “SM 1” for the details of the search strategy.
Study eligibility criteria
Only full-text original articles published in English language on peer-reviewed journals were included in the search. In detail, studies with longitudinal, prospective, cross-sectional, multicentre, evaluative, or comparative designs, and not assessing interventions were analysed. Furthermore, studies had to be on patients with a diagnosis of AD. Diagnosis of AD had to be done using approved diagnostic criteria, i.e., those of DSM-III-R, DSM-IV, DSM-IV-TR, NIA-AA, NINCDS-ADRDA, ICD-10, CERAD, and Braak stage. No age-filters were used. Finally, they had to investigate symptoms of anxiety and/or depression; then, they had to propose pathogenetic hypothesis on anxiety and depression in AD and/or to investigate the association between anxiety and/or depression and cognitive impairment.
The exclusion criteria were (1) literature reviews; (2) systematic reviews; (3) meta-analysis; (4) case reports or case series studies; (5) clinical trials; (6) studies not including patients with AD (i.e., studies including patients with frontotemporal dementia, vascular dementia, Parkinson disease, mixed dementia, post-traumatic dementia, Huntington disease, dementia with Lewy bodies, and HIV-associated dementia); (7) studies not evaluating anxiety or depression; (8) studies evaluating anxiety or depression but not proposing pathogenetic hypothesis on anxiety and depression in AD or not investigating the association between anxiety and/or depression and cognitive impairment; (9) studies not published and not peer-reviewed; and (10) health policies and guidelines.
Studies of grey literature (theses, abstracts, books, dissertations) were not included in the search considering the high number of peer-reviewed articles published on the topic.
No limitations were established on publication data of the studies. No limitations were established on methods of anxiety and depression assessment on condition of these criteria: studies had to assess anxiety and/or depression using validated scales or structured interviews.
Data collection and analysis
Two researchers (NC and AC) identified the potential studies of interest, screening titles, and abstracts. All the studies that did not meet all the inclusion criteria or that complied with almost one exclusion criterion were excluded.
Then, the remaining studies were screened reading their full text, and the selected articles were revised to verify whether they fulfilled the inclusion criteria. If there was any disagreement in the study selection, a third investigator (RB) read the article and NC, AC, and RB decided together for the inclusion of the article in the review or not.
All the studies selected for the review were revised considering the country, objectives, design, sampling and sample size, outcome measures, and results.
Any direct contact with authors was necessary with the following exception: for Panegyres et al.’s study [20], information was missing for the tools used to assess anxiety and depression. So, the people responsible for the C-Path Online Data Repository used by authors were contacted and they provided the missing information.
Risk of bias
We assessed the quality of the included articles using the Newcastle–Ottawa Quality Assessment Scale (NOS) [21], a standardized instrument used to critically review nonrandomized studies with its design and content. Two independent investigators (A.C. and N.C.) analysed each article. Scores ranged from 0 to 9 points, with higher scores indicating higher study quality. We considered NOS scores of 0–3, 4–6, and ≥ 7 to indicate low, medium, and high quality, respectively.
Results
The identified potentially relevant studies, resulting from the searches on the abovementioned databases, were 14,760. Of these, 4700 were on PsycINFO, 1351 on Embase, 4738 on Ovid, and 3971 on CINAHL. After comparison of the databases, 3888 duplicates were removed.
Screening titles and abstracts, 10,798 studies were identified as not meeting the inclusion criteria or fulfilling almost one exclusion criterion and were excluded.
Then, the full texts of the 74 articles considered relevant for the inclusion in the review were analysed. Of those, 40 were excluded because they did not meet the inclusion criteria, or they meet almost one exclusion criterion.
Finally, 34 papers were included in the systematic review after the end of the screening process.
The selection procedure is represented through a flow diagram in the online resource “SM 2.”
Methodological aspects
Country
Fifteen studies were conducted in the USA [22,23,24,25,26,27,28,29,30,31,32,33,34,35,36], 2 in Germany [37, 38], 2 in the Netherlands [39, 40] (Banning et al. [35] conducted their study both in the USA and in Netherlands), 1 in Singapore [41], 2 in Japan [42, 43], 1 in Sweden [44], 2 in Argentina [45, 46], 3 in England [47,48,49], 1 in Australia [20], 2 in France [50, 51], 1 in Italy [52], 1 in China [53], and 1 in Norway [54].
