The Past and the Future of Alzheimer’s Disease Fluid Biomarkers

Early assay developments and clinical neurochemical studies

It is now around two decades since the most commonly used ELISA, the so-called INNOTEST assays, to measure CSF levels of total tau (T-tau), phosphorylated tau (P-tau), and the 42 amino acid isoform of amyloid-β (Aβ₄₂) were published [14–16]. These articles showed a marked increase in both CSF T-tau and P-tau in AD, together with a marked decrease in Aβ₄₂, a CSF biomarker change that today is known as the “Alzheimer profile”. The core AD CSF biomarkers also aid in the differentiation of AD from many differential diagnoses such as depression and Parkinson’s disease, with P-tau levels giving substantial aid also in the differentiation from other dementias, such as frontotemporal dementia and Lewy body dementia [15, 17]. These findings were subsequently validated in numerous papers, with a recent meta-analysis showing very consistent changes of these biomarkers in AD patients, with a mean fold change to elderly control groups of 2.54 for T-tau, 1.88 for P-tau, and 0.56 for Aβ₄₂ [18]. Studies on the core AD CSF biomarkers (T-tau, P-tau, and Aβ₄₂) are also, together with other top candidate CSF and blood AD biomarkers such as VLP-1 and sTREM2, continuously (last update April 2017) curated and presented both individually and in the meta-analysis format at the online Alzbiomarker database, see http://www.alzforum.org/alzbiomarker.

Amyloid PET set the pace in the clinical validation of CSF biomarkers

A problem with studies evaluating the diagnostic accuracy for the CSF biomarkers in clinically diagnosed AD patients as compared with cognitively normal elderly was that a percentage of normal elderly, as well as patients with other dementias, had biomarker concentrations similar to those found in AD patients. This was often interpreted as being due to suboptimal performance of the AD biomarkers.

Although high diagnostic accuracy of the core AD CSF biomarkers also was validated in studies with diagnosis confirmed by autopsy, with even better performance than studies based on pure clinical diagnoses [19, 20], these studies were largely based on cases with near end stage disease.

The availability of amyloid PET made it possible to identify amyloid pathology in vivo, and thereby also offered the possibility to compare the AD CSF biomarkers, especially Aβ₄₂, with amyloid load directly in patients and cognitively unimpaired elderly. Importantly, amyloid PET marked a major change in AD biomarker research, since it became clear that 20–30% of apparently healthy elderly showed positive on scans [21]. This knowledge rather quickly changed the view on how to interpret low CSF Aβ₄₂ levels in cognitively intact elderly, from poor assay quality or suboptimal biomarker performance, to an indicator of cerebral amyloidosis, and thus possibly of preclinical AD.

After the first paper showing that individuals (regardless of whether they had clinical AD symptoms or were cognitively unimpaired) with low CSF Aβ₄₂ had positive amyloid PET scans, and vice versa [22], a large number of papers have consistently found a very high concordance between CSF Aβ₄₂ and amyloid PET outcomes, with almost identical diagnostic accuracy to identify AD [23]. Importantly, high concordance between CSF Aβ₄₂ and amyloid PET has also been validated in a large prospective and longitudinal clinical study enrolling consecutive patients with early cognitive disturbances at a memory clinic [24]. Further, a large clinical study showed that regional PET measures did not outperform assessment of global cortical amyloid deposition as both measures were highly concordant with CSF Aβ₄₂ [25].

Results from some studies suggest that cases showing discordance between CSF Aβ₄₂ and amyloid PET most often have low CSF Aβ₄₂ but a negative amyloid PET scan [23]. This type of discordancy is much more common in cognitively normal elderly and early mild cognitive impairment (MCI) cases than in late MCI or in AD dementia cases [26], i.e., it is preferentially found in the earlier disease stages. A recent study also found that non-demented elderly who are CSF Aβ₄₂ positive but amyloid PET negative continue to build up brain amyloid deposits to the same degree as those who are positive for both CSF Aβ₄₂ and amyloid PET [25]. These results suggest that CSF Aβ₄₂ may be an earlier biomarker for cortical amyloid deposition than amyloid PET. If this can be verified in independent cohorts, it may govern the clinical decision whether to perform CSF analysis or amyloid PET in patients with mild memory complaints and suspected early AD pathology, e.g., the initiate treatment with anti-amyloid disease modifying drugs if such will be available. Additional factors of relevance for this may include availability, costs, and risks (radiation exposure versus post CSF tap headache), as well as both physician and patient preferences.

