Abstract
There is poor knowledge about the clinical effects of Lewy body (LB) pathology in patients with cognitive impairment, especially when coexisting with Alzheimer’s disease (AD) pathology (amyloid-β and tau). Using a seed amplification assay, we analyzed cerebrospinal fluid for misfolded LB-associated α-synuclein in 883 memory clinic patients with mild cognitive impairment or dementia from the BioFINDER study. Twenty-three percent had LB pathology, of which only 21% fulfilled clinical criteria of Parkinson’s disease or dementia with Lewy bodies at baseline. Among these LB-positive patients, 48% had AD pathology. Fifty-four percent had AD pathology in the whole sample (17% of mild cognitive impairment and 24% of patients with dementia were also LB-positive). When examining independent cross-sectional effects, LB pathology but not amyloid-β or tau, was associated with hallucinations and worse attention/executive, visuospatial and motor function. LB pathology was also associated with faster longitudinal decline in all examined cognitive functions, independent of amyloid-β, tau, cognitive stage and a baseline diagnosis of dementia with Lewy bodies/Parkinson’s disease. LB status provides a better precision-medicine approach to predict clinical trajectories independent of AD biomarkers and a clinical diagnosis, which could have implications for the clinical management of cognitive impairment and the design of AD and LB drug trials.
Similar content being viewed by others
Main
Neurodegenerative diseases are a leading health problem, given their devastating effects on quality of life, their high prevalence and the progressive global increase in life expectancy, which will increase their prevalence even more. The development of biomarkers allowing the in vivo detection of the different neurodegenerative pathologies underlying cognitive or motor decline is a crucial step for a timely diagnosis, accurate prediction of disease progression and the stratification of patients for clinical trials1. Neurodegeneration is often characterized by accumulation of misfolded proteins, where the most common are amyloid-β (Aβ) and neurofibrillary tau pathology in AD, the leading cause of dementia worldwide. The second most common proteinopathy in dementias is LB pathology, which is characterized by intracellular aggregates of misfolded α-synuclein (α-syn) forming LBs and Lewy dystrophic neurites that can manifest as both dementia with LB (DLB) and Parkinson’s disease (PD), collectively referred to as Lewy body disease (LBD)1,2. Cognitive impairment due to neurodegenerative diseases is often multifactorial and co-pathologies may contribute to the clinical phenotype, disease progression and response to treatment. For example, AD neuropathological changes are frequently seen together with LB pathology3, but it is unclear how this affects clinical phenotypes, especially regarding longitudinal trajectories of different cognitive and motor functions in different clinical disease stages. Biomarkers that identify a range of different proteinopathies in vivo may provide a precision-medicine approach to the diagnosis and prognosis of patients with neurodegenerative diseases. Positron emission tomography (PET) imaging and cerebrospinal (CSF) markers detecting Aβ and tau pathology in AD have been increasingly used to provide in vivo confirmation of AD pathology1,4. The development of in vitro seed amplification assays (SAAs) that indirectly detect misfolded α-syn in CSF and other tissues has recently provided a pathology-specific biomarker for LBD5. Notably, CSF analysis of α-syn seeding activity by SAA has shown very high diagnostic accuracy in detecting LB pathology in studies validated by postmortem neuropathological data6,7,8,9 and for clinically diagnosed PD and DLB7,8,10,11,12. The availability of a biomarker for LB pathology offers a new opportunity for the characterization of neurodegenerative pathologies underlying cognitive impairment and can be used to evaluate their relative contribution to phenotypic expression and disease progression. Adding the LB status to the established Aβ and tau biomarker profile13, we aimed to study the independent effects of LB and AD pathologies on cognitive and neurological deficits in memory clinic patients with mild cognitive impairment (MCI) or dementia from two well-characterized cohorts (the Swedish BioFINDER-1 (n = 398) and BioFINDER-2 (n = 485) studies).
Results
Participants and prevalence of AD and LB pathologies
Aβ pathology was determined using CSF Aβ42/40, tau pathology using tau-PET or CSF phospho-tau217 (P-tau217) and LB pathology using CSF α-syn real-time quaking-induced conversion (RT-QuIC), an established SAA. AD positivity was defined as being Aβ and tau positive according to the criteria of the National Institute of Aging-Alzheimer’s Association13 and the International Working Group4 and LB positivity as being α-syn SAA-positive; AD and LB positivity refer to the biomarker status, not the clinical diagnoses, which were determined differently and not included in any statistical analyses (Methods)14. Biomarker status was determined at the study baseline. The prevalence of Aβ (A), tau (T) and LB, as well as different combinations of biomarker positivity, is shown in Fig. 1a–c with further patient characteristics in Table 1 and Extended Data Table 1. In patients with cognitive impairment, 302 (34%) had no AD or LB pathology (AD−/LB−). This group consisted clinically mostly of vascular cognitive impairment, frontotemporal dementia and other non-AD and non-LBD causes of cognitive impairment (Extended Data Table 1). Overall, 204 patients (23%) had LB pathology and 475 (54%) had AD pathology. LB pathology occurred with similar prevalence as isolated pathology (AD−/LB+, n = 106; 12%) and as co-pathology with AD (AD+/LB+, n = 98; 11%). In the AD+ group, 36 (17%) patients with MCI and 62 (24%) with dementia were also LB+. At baseline, 21% of LB+ participants fulfilled the clinical criteria for PD15 (n = 14) or DLB (n = 28) (refs. 16, 17) and 49% (n = 232) of AD+ patients fulfilled the clinical criteria for AD (MCI or dementia stage) (Table 1). The prevalence of follow-up diagnoses is shown in Extended Data Table 1 (Methods provides the diagnostic procedure). AD and LB pathologies increased with age, but this was less evident for LB pathology (Fig. 1d–f).