Objectives
Of the 34 studies, 17 explored the pathogenetic hypothesis that explains the comorbidity of AD, anxiety, and/or depression. Among these, 4 evaluated the association between anxiety, depression, and AD biomarkers; 8 evaluated whether anxious and depressive symptomatology in AD arise after the diagnosis of AD or as a reaction to perceived cognitive decline. Ten studies investigated whether anxiety and/or depression can influence the cognitive functions, 3 evaluated the prevalence of depressive and anxiety symptoms, 2 assessed the trajectories of depression, 1 examined if depression is a risk factor for the onset of AD, and 1 study explored clinical differences between early-onset AD and late-onset AD patients.
Study design
Of the 34 studies, 12 were longitudinal studies, 9 were cross-sectional studies, 1 was a comparative study, 1 was a multicentric study, 5 were prospective studies, 2 were retrospective studies, 1 was a cohort observational study, 2 were prospective longitudinal studies, and 1 was a retrospective longitudinal study.
Sample
The samples consisted of 12,512 elderly patients with diagnosis of AD or with probable AD in total. All the screened studies included both genders, predominantly women (56.4%). Patients’ mean age was 73.82 ± 6.8 years (range = 57.7–86.2). Relevant variability among studies was observed in the number of participants. Sample sizes ranged from 20 to 3747 AD patients.
The AD duration varies between studies: in 14 studies, patients suffered from AD from less than 6 years, and in 5 studies, patients suffered from AD from at least 7 years. The authors of the remaining studies did not provide precise data on AD duration.
At the time of the assessment, most patients were in a mild-to-moderate AD stage. Only in 4 studies, participants were patients with severe AD [24, 39, 41, 47].
In addition to AD, patients also showed a comorbidity of depression and/or anxiety. Of all the samples, 18 consisted of subjects with AD and depression; 5 consisted of subjects with AD and anxiety; and 5 included subjects with a comorbidity of AD, and depressive and anxious symptoms. In the other samples, during the study, patients with AD developed depression or anxiety.
About the samples of the included studies, only 2 of them were from psychiatric settings [28, 38] and only 1 was from primary care [26]. Most samples were from dementia specialty clinics. Among them, 15 were from outpatient settings, 4 were inpatient settings, 2 nursing home settings, and 3 in-home settings. The other remaining studies, instead, did not provide further information on the sample.
Outcomes assessment
For AD diagnosis, 26 studies used criteria established by the NINCDS-ADRDA [55] and 1 study [36] also used NIA-AA criteria [56]. Two studies [38, 54], instead, used ICD-10 diagnostic criteria, while the Diagnostic and Statistical Manual of Mental Disorders third edition revised (DSM III-R) [57] and the fourth edition (DSM IV) [58] have been used in 6 studies, respectively, for AD diagnosis [29, 43, 44] and for dementia diagnosis [35, 36, 40]. In one study [39], AD diagnosis was neuropathologically confirmed in post-mortem using the Consortium to Establish a Registry for AD (CERAD) criteria [59].
Few studies [39, 41, 48] also performed the staging of the severity of AD neuropathology, using the Braak staging scheme [60]. For the assessment of the cognitive impairment, the Mini Mental State Examination (MMSE) [61] was used in almost all the studies.
Most studies evaluated anxiety and depression using the Neuropsychiatric Inventory (NPI) [62], the DSM III-R/DSM IV criteria [57, 58], the Hamilton Depression Rating Scale (HDRS) [63], and the Hamilton Anxiety Rating Scale (HARS) [64].
Risk of bias assessment
The risk of bias assessment of the included studies showed high-quality design in most of our studies (25 out of 34), while the rest appeared with a medium risk of bias (9 out of 34). A closer analysis revealed that most of the research did not clarify the duration of the follow-up or how many patients concluded it; some articles lost “stars” within the “comparability category”; finally, several studies did not specify in detail the history of the investigated disease. The table in the online resource “SM 3” shows the results of the risk of bias assessment, specifying how many “stars” we evaluated in each included study.
Results
Pathogenetic hypothesis for anxiety, depression, and AD comorbidity
Depression and anxiety occur throughout the AD course both due to brain damage and psychosocial factors [43, 49, 54].
Higher anxiety levels seemed to be associated with higher strychnine-sensitive glycine receptor (GlyRS) functioning and selective reduction of N-methyl-d-aspartate (NMDA) receptor NR2A density [41]. Anxiety in AD could be explained by the atrophy in the right precuneus and inferior parietal lobule and hyperperfusion of the bilateral anterior cingulate cortex [42]. Higher anxiety was associated with lower resting metabolism in the bilateral entorhinal cortex, anterior parahippocampal gyrus, left anterior superior temporal gyrus, and insula [30].