Interestingly, discordancy (low CSF Aβ₄₂ but negative amyloid PET) is preferentially found in cognitively unimpaired elderly and early AD, while it is rare in AD dementia cases [26]. One study examined a large cohort with non-demented ADNI subjects and found that those with low CSF Aβ₄₂, but negative amyloid PET, at baseline accumulated brain amyloid deposits at a rate similar to cases positive for both biomarkers, and at a rate three times higher than those with both biomarkers being normal [27]. These findings suggest that CSF Aβ₄₂ may be the earliest AD biomarker, becoming positive before amyloid PET and neurodegeneration.

Evaluating CSF biomarkers for early diagnosis

It may be logical to assume that novel anti-Aβ and anti-tau disease-modifying drug candidates likely will be more effective if treatment can be initiated early in the course of disease, before neurodegeneration is too severe [28], in the MCI stage of AD, or even pre-clinically. Given the diagnostic challenges to accurately diagnose AD in the MCI stage, there was a need to evaluate the CSF biomarkers for early diagnosis, and also for studies in which the core AD CSF biomarkers show a change earliest during the course of the disease.

In 1999, the first paper evaluating the AD CSF biomarkers in MCI patients showed that those who progressed to AD dementia (previously called “converted”) during clinical follow-up had the typical AD CSF profile, with biomarker levels being equally abnormal as in the dementia stage of the disease [29]. In this first study, no cognitively stable MCI group was included (to ascertain absence of progressive neurodegenerative disease, follow-up over several years is needed). In 2006, the first study with an extended clinical follow-up period (4–7 years) was published, showing a very high sensitivity (95%) for the core AD CSF biomarkers to identify prodromal AD, and also a high specificity to differentiate prodromal AD from stable MCI cases and those developing other dementias [30]. A high diagnostic accuracy of the CSF biomarkers for prodromal AD was soon thereafter verified in several large multi-center studies [20, 32].

The Aβ_42/40 ratio compensates for factors complicating Aβ₄₂ measurements

In addition to Aβ₄₂, CSF contains several other Aβ species, the most abundant one being Aβ₄₀ [33]. Even if CSF Aβ₄₀ shows no clear change in AD [18], the CSF Aβ_42/40 ratio has been suggested to have stronger diagnostic accuracy for AD compared to CSF Aβ₄₂ alone [34–36]. Recent studies also suggest that the Aβ_42/40 ratio has better concordance with amyloid PET than Aβ₄₂ [37–39], and that the CSF Aβ_42/40 ratio is also valuable in the clinical setting [40].

The explanation has been hypothesized to be due to the ratio normalizing the “total” Aβ production level between individuals, so that lowering of CSF Aβ₄₂ in high Aβ producers can more accurately be identified, and vice versa [41]. Alternative explanations may involve the ratio normalizing for differences in CSF dynamics (affecting both Aβ₄₂ and Aβ₄₀ similarly), such as variable CSF production or clearance rate, or in the proportion of CSF diffusing along the spinal cord to the lumbar sac as compared with proportion flowing over the cortex to the venous sinuses. Such differences between individuals may affect Aβ₄₂ levels, but may be compensated for by the Aβ_42/40 ratio. Last, the CSF Aβ_42/40 ratio may compensate for pre-analytical confounders that affects both Aβ₄₂ and Aβ₄₀ in the same way [42]. As an alternative to the Aβ_42/40 ratio, the ratios between T-tau/Aβ₄₂ and P-tau/Aβ₄₂ have also been evaluated in some studies. Indeed, all three ratios show very high concordance figures [receiver operating characteristic (ROC) area under curves (AUCs) around 0.95] with amyloid PET [24, 37], and another study also found very high concordance figures for all of CSF Aβ₄₂ (ROC AUC 0.94) and the T-tau/Aβ₄₂ and P-tau/Aβ₄₂ ratios (ROC AUCs of 0.98 and 0.97) [43]. Further studies are warranted to evaluate, for example, whether the Aβ_42/40 ratio, that is based only on amyloid markers, may signal earlier during the course of AD than the T-tau/Aβ₄₂ and P-tau/Aβ₄₂ ratios, which combine amyloid with neurodegeneration and tau pathology biomarkers.