Cross-sectional associations with clinical outcomes
Next, we studied the effects of the different key brain pathological changes on clinical deficits at baseline. When comparing group differences (Fig. 2a–c,g–i), patients who were AD−/LB+, AD+/LB− or AD+/LB+ had worse attention/executive and visuospatial function than patients who were AD−/LB−. Patients who were AD+/LB− and AD+/LB+ had worse memory and global cognition compared to patients who were either AD−/LB− or AD−/LB+. Patients who were AD−/LB+ had worse motor function and exhibited a higher prevalence of hallucinations compared to all the other groups.
Multivariable linear regression analyses using the measures of LB, Aβ and tau pathologies as predictors in the same model and the clinical symptoms as outcomes could overall confirm the cognitive and clinical profiles from the group analyses (Fig. 2d–f,j–l). When used simultaneously as predictors, LB pathology, but not Aβ nor tau pathologies, had independent effects on worse attention/executive, visuospatial and motor function and was associated with higher prevalence of hallucinations. Aβ and tau, on the other hand, had independent effects on worse memory and global cognition. Model specifications of the effects of LB with/without adjusting for Aβ and tau pathology are shown in Extended Data Table 2. Finally, we found no association between presence of LB and Aβ status (P = 0.14, adjusted for age) or LB and tau status (P = 0.065, adjusted for age).
Longitudinal associations with cognitive outcomes
Next, we studied the effects of the different brain pathologies on longitudinal changes in cognitive function. First, we examined the effects of the AD/LB group classification on longitudinal cognitive function using linear mixed-effects models. We found that patients who were AD−/LB+, AD+/LB− or AD+/LB+ progressed faster in all cognitive outcomes than those who were AD−/LB− (Fig. 3a–d). Deterioration in global cognitive function and attention/executive function was seen in both AD+ and LB+ groups, but those with AD pathology declined even faster (Fig. 3a,b). To make sure that differences in trajectories were not driven by baseline group differences, we performed a sensitivity analysis using change in cognition from baseline as outcome and adjusted the model for baseline cognitive score, which confirmed the significant differences (Extended Data Table 3). Second, when studying the independent effects of LB, Aβ and tau pathologies, we found that only LB pathology was independently associated with a faster decline in visuospatial function (Fig. 3h). Further, both LB and tau pathologies were independently associated with a faster decline in memory, attention/executive and global cognitive function (Fig. 3e–g). Model details with/without adjusting for Aβ and tau are shown in Extended Data Table 4. To examine whether LB pathology provided prognostic information in addition to identifying the clinical features of DLB, PD or PD with dementia (PDD), we adjusted these models for a clinical baseline diagnosis of DLB/PD/PDD. We found that LB pathology was still an independently significant predictor of cognitive decline in all cognitive domains (Extended Data Table 5).
Discussion
Clinicopathological postmortem association studies suggest that both AD and LB pathologies play a substantial role in determining the clinical phenotype in patients where the two pathologies coexist18,19,20; however, neuropathological evaluation only provides a terminal end-stage window of the co-occurring pathologies, which is difficult to correlate with the earlier signs and the clinical trajectories of patients assessed longitudinally for many years. Before the introduction of α-syn SAAs, the lack of a reliable biomarker for LB pathology hampered the design of clinicopathological association studies in vivo. Here we provide a combined in vivo evaluation of biomarkers highly specific for AD and LB pathology and their correlation with the clinical phenotype in a large heterogeneous cohort of patients with cognitive impairment. The results show that LB pathology had effects on the clinical profile independent of Aβ and tau pathologies with cross-sectional impairment in attention/executive, visuospatial and motor functions. LB pathology also had independent associations with a faster decline over time in global, attention/executive, memory and visuospatial functions. Overall, adding classification by LB status to the standard AD-centered Aβ/tau classification identifies patient subgroups with distinct cognitive profiles and clinical trajectories. The cognitive findings from this in vivo biomarker-based patient classification are in line with those obtained in neuropathologically verified cohorts with cognitive data showing an association between LB pathology and antemortem deficits in attention, executive and visuospatial functions also in participants with mixed AD and LB pathology21,22,23,24.
In the present study, we show that this biomarker-based classification cannot be replaced by clinical phenotyping as only 21% at baseline and 32% during follow-up of the patients who were LB+ fulfilled the clinical criteria for PD or DLB (Table 1). This can be compared to patients who are AD+, where 50% had a clinical baseline diagnosis of AD and 87% during follow-up (note that if a patient fulfilled the criteria for both AD and DLB this was coded as DLB). This was specifically highlighted when we adjusted the models for a clinical DLB/PD/PDD diagnosis at baseline and found that LB pathology was still a significant predictor of cognitive decline (Extended Data Table 5). In particular, the presence of both pathologies (AD+/LB+) seems more difficult to identify clinically as only 9% in this group fulfilled the criteria for DLB/PD at baseline (16% during follow-up) versus 31% (46% during follow-up) in the AD−/LB+ group (P < 0.001; Table 1). This may be related to a significantly lower frequency of motor symptoms and hallucinations in the AD+/LB+ group compared to the AD−/LB+ group (i.e., fewer core clinical features of PD15 or DLB;17 Fig. 2h,i). The demonstration of concurrent AD and LB pathologies has previously mainly been possible postmortem by neuropathologic studies, which is of little help to the patients, yet these patients are particularly important to identify in the clinic because of the fast clinical progression (Fig. 3a–d). Moreover, the exclusion or the separate evaluation of patients with these profiles in trials assessing the effect of new therapies for AD will be essential for determining the impact of disease-modifying AD treatments without the confounding effect of a concomitant LB pathology driving disease progression independently and despite removal of AD pathology.
Both for trial screenings and clinical practice, it would be advantageous to have several options for analyzing LB pathology, depending on the setting and available instruments. We used CSF for the α-syn SAA, which requires a lumbar puncture, but several studies successfully used skin biopsies instead25,26,27. An even less-invasive approach would be to measure α-syn seeding activity in blood, which is currently under development with promising preliminary results28.
