The literature search was conducted on the following electronic databases, in the following order: PubMed, Scopus, and Web of Science. The search was limited to articles published between January 2000 and July 2022. This time period was selected due to the fact that research in the last 10 years has identified atypical profiles of AD; therefore, the search start date had to be extended to the year 2000 to obtain a general perspective of both typical and atypical AD. The general search strategy was as follows: (Alzheimer disease AND Lewy body dementia) AND (cognitive function OR memory OR executive function OR attention OR visuoconstructive skills OR visuospatial skills OR processing speed OR language) AND (neuropsychological assessment OR cognitive tests OR neuroimaging OR differential diagnosis). All terms were adapted to each database. The complete search strategy for each database is included in the Supplementary material (Appendix 2).

We applied the following inclusion criteria for screening by title and abstract: a) analytical observational studies of diagnostic tests, reporting neuropsychological assessment and/or neuroimaging study results; b) studies written only in English; and c) including patients aged at least 60 years with a clinical diagnosis of AD or LBD. We excluded the following types of article: a) editorials, experimental studies, systematic reviews with or without meta-analyses, study protocols, and theses; b) studies including patients with mixed dementia or pseudodementia; and c) studies including patients with history of psychiatric disorders (e.g., psychosis, schizophrenia).

Studies were imported to the Rayyan software43 to eliminate duplicate articles. Subsequently, 2 reviewers (VMC and DTR) applied the inclusion and exclusion criteria to the titles and abstracts of all articles. In the event that decisions could not be made based solely on the title and abstract, full texts of the articles were retrieved. A third reviewer (TJR) participated in the final selection of articles included for review, resolving disagreements through discussion where necessary.

To evaluate the methodological quality and risk of bias of the articles selected, we used the QUADAS-2 tool,44 an instrument designed and validated for the independent evaluation of methodological quality and risk of bias in studies of diagnostic accuracy. This instrument evaluates 4 key domains: patient selection, the index test, the reference standard, and the patient flow and timing of the study (the latter 2 aspects are grouped together into the domain “flow and timing”). Studies were classified into one of 3 risk categories: high, low, or unclear. Methodological quality was assessed according to the domains patient selection, index test, and reference standard, and was classified as high, low, or unclear.

Table 1 presents a narrative synthesis of our findings. This synthesis summarises the general characteristics of the studies reviewed, such as study population, mean age, and the instruments/measures used. It also presents the main findings regarding the neuropsychological similarities and differences between AD and LBD, with the neuroimaging profiles reported.

The PRISMA flow diagram in Fig. 1 illustrates the article selection process.42 We identified the titles and abstracts of 447 articles, 50 of which were duplicates. We excluded 202 articles after application of the selection criteria. Of the 195 full-text articles screened for eligibility, 154 were excluded. Therefore, a total of 41 articles were included in the systematic review for qualitative analysis.

Figure 1.

PRISMA flow chart.

Table 1 shows the general characteristics of the 41 articles included for review. The year in which the greatest number of articles were published was 2017 (6 articles), with the years 2019, 2007, 2006, 2005, 2004, 2001 presenting the lowest number of articles (one each). The selected studies included a total of 8780 patients, with a mean age of 75.2 years (range, 60–80; standard deviation [SD]: 7.0). A total of 4498 (57%) were men.

Regarding the main neuropsychological findings, the results suggest that the cognitive domains of memory, attention, executive function, visuospatial/visuoconstructive skills, and verbal fluency (both semantic and phonological) are key aspects in the differential diagnosis of AD and LBD. From an anatomical/functional perspective, the pattern of atrophy in the frontal, parietal, and temporal lobes, as well as the hippocampus and precuneus, seems to enable differential diagnosis between the 2 disorders. However, the results underscore that the level of functional connectivity is reduced in sensorimotor, temporal, basal ganglia, thalamic, insular, and anterior cingulate networks in LBD, whereas in AD it is reduced in frontal and temporal areas, with increased connectivity in the posterior cingulate and hippocampus. This is a relevant finding, as this may be a useful indicator for establishing an early, accurate diagnosis.

Finally, the neuropsychological instruments and measures most frequently used to diagnose AD and LBD were the Mini–Mental State Examination (MMSE), Montreal Cognitive Assessment (MoCA), Boston Naming Test (BNT), Trail-Making Test (TMT) parts A and B, Frontal Assessment Battery (FAB), FAS verbal fluency test, and Cambridge Cognition Examination (CAMCOG). The most frequently used neuroimaging techniques were MRI, fMRI, and PET, which are combined to establish an anatomical-functional correlate (Table 1).

The 41 articles selected were analysed using the QUADAS-2 tool (Fig. 2).44 In the risk of bias assessment, the domains patient selection and flow and timing presented low risk of bias in 95% of studies and unclear risk in 5%. In the index test domain, 90% of studies presented low risk, 5% presented high risk, and 5% presented unclear risk. In the reference standard domain, 93% of studies presented low risk, 5% presented high risk, and 2% presented unclear risk. In turn, in the assessment of methodological quality, 95% of articles presented high quality for patient selection, compared to 90% and 93% for index test and reference standard, respectively.