Depression was associated with AD pathology, i.e., lower CSF Aβ42 and higher t-tau and p-tau levels [36], to atrophy of the insula, the inferior frontal lobe, and the limbic neural networks, and to changes in the temporal and parietal regions, including supramarginal, superior and inferior temporal and fusiform gyri, right posterior cingulate and precuneus, locus coeruleus, and basal nucleus of Meynert [22, 35, 44, 47, 53]. Depression can be determined by decreased cortical metabolism, neuritic plaques, and neuronal damage in the temporal cortex that lead to disinhibition of the HPA-axis. On the other hand, the association between depression, HPA hyperactivity, and cardiovascular disease can determine AD progression [39]. AD development seems to stop the continuity of the depressive state due to impaired memory and executive control [32]. Affective symptoms and the expression of the depressive symptoms tend to reduce as AD progresses [48, 53]. Dysthymia was primarily in the early stages of AD, as an emotional reaction to the progressive cognitive decline, while major depression may be related to biological factors and is a symptom of the neurodegenerative AD processes [26, 38, 45].
Banning et al. [35] explained anxiety in AD as an initial compensating behaviour, while depression could be more related to AD awareness or to the psychological reaction to AD, and to relational and biological factors [36]. Depression can also be reactive to AD-related loss of functional ability [29, 31, 33].
Anxiety and depression were higher in patients with early-onset AD compared to patients with late-onset AD due to the following factors present in early-onset AD patients: greater changes in lifestyles, roles, and responsibility; poor social adjustment; cognitive impairment; dementia severity; and more rapid progression [20, 34, 43, 49]. Van Vliet [40] evidenced that in late-onset AD, depression was more persistent and was the most prevalent symptom, probably due to contextual factors, i.e., death of a loved one or physical disability (see Fig. 1).
Association between anxiety, depression, and cognitive impairment
Cognitive impairment seemed to mediate the association between the presence of anxiety, lower CSF levels of Ab42, and higher levels of CSF t-tau and p-tau [35]. Lower inhibition performance on Stroop test was associated with subsequent higher risk of anxiety and depression, due to the involving of anterior cingulate cortex [51]. Association of depressive symptoms and cognitive impairment seems to be independent of cortical plaques and tangles [25].
Depressive symptoms in AD were associated with a greater severity of cognitive impairment [26, 28, 37] and additional cognitive impairment, i.e., frontal planning impairments, disappear or improve with remission of depression [52].
Depression did not increase as mild cognitive impairment developed [32]. It could be an early reaction to perceived cognitive decline [50].
Depression can cause cognitive impairment [48, 54], but it seems to have no impact on cognitive functions during the early and advanced stages of AD [48].
Cognitive impairment was associated with a small reduction in mood symptoms and a modest increase in somatic symptoms: the AD progression determines the degradation of the ability to experience or express emotion [27] (see Fig. 2).
A summary of the 34 studies included in the systematic review is reported in Table 1.
Discussion
The review aims to provide a bio-psycho-social frame to explain why AD patients can suffer from anxiety and depression, considering the phenomenon in its complexity. Thus, multiple pieces of punctual evidence have been combined to resume and conceptualize the literature state of the art on reasons underlying the comorbidity between anxiety, depression, and AD. For this reason, the results of the studies analysed in this review are heterogeneous because they consider not only biological, but also psychosocial aspects and they deal with AD in all its different phases relative to its progression. They evidence that both anxiety and depression could be due to brain damage on the one hand and psychosocial factors on the other.
The neurodegeneration of neural areas and circuits dealing with emotions can determine hyperactivation and disinhibition of the HPA axis that can elicit the anxious and depressive symptoms. In this regard, it has been hypothesized that hyper perfusion and atrophy of cerebral areas—i.e., anterior cingulate cortex, precuneus and parietal lobule—but also receptor alterations—i.e., NMDA receptor—could be linked to depressive symptoms [41, 42]. This condition of chronic distress, in turn, can lead to neurodegeneration and contribute to AD progression. Then, during the late AD stages, the high rate of brain damage could stop the depressive condition due to the impairment of memory and the executive functions, and the intensity and expression of the affective symptoms are reduced. This phenomenon could be present because a more severe cognitive decline is frequently associated with loss of insight in AD [65]. Stronger negative emotions require a good cerebral function: if the cognitive impairment is too serious, patients will not be able to produce this type of emotional response [27, 37].
On the other hand, the early stages of AD seem to be characterized by dysthymia, as an emotional reaction to the cognitive decline, and anxiety, as an initial compensating behaviour. During the initial phases of AD, depressive symptoms can manifest due to AD awareness, the impairment of the socio-relational functioning, and the loss of functional abilities. Thus, in this phase, anxiety and depression could arise due to difficulties in the adaptation to the disease and represent the psychological response to the loss of self-sufficiency and independence [14, 15, 35]. Instead, major depression could be more related to biological factors, such as neurotransmitters and endocrine alterations or cortical apoptosis.