In this study, 21% of patients who were AD+ showed evidence of LB pathology, which is lower than the percentage of concomitant LB pathology detected by neuropathological postmortem studies (33–42%) (refs. 3,29). One explanation could be the effect of sample selection. In the BioFINDER cohorts, patients are consecutively recruited based on referrals to secondary memory clinics, whereas those who undergo neuropathological examination are often more selected28. Another possibility is that this is related to the sensitivity of α-syn SAAs compared to neuropathological verification of LB pathology. α-Syn SAAs have a very high sensitivity for the transitional limbic and diffuse neocortical stages of LB pathology, but lower for focal types of LB pathology limited to the amygdala or possibly the brainstem8,9,11,14. Notably, the amygdala-only variant contributes a substantial proportion of AD cases with α-syn pathology in postmortem studies and would thus go largely unnoticed using α-syn SAAs30; however, the amygdala-predominant variant does not lead to a clinical LBD presentation and is less clinically relevant31.
Regarding the prevalence of LB and AD pathologies in relation to increasing age, this was more prominent for Aβ and tau, than LB. Further, after the age of 80 years, the prevalence of Aβ and tau did not seem to further increase in our memory clinic population (Fig. 1d). The results of a large neuropathological study support our finding of a lack of, or only subtle, association between age and LB pathology in cognitively impaired individuals32. The seemingly paradoxical finding that LB pathology becomes more prevalent with age on a population basis but less so in cognitively impaired/memory clinic samples32, might be explained by the increasing prevalence of other pathologies (for example limbic-predominant age-related TDP-43 encephalopathy (LATE) and vascular lesions) contributing to cognitive decline, resulting in a lack of clear increase in the proportion of LB pathology among memory clinic patients33.
A limitation of the present study concerns the lack of longitudinal analyses of non-cognitive symptoms, including structured assessments of fluctuations in alertness/attention and signs of REM sleep behavioral disorders, often seen in individuals with LB pathology17. Future studies should examine the longitudinal changes of all LB-related symptoms (not just cognition) in more detail to better define the clinical trajectory of patients with coexisting AD and LB pathology. It would be of particular interest to see whether or when the AD+/LB+ group would develop motor dysfunction similarly to the AD−/LB+ group. As for the measure of motor dysfunction in the statistical analysis, we used an informant-based questionnaire, but data from a formal objective assessment (for example UPDRS-III) were lacking in this study; however, we still identified a significant association between motor function and LB pathology (Fig. 2i,l) indicating the adequate validity of the questionnaire. Moreover, due to the study designs, AD biomarkers for tau pathology differed between patients in BioFINDER-2 and BioFINDER-1; however, the CSF assay (Lilly-developed CSF P-tau217) used for tau in BioFINDER-1 has shown a very high agreement with tau-PET status (used in BioFINDER-2) (ref. 34).
This study has highlighted the potential improvement of including an LB biomarker in the clinical assessment of a patient with cognitive impairment, with substantial diagnostic and prognostic implications. Still, it is important to remember that other pathologies currently lack corresponding in vivo biomarkers, such as LATE and four repeat (4R) tauopathies (such as progressive supranuclear palsy and corticobasal degeneration)35,36. Although non-AD and non-LB pathologies may be less common, occur more often in older people or have less prominent clinical impact22,29,37,38, it is crucial with continued efforts to develop corresponding biomarkers to implement a more complete, pathology-based precision-medicine approach.
In summary, in this large heterogeneous sample of patients with cognitive impairment referred to secondary memory clinics, our results indicate that classifying patients based on the presence of LB, Aβ and tau pathologies identifies subgroups with distinct clinical phenotypes and trajectories that are not captured by using clinical syndromes or classification according to the standard Aβ and tau biomarkers. Analyzing LB pathology in vivo could provide a better precision-medicine approach for the clinical management of patients with cognitive impairment and for designing drug trials of participants with AD and LBD.
Methods
Participants and clinical diagnostics
All participants were part of the BioFINDER-1 (NCT01208675; n = 398) or BioFINDER-2 (NCT03174938; n = 485) studies, described previously34,40,41. The inclusion criteria were (1) referred to participating secondary memory clinics due to cognitive symptoms recognized by the patient, caregiver and/or the referring physician; (2) age 40–100 years; and (3) speaks and understands Swedish to the extent that an interpreter is not necessary for the patient to fully understand the study information and cognitive tests. The exclusion criteria were (1) significant unstable systemic illness or organ failure, such as terminal cancer, which makes it difficult to participate in the study; and (2) current significant alcohol or substance misuse. Only participants (1) with MCI or dementia at baseline; (2) with complete biomarker data for Aβ, tau and α-syn (LB pathology); and (3) referred to the participating memory clinics of Skåne University Hospital or the hospital of Ängelholm in Sweden due to cognitive symptoms recognized by the patient, caregiver and/or the referring physician, were included in the present study. All patients were enrolled and underwent baseline examination from 2007 to 2015 (BioFINDER-1) or from 2017 to 2021 (BioFINDER-2). MCI was classified as not fulfilling the criteria for dementia (major neurocognitive disorder according to DSM-5 (ref. 42)) and performing worse than −1.5 × s.d. in at least one of the cognitive domains of memory, attention/executive, verbal or visuospatial function. In BioFINDER-1, this was assessed by a senior neuropsychologist after a thorough neuropsychological battery, as described in detail previously43. In BioFINDER-2, the MCI classification was operationalized as performing worse than −1.5 z scores in any cognitive domain according to regression-based norms accounting for age and education and the test performance in Aβ-negative controls44 (see elsewhere45,46 for a description on the regression-based z scores). Cognitive domain z scores were derived by calculating the mean z score of the tests in each of the following domains: attention/executive function (trail-making test A, trail-making test B and symbol digit modalities test), verbal ability (verbal fluency animals and the 15-word short version of the Boston naming test), memory (ten-word delayed recall from the Alzheimer’s disease assessment scale (ADAS)) and visuospatial function (incomplete letters and cube analysis from the visual object and space perception battery). Dementia was classified according the DSM-5 criteria for major neurocognitive disorders42.