Figure 2.

Assessment of risk of bias and methodological quality.

Our findings suggest that episodic memory is impaired in both conditions. However, the deficit is more severe in AD; this is consistent with the results of previous studies.13,89 In contrast, Calderon et al.20 report that episodic memory impairment does not differ between the 2 diseases; in fact, they suggest that working memory is more severely affected in LBD. Significant differences were also observed in the ability to consolidate information, with AD showing severe deficits mainly affecting delayed recall and verbal memory.45

Another recent study90 notes that analysis during the pre-dementia stage is key to differentiating between patients who will progress to AD or LBD. The results suggest that patients in the mild cognitive impairment stage who present mild memory deficits tend to progress to LBD, whereas progression to AD is associated with severe memory impairment. Previous studies91–93 report that this performance is also observed in patients with subjective memory complaints. Similarly, Lemstra et al.94 highlight the relevance of LBD co-occurring with AD, as memory decline tends to be severe in these patients, even at early stages. Nonetheless, the results reported in the literature are contradictory, with other studies suggesting that memory performance is better in patients with AD plus LBD than in those with pure AD19,95; on the other hand, Azar et al.30 suggest that memory impairment is no different in patients with AD and concomitant LBD. These discrepancies may be explained by differences in sample size. It should also be noted that there is a clear overlap in the cognitive symptoms and patterns of brain involvement between AD and AD plus LBD; as a result, differential diagnosis is relatively imprecise.77,96

Attention deficit and executive function decline were identified as cognitive markers for the differential diagnosis of AD and LBD. In line with our own findings, Xu et al.97 report that both domains are more severely impaired in LBD than in AD. Furthermore, several authors98–100 suggest that selective attention is a differential cognitive marker in early stages. Although attention deficit manifests early in AD, it is more evident in moderate and severe disease.71 However, other studies present contradictory results,101–103 suggesting that divided attention is key to differentiating between these diseases, as it is more severely impaired in LBD.

Regarding executive function, specific subdomains are proposed for differential diagnosis. For instance, the evidence suggests that inhibitory control97,104,105 and cognitive flexibility50,106–109 are affected in LBD. In contrast, Bailon et al.110 and Bussè et al.103 suggest that cognitive flexibility does not present significant impairment in LBD. Similarly, discrepancies were also observed regarding performance in abstract reasoning tasks and conceptual skills. While some authors assert that these domains are unaffected,105,108 Perri et al.111 report severe impairment in patients with LBD compared to those with AD.

Visuoconstructive and visuospatial deficits are observed in both AD and LBD. Ferman et al.107 note that visuoconstructive impairment enables accurate differentiation between LBD, AD, and healthy elderly adults (sensitivity: 80%; specificity: 90%). Similarly, other studies suggest that visuoconstructive skills are severely impaired in LBD, whereas AD is associated with severe impairment of episodic memory, favouring differential diagnosis.112–114 Furthermore, these studies report that early stages are crucial in identifying the deficit, as motor symptoms in advanced stages of LBD contribute to diagnostic errors.

Visuospatial skills are also proposed as a key element in differential diagnosis. Classically, severe visuospatial deficit has been considered a differentiating factor in LBD66,77,95,98; however, interesting findings are also reported in AD. It has been suggested that deficits in these skills may be the first cognitive manifestations of AD, with the initial stage being fundamental to distinguishing it from LBD.115–118

Changes in visuoperceptual skills have been associated with these diseases; among the different types of visuocognitive ability, these skills stand out for their high complexity. Visuoperceptual skills are reported to be significantly impaired in LBD, enabling differentiation from AD at early stages.22,54,62,76,119,120 However, other studies report diverging results, with these deficits also having been observed in preclinical and mild AD.121,122

Various studies62,105,106,123 report that patients with LBD present severe impairment of semantic and phonological verbal fluency, as well as deficits in naming. Ralph et al.22 support this hypothesis, but note that patients with typical AD present better phonological performance. Other researchers124–126 argue that the deficit in semantic verbal fluency in AD is due to a loss of semantic knowledge. Similarly, patients with LBD also show language impairment, but this differs from that observed in AD in that lexical and semantic abilities are spared.127 Additionally, it should be noted that verbal fluency tests involving verbs have also been proposed as cognitive/linguistic markers. For instance, Delbeuck et al.128 found that patients with LBD were able to produce higher numbers of verbs than those with AD.