Literature evidence also differences in anxiety and depression between early-onset and late-onset AD. They seem to be more intense in early-onset AD due to more changes in lifestyles and life roles, to more responsibilities to cope with and to poorer social adjustment to the disease. Moreover, early-onset AD is often characterized by more rapid progression, dementia severity, and cognitive impairment and this can promote the psychological symptoms. The late-onset AD can occur in the elders in comorbidity with other concerns, such as physical disability or bereavements. Thus, in late-onset AD, depressive symptoms are the most prevalent and seem to be more persistent.
The results of the studies show an association between anxiety, depression, and cognitive decline. Anxious and depressive symptoms can manifest as an initial psychological reaction to the cognitive impairment. Furthermore, on its turn, depression can impact on the cognitive functioning, causing an increase of the cognitive deficits: i.e., during the remission of the depressive symptoms, the capacities of planning mediated by the frontal circuits improve. This role of influence of depression on cognition has been observed only in the intermediate AD phases.
Finally, higher cognitive impairment is associated with higher somatic symptoms of anxiety and depression and lower affective symptoms. This could be due to reduced metacognitive possibilities to experience and express emotions.
The methodology of the symptoms’ assessment could have moderated the abovementioned findings.
Assessment tools more specifically dedicated to the analysis of anxiety and depression in AD can estimate symptoms differently than those provided by more generic criteria, such as the DSM or the ICD [66, 67]. In this regard, Vilalta-Franch and colleagues [67] hypothesized that the degree of rigidity of the included criteria could influence the diagnosis. Furthermore, they observed that the use of the Neuropsychiatric Inventory (NPI) can be biased by the fact that caregivers usually overestimate patients’ depressive symptoms due to their own distress [68, 69].
The minority of studies performed longitudinal research designs, so further research with longitudinal observations is needed to better explore the variation of anxiety and depression along the AD course. Moreover, few studies assessed the AD severity, despite it emerging as a factor playing a role with respect to the considered psychological symptomatology. Another limitation of the studies is that they have used different AD diagnostic criteria, such as NINCDS-ADRDA, NIA-AA, DSM, and ICD. Furthermore, NINCDS-ADRDA, although it is the most used and more valid than the other diagnostic criteria, is less accurate than the currently used NIA-AA criteria. Large criteria for source search have been preferred to more stringent ones to collect and mix more evidence. At the same time, they reduced quality and homogeneity of evidence. In fact, NOS scores indicated that the quality of the included studies is not high, and studies were heterogeneous in aims, types of assessment, sampling, participants, AD duration, and neuropsychological assessment, that in most cases were not adequate. In this regard, also time impacted on method heterogeneity between older studies and the more recent ones, because the assessment criteria have changed and improved over time. Implementing more circumscribed reviews could preserve research quality and favour a more specific, detailed, and reliable comprehension of the described clinical phenomena. Moreover, most studies assessed anxiety and depression when AD was mild or moderate and not severe: this is understandable considering the serious cognitive decline that characterizes the AD advanced phases and hinders the psychological assessment, but, at the same time, it limits the exploration of anxiety and depression in patients with severe AD. Finally, AD is often present in comorbidity with dementias due to other causes, such as the vascular one. So, it would be useful to study anxiety and depression also in clinical condition of multiple dementias.
Conclusion
The neurodegeneration of areas and circuits dealing with emotions can elicit the anxious and depressive symptoms that, in their turn, can lead to neurodegeneration. In the early AD stages, anxiety and depression could arise as a psychological reaction to the disease and due to difficulties in the adaptation to AD. During the late AD stages, the serious cognitive impairment reduces the emotional responses and their expression. Finally, anxiety and depression are more intense in early-onset AD, due to the major impact of AD on the individual.
Further research, especially with longitudinal design, considering all the AD stages, performing adequate neuropsychological assessment, and investigating psycho-social factors are needed to better clarify the comorbidity between depression, anxiety, and AD.
Data availability
Data sharing is not applicable to this article as no datasets were generated or analysed during the current study.
Change history
19 July 2022
Missing Open Access funding information has been added in the Funding Note.
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Botto, R., Callai, N., Cermelli, A. et al. Anxiety and depression in Alzheimer’s disease: a systematic review of pathogenetic mechanisms and relation to cognitive decline. Neurol Sci 43, 4107–4124 (2022). https://doi.org/10.1007/s10072-022-06068-x
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DOI: https://doi.org/10.1007/s10072-022-06068-x