A clinical diagnosis of AD was based on the DSM-5 criteria for mild or major neurocognitive disorder due to AD42. In addition, signs of Aβ positivity were required in agreement with the National Institute of Aging-Alzheimer’s Association13 and International Working Group4 criteria for AD. The biomarker for Aβ positivity was not the same as the Elecsys CSF Aβ42/Aβ40 assay used in the present study (described in detail previously41), which explains why some with a clinical AD diagnosis (Table 1 and Extended Data Table 1) are AD− in the AD/LB biomarker classification. Note that this clinical diagnosis was only used for describing the sample (Table 1 and Extended Data Table 1). The purely biomarker-driven classification for AD pathology (Aβ and tau positivity, regardless of clinical syndrome) was used in the statistical analysis. A clinical diagnosis of DLB was based on the McKeith criteria for probable DLB (MCI16 or dementia17 stage) and PD was based on previously published criteria for PD and PDD47 (where the DSM-5 criteria were used to identify presence of dementia/major neurocognitive disorder42). The PD diagnoses are detailed in Supplementary Table 3, where the criteria used in the present study (Gelb et al.47) are compared to the diagnostic classification according to the Movement Disorder Society (MDS) criteria15. If a participant fulfilled the criteria for both AD and DLB/PD he/she was coded as DLB or PD in the analyses. The other diagnostic entities were diagnosed according to published criteria42,48,49,50,51, as previously described34. Notably, to increase the clinical diagnostic accuracy, the diagnoses were also determined during a longitudinal follow-up of symptoms and advanced investigations at a secondary memory clinic (Extended Data Table 1). Note that α-syn SAA results were not available when the diagnoses were determined.
All participants or their legal representatives provided written informed consent. Ethical approval was given by the Regional Ethical Committee in Lund, Sweden.
Clinical outcomes
All clinical outcomes, except the presence of hallucinations and correctly completed visuospatial task, were z scored according to distribution in Aβ− cognitively unimpaired participants in BioFINDER-1 and BioFINDER-2. The modified Preclinical Alzheimer Cognitive Composite-5 (mPACC5; also referred to as PACC) was used as a measure of global cognition, containing tests of memory, executive, attention and verbal function52. It was calculated based on the previously described PACC5, using the MMSE, symbol digit modality test (SDMT) and animal fluency52. As the memory tests logical memory and the free and cued selective reminding tests were not available in BioFINDER, the ten-word delayed recall task from ADAS-cognition (ADAS-cog)53 was used (weighted twice), as previously applied in several studies54,55. The mPACC5 was thus calculated using z scores based on the distribution in Aβ− cognitively unimpaired in the following way: (MMSE + (ADAS-cog delayed recall × 2) + SDMT + animal fluency) / 5. Memory was measured using the ten-word delayed recall task from ADAS-cog53. Attention/executive function was measured using the SDMT56. If SDMT was not available, the serial 7s task of the MMSE was used (Supplementary Tables 1 and 2 detail missingness)57. Visuospatial function was measured using the incomplete letters task from the visual object and space perception battery and if incomplete letters was not available (per study design only available in BioFINDER-2), the pentagon copying task from the MMSE was used. As pentagon copying is scored as either normal (1) or abnormal (0), the incomplete letters task was binarized at ≤18 of 20 points (mean − 2 × s.d. in Aβ-negative cognitively unimpaired participants in BioFINDER-2).
Presence of hallucinations (yes / no) was assessed using the informant-based cognitive impairment questionnaire (CIMP-QUEST)58, item eight in the associated symptom’s part (‘Does the patient has hallucinations, seeing, hearing or feeling things that don’t actually exist but that he/she has a clear experience of?’). Motor function was measured using the combined score from all motor symptoms in CIMP-QUEST, covering aspects of bradykinesia, reaction, changed the way of walking, poorer balance, clumsier hands, changed facial expressions and dysarthria.
Biomarker of Aβ
The CSF Aβ42/Aβ40 ratio was used to define Aβ positivity, as Aβ-PET was not included at baseline in BioFINDER-1 and was not available in BioFINDER-2 participants with dementia, per study design. Aβ42 and Aβ40 were analyzed on a cobas e 601 analyzer using the Roche NeuroToolKit. The threshold for positivity was defined using mixture modeling statistics59. In BioFINDER-1, the previously established cutoff of CSF Aβ42/Aβ40 < 0.066 was used60. For BioFINDER-2, the cutoff was established in all BioFINDER-2 participants (cognitively unimpaired and impaired) with available CSF Aβ42 and Aβ40 data (n = 1,076), resulting in a cutoff of <0.080 (the difference in cutoffs between cohorts is explained by preanalytical differences in that LoBind tubes were used in BioFINDER-2 but not in BioFINDER-1 (refs. 61,62) for preanalytical protocols and differences).
Biomarker of tau
Tau positivity was defined as either abnormal CSF P-tau217 (BioFINDER-1) or abnormal tau-PET (BioFINDER-2). CSF P-tau217 was measured using the Meso Scale Discovery platform using an assay developed by Eli Lilly and tau-PET was performed using RO948 labeled with radioactive fluorine [18F], as previously described34. SUVR was measured in a temporal meta-ROI using the inferior cerebellar cortex as reference region34. Cutoffs were established at the mean + 2 × s.d. in Aβ− controls as previously described and the cutoff for CSF P-tau217 was >11.42 pg ml−1 and for tau-PET > 1.32 SUVR (ref. 34).