The studies reviewed frequently used the MMSE and MoCA test to evaluate cognitive performance. The MMSE is a brief, simple cognitive screening test, but is unable to exhaustively assess the different cognitive domains. However, its use is encouraged in clinical practice as it is able to detect progression of cognitive impairment and to differentiate AD from LBD. In fact, patients with LBD show significant reductions in scores at annual follow-up visits compared to those with AD.84,88,129 Similarly, longitudinal studies80,130,131 highlight the rapid decline observed in MMSE scores in LBD. Although the MMSE is more useful than the MoCA test for identifying cognitive impairment in LBD,132 it is not recommended for studying progression of the diagnosis and cognitive decline in longitudinal studies.133 Using the MMSE to monitor disease progression is only helpful in more advanced stages of LBD (General Deterioration Scale scores > 4), as results are often normal in earlier stages, when abnormal results indicate an amnestic profile suggesting copresence of AD. Furthermore, variation is reported in MMSE scores, which differ significantly in LBD (lower scores on the MoCA test and higher scores on the MMSE).134

Our results showed that the Free and Cued Selective Reminding Test is not frequently used, despite its demonstrated efficacy in identifying patients with AD.135 Bussè et al.136 studied the test’s effectiveness for differentiating LBD from AD, finding that although patients with LBD presented greater overall performance, total recall and delayed free recall were key to differentiating the 2 diseases.

Language evaluation is mainly based on such tests as the BNT, FAS, semantic verbal fluency, and the language subdomains of the CAMCOG. Although these tools offer a general view of language performance, they do not assess specific subdomains in detail. For instance, the Mini–Linguistic State Examination (MLSE),137 recently validated for classifying primary progressive aphasia in Spanish-speaking populations,138 may be useful for better characterising language deficits in AD and LBD based on phonology, semantics, and syntax (including working memory). However, language evaluation should also consider spontaneous language, which is thought to play a key role in differentiating between these 2 diseases.139

Structural MRI is frequently used to diagnose AD and LBD, and is able to identify structural damage and grey matter loss. Previous studies140–142 confirm these findings, highlighting the overlap between the patterns of atrophy in LBD and in AD. However, atrophy is more diffuse in LBD, with moderate preservation of the medial temporal lobe. Similarly, several other studies143–145 report that atrophy in AD involves not only the temporal lobe, but also the cingulate, parahippocampal regions, and the precuneus. In LBD, cortical thinning is reported to affect superior temporo-occipital regions, the lateral orbitofrontal cortex, and the posterior and medial cingulate cortex.143–145

Furthermore, fMRI studies show greater connectivity in the inferior parietal cortex and putamen in LBD, whereas patients with AD display greater connectivity in frontoparietal areas, the medial prefrontal cortex, the primary visual cortex, and the left hippocampus.146,147 In contrast, Schumacher et al.47 recommend caution in the interpretation of fMRI results, as the increase in frontotemporal connectivity in LBD overlaps with that reported in AD.

The growing interest in establishing an accurate differential diagnosis between AD and LBD has promoted the use of PET studies. This technique is useful for identifying AD and for distinguishing it from LBD, with the hippocampus being the region of interest. Tau-PET reveals greater concentration of tau protein in the hippocampus in AD, with more moderate concentrations in LBD.148–150 Furthermore, FDG-PET results show hypometabolism in the occipital region in LBD, with sparing of the posterior cingulate, whereas hypometabolism in AD affects temporo-occipital regions.5 Finally, Marquié et al.151 suggest that the radiotracer 18F-AV-1451 in tau-PET studies may be a potential biomarker for differential diagnosis, as it presents high affinity for tau neurofibrillary pathology in AD.

This study presents 4 significant limitations. Firstly, the review does not include a meta-analysis, which would improve the interpretation of the neuropsychological and imaging findings in AD and LBD. Secondly, only 3 databases were consulted (PubMed, Scopus, and Web of Science). Future studies should search a larger number of databases to obtain a global view of the differential diagnosis of these diseases. Thirdly, the search strategy was limited, focusing only on observational studies of diagnostic tests and excluding other study designs and even neuropathological diagnosis. Similarly, given the range of years of publication, we consider that there is a need for future studies in this area to take into account updates to diagnostic criteria. Finally, we excluded atypical AD profiles, such as primary progressive aphasia and posterior cortical atrophy, as numerous studies suggest that these share symptoms with LBD.152–155

To our knowledge, this is the first systematic review addressing differential diagnosis between AD and LBD that considers both the neuropsychological profile and the anatomical/functional correlates of each disease. These findings are valuable beyond the research setting, contributing directly to improving screening and accurate differential diagnosis in the early stages of both diseases.

Future studies should consider using fMRI to comprehensively analyse semantic and phonological processing and to analyse connectivity patterns in brain areas responsible for language processing in AD and LBD. A final future challenge will be to promote studies that expand clinical diagnosis beyond neuropsychological symptoms and the pattern of atrophy, seeking to characterise the complete neuropsychiatric picture of each disease. Regarding the characteristics of psychoemotional interaction and social cognition, there is a need for deeper understanding of abilities related to the theory of mind, as few studies have examined the relationship between these processes and neuropsychiatric symptoms in early stages of dementia.156,157