The core AD CSF biomarkers enter novel diagnostic criteria

In 2007, the International Working Group (IWG) published the first research criteria for the diagnosis of prodromal AD [44], which provided a new conceptual framework based on that AD could be diagnosed before the dementia stage, by the combination of a clinical phenotype of episodic memory disturbances and one or more abnormal AD biomarker (CSF biomarkers, volumetric MRI, and amyloid PET). Similar, but not identical, criteria for MCI due to AD [45] and dementia due to AD [46] have been published by the National Institute on Aging-Alzheimer’s Association (NIA-AA) working groups on diagnostic guidelines for AD. Recently, in the updated IWG-2 criteria [47], the CSF biomarkers got a more significant role, together with amyloid PET, while the downstream topographical biomarkers (volumetric MRI and FDG-PET), were assigned as tools to monitoring disease course in AD.

Monitoring assay performance in the quality control program

Although strict quality control procedures within a clinical laboratory can assure accurate measurements over time [24] and facilitate implementation in clinical routine diagnostics [52], the between-laboratory differences in absolute levels precludes the introduction of uniform global cut-off levels and thus a more widespread implementation of CSF biomarkers in clinical routine. This is not unique for the AD CSF biomarkers, but a problem for any novel, either fluid or imaging (PET or MRI), biomarker, which simply calls for standardization efforts to solve the problems.

From the start, the QC program had several goals. The main goal was to establish a working program to monitor the performance of the CSF biomarker measurements between laboratories and between batches of reagents, just like any proficiency program that is running for common routine assays such as blood cholesterol, glucose, and tumor markers. Important goals were also to stimulate spin-off projects focused on standardization, as well as Biotech company efforts on development of novel high-quality assay versions, or building CSF biomarker assays on fully automated laboratory instruments.

Disappointingly, between-laboratory CVs have been around 15–25% for the ELISA and Luminex methods since the beginning, without any trend for improvement, despite training efforts and attempts to introduce common standard operating procedures for the methods [53], indicating the need of more automated analytical techniques.

Standardization efforts

In clinical chemistry, the highest level of standardization is through a Certified Reference Material (CRM). For the AD CSF biomarkers, this means a “Gold Standard” large CSF pool with known exact biomarker levels, from which aliquots can be distributed to kit vendors and large laboratories for harmonization of levels between assay formats, and to secure long-term (batch-to-batch) stability of assays. From the Alzheimer’s Association QC program, it was known that the largest problem with between-assay and between-batch variability was for CSF Aβ₄₂ [50]. Thus, the International Federation of Clinical Chemistry and Laboratory Medicine Working Group for CSF proteins (IFCC WG-CSF, http://www.ifcc.org/ifcc-scientific-division/sd-working-groups/csf-proteins-wg-csf/), was initiated to start working on standardization of this biomarker [54], in close conjunction with the Alzheimer’s Association Global Biomarker Standardization Consortium [55].

To set the absolute concentration of Aβ₄₂ in the CRM, methods capable of absolute quantification without matrix effects is needed. With the aim to develop such a “Gold Standard” method, called a Reference Measurement Procedure (RMP), a first paper on a selected reaction monitoring mass spectrometry method for CSF Aβ₄₂, where isotope-labeled Aβ₄₂ was added to the CSF sample prior to sample workup for use as an internal standard, was published [56]. The fully validated CSF Aβ₄₂ candidate RMP was published in 2014 [57], and was approved and listed as an RMP (No. C11RMP9) by the Joint Committee for Traceability in Laboratory Medicine [58], which is the regulatory body for reference methods, in 2015.