Preparation of recombinant α-synuclein (LB pathology)
The purification of recombinant wild-type α-syn was performed as previously reported8, with minor modifications. Briefly, transformed Escherichia coli BL21 (DE3) bacteria (New England Biolabs) from a glycerol stock were streaked on a selective plate (Kan+, 50 µg ml−1, kanamycin from Sigma) and incubated at 37 °C overnight. A single colony was selected and inoculated into 5 ml Luria Broth (Sigma) with kanamycin and allowed to grow for 4–5 h at 37 °C with continuous agitation at 250 r.p.m. This starter culture was then added to 1 l Luria Broth containing kanamycin and the overnight express auto-induction system (Merk-Millipore 71300-4) in a fully baffled flask. Cells were grown in a shaking incubator at 37 °C, 200 r.p.m. overnight. The next day, the culture was split into four 250-ml flasks and centrifuged at 3,200g for 10 min at 4 °C. The pellet was gently resuspended in 25 ml osmotic shock buffer containing 40% sucrose (Sigma), 2 mM EDTA (Sigma) and 30 mM Tris (Bio-Rad) at pH 7.2 using a serological pipette and incubated for 10 min at room temperature under mild agitation on a rotator mixer. The solution was then centrifuged at 9,000g, 20 min at 20 °C and each pellet was resuspended in 10 ml ice-cold Milli-Q water. The four suspensions were pooled into two 50-ml tubes and 20 µl of saturated MgCl2 (Sigma). After 3 min incubation under mild rocking on ice, the suspension was centrifuged at 9,000g for 30 min at 4 °C and the supernatant was collected into a 100-ml glass beaker. The pH was reduced to pH 3.5 by adding 400–600 µl HCl 1 M (PanReac AppliChem) and incubated under stirring for 10 min at room temperature. After a second centrifugation at 9,000g for 30 min at 4 °C, the supernatant was collected into a clean 100-ml glass beaker. The pH was adjusted to 7.5 by adding 400–600 µl NaOH 1 M (Sigma). The protein extract was filtered through a 0.22-µm filter (Merk-Millipore), loaded into a Ni–NTA column (Cytiva 17525501) on an NGC chromatography system (Bio-Rad) and washed with 20 mM Tris, pH 7.5 at room temperature. The column was further washed with 50 mM imidazole (Sigma) in Tris 20 mM, pH 7.5, generating a peak that was not collected. A linear gradient up to 500 mM imidazole in 20 mM Tris, pH 7.5 was performed and the peak was collected between 30% and 75% of imidazole buffer (150 and 375 mM, respectively). This peak was loaded onto an anion exchange column Q-HP (Cytiva 17115401) and washed in Tris 20 mM, pH 7.5, followed by another washing in 100 mM NaCl in Tris 20 mM, pH 7.5. Again, a linear gradient up to 500 mM of NaCl in Tris 20 mM pH 7.5 was carried out to collect the peak between 300 and 350 mM NaCl. The fractions were pooled and filtered through a 0.22-µm filter and dialyzed against Milli-Q water overnight at 4 °C using a 3.5 kDa MWCO dialysis membrane (Thermo-Scientific). The next day, the protein was moved into fresh Milli-Q water and dialyzed for 4 h more. The protein concentration was measured by a spectrophotometer using a theoretical extinction coefficient at 280 nm of 0.36 (mg ml−1) − 1 cm−1. Finally, the protein was lyophilized for 6 h and stored in aliquots at a final concentration of 1 mg ml−1 after resuspension into 500 µl phosphate buffer (PB; Sigma) 40 mM, pH 8.0. Lyophilized aliquots were stored at − 80 °C until usage.
α-Syn RT-QuIC analyses
α-Syn RT-QuIC analyses were performed blinded to clinical status and diagnosis of the participant and according to an established protocol8,63,64, with minor modifications. Briefly, six 0.8-mm silica beads (OPS Diagnostics) per well were pre-loaded into black 96-well plates with a clear bottom (Nalgene Nunc International). CSF samples were thawed and vortexed for 10 s before use. Then, 15 μl CSF was added to a 85 μl reaction mix composed of 40 mM PB, pH 8.0, 170 mM NaCl, 10 mM thioflavin-T (Sigma), 0.0015% SDS (Bio-Rad) and 0.1 g l−1 of filtered recombinant α-syn (100-kDa Amicon centrifugal filters, Merck Millipore). Plates were closed with a plate sealer film (Nalgene Nunc International) and incubated into a FLUOstar Omega plate reader (BMG Labtech) at 42 °C with intermittent double orbital shaking at 400 r.p.m. for 1 min, followed by 1 min rest. Fluorescence was measured every 45 min with 450 nm excitation and 480 nm emission filters during the 30 h test run. Samples and controls were run in quadruplicate and considered positive after the first run when at least three out of four replicates reached a threshold arbitrarily set at 30% of the median of Imax values reached by the positive control replicates. To keep the risk of false-positive results at a minimum, we repeated three times the analysis of samples showing seeding activity in only one or two out of four replicates in the first run. We considered a positive result only when at least 4 of the 12 total replicates reached the threshold. We used 30 different batches of α-syn recombinant protein throughout the study. Each batch underwent a quality control test before use. We ran at least one positive and negative control on each plate. The positive controls were chosen from patients with probable or definite DLB or PD whose CSF samples gave four out of four positive replicates during screening. In each validated experiment (plate) included in the final analysis, the positive controls showed at least three out of four positive replicates.
Statistical analyses
In cross-sectional analyses, the AD/LB group, age, sex (assigned, not self-reported), cognitive stage (MCI or dementia) and, for cognitive test outcomes, years of education, were used as independent variables in general linear regression models. Dependent variables were either cognitive function, motor function or presence of hallucinations. Next, binarized Aβ, tau and LB pathology (to facilitate easier comparison of estimates), were used instead of the AD/LB group. Logistic regression models were used for the binary outcomes (visuospatial function and presence of hallucinations). In longitudinal analyses, LME models were used (R packages lme4 and the function lmer for continuous outcomes and glmer for binarized outcomes were used and P values were calculated using the package lmerTest). Cognitive function was used as an outcome and significant results were presented for the AD/LB group × time and pathology × time interactions. The models also included age, sex, cognitive stage (MCI or dementia), years of education and random slopes and intercepts. For models including pathology × time, the interaction between time and all covariates were also included. In a sensitivity analysis, the LME models using AD/LB group × time were also adjusted for baseline cognitive test result (if there was a difference between AD/LB groups at baseline) with change from baseline in cognitive test result as outcome. All available data were used in the statistical analyses. Missing data and number of participants at each visit are described in Supplementary Tables 1 and 2. A two-sided P value <0.05 was considered to indicate statistical significance. Multiple comparison corrections were performed using the false discovery rate method at α = 0.05, applying correction per outcome (six comparisons for AD/LB group comparisons and three for the independent effects of LB, Aβ and tau pathology). The statistical analyses were performed using R v.4.1.
Reporting summary
Further information on research design is available in the Nature Portfolio Reporting Summary linked to this article.
Data availability
Anonymized data will be shared by request from a qualified academic investigator for the sole purpose of replicating procedures and results presented in the article and as long as a data transfer is in agreement with EU legislation on the General Data Protection Regulation and decisions by the Ethical Review Board of Sweden and Region Skåne, which should be regulated in a material transfer agreement.
Code availability
No custom code or mathematical algorithm that was central to the conclusions was used in this study.
References
Hansson, O. Biomarkers for neurodegenerative diseases. Nat. Med. 27, 954–963 (2021).
Taylor, J. P. et al. New evidence on the management of Lewy body dementia. Lancet Neurol. 19, 157–169 (2020).
DeTure, M. A. & Dickson, D. W. The neuropathological diagnosis of Alzheimer’s disease. Mol. Neurodegener. 14, 32 (2019).
Dubois, B. et al. Clinical diagnosis of Alzheimer’s disease: recommendations of the International Working Group. Lancet Neurol. 20, 484–496 (2021).
Bellomo, G. et al. α-Synuclein seed amplification assays for diagnosing synucleinopathies: the way forward. Neurology 99, 195–205 (2022).
Bargar, C. et al. Streamlined α-synuclein RT-QuIC assay for various biospecimens in Parkinson’s disease and dementia with Lewy bodies. Acta Neuropathol. Commun. 9, 62 (2021).
Hall, S. et al. Performance of α-Synuclein RT-QuIC in relation to neuropathological staging of Lewy body disease. Acta Neuropathol. Commun. 10, 90 (2022).
Rossi, M. et al. Ultrasensitive RT-QuIC assay with high sensitivity and specificity for Lewy body-associated synucleinopathies. Acta Neuropathol. 140, 49–62 (2020).
Arnold, M. R. et al. α-Synuclein seed amplification in CSF and brain from patients with different brain distributions of pathological α-synuclein in the context of co-pathology and non-LBD diagnoses. Ann. Neurol. 92, 650–662 (2022).
Siderowf, A. et al. Assessment of heterogeneity among participants in the Parkinson’s Progression Markers Initiative cohort using α-synuclein seed amplification: a cross-sectional study. Lancet Neurol. 22, 407–417 (2023).
Kang, U. J. et al. Comparative study of cerebrospinal fluid α-synuclein seeding aggregation assays for diagnosis of Parkinson’s disease. Mov. Disord. 34, 536–544 (2019).
Poggiolini, I. et al. RT-QuIC using C-terminally truncated α-synuclein forms detects differences in seeding propensity of different brain regions from synucleinopathies. Biomolecules https://doi.org/10.3390/biom11060820 (2021).
Jack, C. R. Jr. et al. NIA-AA research framework: toward a biological definition of Alzheimer’s disease. Alzheimers Dement. 14, 535–562 (2018).
Attems, J. et al. Neuropathological consensus criteria for the evaluation of Lewy pathology in post-mortem brains: a multi-centre study. Acta Neuropathol. 141, 159–172 (2021).
Postuma, R. B. et al. MDS clinical diagnostic criteria for Parkinson’s disease. Mov. Disord. 30, 1591–1601 (2015).
McKeith, I. G. et al. Research criteria for the diagnosis of prodromal dementia with Lewy bodies. Neurology 94, 743–755 (2020).
McKeith, I. G. et al. Diagnosis and management of dementia with Lewy bodies: third report of the DLB Consortium. Neurology 65, 1863–1872 (2005).
Ferman, T. J. et al. The limbic and neocortical contribution of α-synuclein, tau, and amyloid β to disease duration in dementia with Lewy bodies. Alzheimers Dement. 14, 330–339 (2018).
Thomas, A. J. et al. Improving the identification of dementia with Lewy bodies in the context of an Alzheimer’s-type dementia. Alzheimers Res Ther. 10, 27 (2018).
Coughlin, D. et al. Cognitive and pathological influences of tau pathology in Lewy body disorders. Ann. Neurol. 85, 259–271 (2019).
Ryman, S. G. et al. Cognition at each stage of Lewy body disease with co-occurring Alzheimer’s disease pathology. J. Alzheimers Dis. 80, 1243–1256 (2021).
Brenowitz, W. D. et al. Mixed neuropathologies and associations with domain-specific cognitive decline. Neurology 89, 1773–1781 (2017).
Malek-Ahmadi, M. et al. Faster cognitive decline in dementia due to Alzheimer disease with clinically undiagnosed Lewy body disease. PLoS ONE 14, e0217566 (2019).
Gu, Y. et al. Clinical trajectories at the end of life in autopsy-confirmed dementia patients with Alzheimer disease and Lewy bodies pathologies. Neurology 98, e2140–e2149 (2022).
Mammana, A. et al. RT-QuIC detection of pathological α-synuclein in skin punches of patients with Lewy body disease. Mov. Disord. 36, 2173–2177 (2021).
Wang, Z. et al. Skin α-synuclein aggregation seeding activity as a novel biomarker for Parkinson disease. JAMA Neurol. 78, 1–11 (2020).
Iranzo, A. et al. Misfolded α-synuclein assessment in skin and CSF by RT-QuIC in isolated REM sleep behavior disorder. Neurology https://doi.org/10.1212/WNL.0000000000207147 (2023).
Kluge, A. et al. Detection of neuron-derived pathological α-synuclein in blood. Brain 145, 3058–3071 (2022).
Spina, S. et al. Comorbid neuropathological diagnoses in early versus late-onset Alzheimer’s disease. Brain 144, 2186–2198 (2021).
Twohig, D. & Nielsen, H. M. α-Synuclein in the pathophysiology of Alzheimer’s disease. Mol. Neurodegener. 14, 23 (2019).
Toledo, J. B. et al. Dementia with Lewy bodies: impact of co-pathologies and implications for clinical trial design. Alzheimers Dement. 19, 318–332 (2023).
Parkkinen, L., Soininen, H., Laakso, M. & Alafuzoff, I. α-Synuclein pathology is highly dependent on the case selection. Neuropathol. Appl. Neurobiol. 27, 314–325 (2001).
Jellinger, K. A. & Attems, J. Prevalence and pathology of dementia with Lewy bodies in the oldest old: a comparison with other dementing disorders. Dement Geriatr. Cogn. Disord. 31, 309–316 (2011).
Palmqvist, S. et al. Discriminative accuracy of plasma phospho-tau217 for Alzheimer disease vs other neurodegenerative disorders. JAMA 324, 772–781 (2020).
Nelson, P. T. et al. Limbic-predominant age-related TDP-43 encephalopathy (LATE): consensus working group report. Brain 142, 1503–1527 (2019).
Rosler, T. W. et al. Four-repeat tauopathies. Prog. Neurobiol. 180, 101644 (2019).
Kapasi, A. et al. Limbic-predominant age-related TDP-43 encephalopathy, ADNC pathology, and cognitive decline in aging. Neurology 95, e1951–e1962 (2020).
Walker, J. M. et al. Cognitive and neuropsychological profiles in Alzheimer’s disease and primary age-related tauopathy and the influence of comorbid neuropathologies. J. Alzheimers Dis. https://doi.org/10.3233/JAD-230022 (2023).
Postuma, R. B. et al. A single-question screen for rapid eye movement sleep behavior disorder: a multicenter validation study. Mov. Disord. 27, 913–916 (2012).
Palmqvist, S. et al. Performance of fully automated plasma assays as screening tests for Alzheimer disease-related β-amyloid status. JAMA Neurol. 76, 1060–1069 (2019).
Palmqvist, S. et al. Prediction of future Alzheimer’s disease dementia using plasma phospho-tau combined with other accessible measures. Nat. Med. 27, 1034–1042 (2021).
American Psychiatric Association. Diagnostic and Statistical Manual of Mental Disorders, Fifth Edition (DSM-5) 607–608 (American Psychiatric Publishing, 2013).
Petrazzuoli, F. et al. Brief cognitive tests used in primary care cannot accurately differentiate mild cognitive impairment from subjective cognitive decline. J. Alzheimers Dis. 75, 1191–1201 (2020).
Borland, E., Stomrud, E., van Westen, D., Hansson, O. & Palmqvist, S. The age-related effect on cognitive performance in cognitively healthy elderly is mainly caused by underlying AD pathology or cerebrovascular lesions: implications for cutoffs regarding cognitive impairment. Alzheimers Res. Ther. 12, 30 (2020).
Borland, E. et al. The Montreal cognitive assessment: normative data from a large Swedish population-based cohort. J. Alzheimers Dis. 59, 893–901 (2017).
Shirk, S. D. et al. A web-based normative calculator for the uniform data set (UDS) neuropsychological test battery. Alzheimers Res. Ther. 3, 32 (2011).
Gelb, D. J., Oliver, E. & Gilman, S. Diagnostic criteria for Parkinson disease. Arch. Neurol. 56, 33–39 (1999).
Hoglinger, G. U. et al. Clinical diagnosis of progressive supranuclear palsy: The Movement Disorder Society criteria. Mov. Disord. 32, 853–864 (2017).
Gilman, S. et al. Second consensus statement on the diagnosis of multiple system atrophy. Neurology 71, 670–676 (2008).
Armstrong, M. J. et al. Criteria for the diagnosis of corticobasal degeneration. Neurology 80, 496–503 (2013).
Gorno-Tempini, M. L. et al. Classification of primary progressive aphasia and its variants. Neurology 76, 1006–1014 (2011).
Papp, K. V., Rentz, D. M., Orlovsky, I., Sperling, R. A. & Mormino, E. C. Optimizing the preclinical Alzheimer’s cognitive composite with semantic processing: the PACC5. Alzheimers Dement. 3, 668–677 (2017).
Rosen, W. G., Mohs, R. C. & Davis, K. L. A new rating scale for Alzheimer’s disease. Am. J. Psychiatry 141, 1356–1364 (1984).
Insel, P. S. et al. Determining clinically meaningful decline in preclinical Alzheimer disease. Neurology 93, e322–e333 (2019).
Pichet Binette, A. et al. Combining plasma phospho-tau and accessible measures to evaluate progression to Alzheimer’s dementia in mild cognitive impairment patients. Alzheimers Res. Ther. 14, 46 (2022).
Smith, A. Symbol Digit Modalities Test (Western Psychological Services, 1991).
Folstein, M. F., Folstein, S. E. & McHugh, P. R. ‘Mini-mental state’. A practical method for grading the cognitive state of patients for the clinician. J. Psychiatr. Res. 12, 189–198 (1975).
Astrand, R., Rolstad, S. & Wallin, A. Cognitive Impairment Questionnaire (CIMP-QUEST): reported topographic symptoms in MCI and dementia. Acta Neurol. Scand. 121, 384–391 (2010).
Benaglia, T., Chauveau, D., Hunter, D. R. & Young, D. S. mixtools: an R package for analyzing finite mixture models. J. Stat. Softw. 32, 1–29 (2009).
Palmqvist, S. et al. An accurate fully automated panel of plasma biomarkers for Alzheimer’s disease. Alzheimers Dement. https://doi.org/10.1002/alz.12751 (2022).
Blennow, K. et al. Second-generation Elecsys cerebrospinal fluid immunoassays aid diagnosis of early Alzheimer’s disease. Clin. Chem. Lab. Med. 61, 234–244 (2023).
Palmqvist, S. et al. Accuracy of brain amyloid detection in clinical practice using cerebrospinal fluid β-amyloid 42: a cross-validation study against amyloid positron emission tomography. JAMA Neurol. 71, 1282–1289 (2014).
Groveman, B. R. et al. Rapid and ultra-sensitive quantitation of disease-associated α-synuclein seeds in brain and cerebrospinal fluid by αSyn RT-QuIC. Acta Neuropathol. Commun. 6, 7 (2018).
Rossi, M. et al. Diagnostic value of the CSF α-synuclein real-time quaking-induced conversion assay at the prodromal MCI stage of dementia with Lewy bodies. Neurology 97, e930–e940 (2021).
Acknowledgements
The study was supported by the Alzheimer’s Association (no. SG-23-1061717), Swedish Research Council (nos. 2022-00775 and 2018-02052), ERA PerMed (no. ERAPERMED2021-184), the Knut and Alice Wallenberg Foundation (no. 2017-0383), the Strategic Research Area MultiPark (Multidisciplinary Research in Parkinson’s disease) at Lund University, the Swedish Alzheimer Foundation (nos. AF-980907 and AF-968598), the Swedish Brain Foundation (nos. FO2021-0293 and FO2022-0204), The Parkinson foundation of Sweden (no. 1280/20), the Cure Alzheimer’s Fund, the Konung Gustaf V:s och Drottning Victorias Frimurarestiftelse, the Skåne University Hospital Foundation (no. 2020-O000028), Regionalt Forskningsstöd (nos. 2022-1259 and 2022-1346), the Swedish Federal Government under the ALF agreement (nos. 2022-Projekt0080 and 2018-Projekt0279), the Regione Emilia Romagna (nos. FIN-RER 2020, C.U.P. E45J19000810002), the Carisbo Foundation (no. 2022.0093) and the Italian Ministry of Health (Ricerca Corrente, no. 2021-22). Eli Lilly provided the antibodies and calibrators for the CSF P-tau217 assay. The precursor of 18F-RO948 was provided by Roche. Figure 1 was created with support from L. L. Raket.
Funding
Open access funding provided by Lund University.
Author information
Authors and Affiliations
Contributions
O.H. and P.P. conceived the project. C.Q. and S.P. contributed equally as first authors. O.H. and P.P. supervised the project and contributed equally as senior authors. C.Q., M.R. and S.D. produced the recombinant α-syn for the RT-QuIC assay and performed the substrate quality control. C.Q., M.R., A.M. and S.D. executed the RT-QuIC experiments. M.R. and S.B. quality-checked the data of the RT-QuIC assay. O.H. was principial investigator of the BioFINDER study and E.S. responsible for the logistics of the study. S.P., S.H., E.S. and O.H. were responsible for the clinical assessments of the patients. S.J. performed AD biomarker measurements. S.P. performed the statistical analyses. N.M.C. provided statistical support. S.P. wrote the initial draft of the paper with direct input from P.P. and O.H. All authors contributed substantially to the subsequent version of the manuscript and approved the final version for submission.
Corresponding authors
Ethics declarations
Competing interests
None of the authors has any financial interest in the α-syn SAA test. S.P. has acquired research support (for the institution) from ki elements/Alzheimer Drug Discoveries Foundation. In the past 2 years, he has received consultancy/speaker fees from Bioartic, Biogen, Lilly and Roche. O.H. has acquired research support (for the institution) from ADx, AVID Radiopharmaceuticals, Biogen, Eli Lilly, Eisai, Fujirebio, GE Healthcare, Pfizer and Roche. In the past 2 years, he has received consultancy/speaker fees from AC Immune, Amylyx, Alzpath, BioArctic, Biogen, Cerveau, Eisai, Eli Lilly, Fujirebio, Genentech, Merck, Novartis, Novo Nordisk, Roche, Sanofi and Siemens. M.R., S.H., C.Q., N.M.C., S.D., A.M., S.J., S.B., E.S. and P.P. declare no competing interests.
Peer review
Peer review information
Nature Medicine thanks Charbel Moussa, Thomas Montine, Johannes Levin and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. Primary Handling editor: Jerome Staal, in collaboration with the Nature Medicine team.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Extended data
Supplementary information
Supplementary Information
Supplementary Figs. 1 and 2 and Supplementary Tables 1–3.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Quadalti, C., Palmqvist, S., Hall, S. et al. Clinical effects of Lewy body pathology in cognitively impaired individuals. Nat Med 29, 1964–1970 (2023). https://doi.org/10.1038/s41591-023-02449-7
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1038/s41591-023-02449-7
- Springer Nature America, Inc.
This article is cited by
-
Plasma biomarkers of amyloid, tau, axonal, and neuroinflammation pathologies in dementia with Lewy bodies
Alzheimer's Research & Therapy (2024)
-
Disease progression modelling reveals heterogeneity in trajectories of Lewy-type α-synuclein pathology
Nature Communications (2024)
-
Lewy body pathology exacerbates brain hypometabolism and cognitive decline in Alzheimer’s disease
Nature Communications (2024)
-
Performance of a seed amplification assay for misfolded alpha-synuclein in cerebrospinal fluid and brain tissue in relation to Lewy body disease stage and pathology burden
Acta Neuropathologica (2024)
-
Updates in Fluid, Tissue, and Imaging Biomarkers for Dementia with Lewy Bodies and Implications for Biologically Based Disease Definitions
Current Treatment Options in Neurology (2024)