In the development process of a CRM, the type of matrix for this material needs to be evaluated in so called commutability studies, i.e., studies examining whether the measured values in different candidate CRMs align with individual CSF samples when measured using different assay formats. For Aβ₄₂, such a commutability study showed that only native human CSF works as a CRM, and that so-called artificial CSF, or Aβ₄₂ spiked into buffer, did not commute, meaning that such materials did not behave like the native peptide present in human CSF when quantified using different assays [59]. For this reason, together with the Joint Research Centre European Commission Science Hub (see https://ec.europa.eu/jrc/en/reference-materials), the IFCC-WG CSF decided to develop three CRMs, with low, medium, and high Aβ₄₂ levels, with exact concentrations assigned using the RMP and equivalent methods that have been tested in Round Robin studies for concordance [39]. These three CRMs (or aliquot sets) have also been tested for homogeneity, long-term stability, and other quality measures, and will serve at the top of the calibration hierarchy, for calibration of commercial assays to these reference aliquots, which will make the different assays directly comparable to each other. We see the above as important steps in the standardization of Aβ₄₂, the trickiest AD CSF biomarker.

Fully automated instruments for the AD CSF biomarkers

In clinical chemistry, for the majority of protein biomarkers, e.g., PSA for prostate cancer and troponin-T for myocardial infarction, analyses are performed on fully automated laboratory instruments. These instruments are very exact, and there are no manual steps, meaning that the assays have superior performance as compared with, for example, ELISA methods. In 2016, a paper was published on the full validation and analytical performance a novel β-amyloid (1–42) assay on such a fully automated instrument [60]. Results showed excellent performance (repeatability CVs for human CSF pools of 1.0%–1.6% and intermediate CVs of 1.9%–4.0%) and very low between-batch variability (correlation coefficients for 100 individual samples analyzed using three different batches of reagents of 0.996–0.998). This assay has also been running in the QC program since 2014, with coefficients of variations (CVs) dropping to a mean of 4% (for in total 22 individual QC samples analyzed from 2014–2017) as compared with a mean of 15-16% for the ELISA methods during the same time period. Assays for T-tau and P-tau on fully automated instruments have also been developed and have done one round in the QC program, showing excellent CVs of 3.7% (T-tau) and 1.9% (P-tau). A number of companies are building assays on fully automated laboratory, meaning that clinical laboratories can choose between different platforms for their clinical routine measurements.

These new types of assays will serve as the basis for highly stable and precise results for CSF biomarkers, which, together with certified reference materials, will allow for the establishment of uniform worldwide cut-off levels. We believe that this will lead to a more general use of CSF biomarkers in the routine diagnostic evaluation of patients with suspected AD, and also in clinical trials in novel disease-modifying drugs. Last, highly exact CSF biomarker levels with stable results between batches will allow for both longitudinal studies and merging data from clinical research centers worldwide, in clinical studies on disease pathogenesis.

As mentioned above, the proportion of cognitively unimpaired elderly harboring AD pathology increases with age, particularly after age 65 [7–9, 62], and that the amounts of plaques and tangles varies between late onset AD patients, and overlaps with those found in cognitively unimpaired elderly [8, 63]. Therefore, it will probably not be possible to identify any AD biomarker reflecting pathology that will show a complete discrimination; instead, studies show a clear overlap in both CSF Aβ₄₂ and SUVr values between AD patients and controls [64]. It is our belief that reporting absolute biomarker values (instead of reporting back results as being “positive” or “negative”) will allow clinicians to manage patients with clearly abnormal biomarker values and those with values close to the cut-off (sometimes called “grey zone” values) differently. The improved performance of the novel automated assays may help in this respect.

Early search for synaptic proteins in CSF

Based on semi-preparative scale chromatographic and gel electrophoretic protein separation combined with western blotting and mass spectrometric identification, in the late 1990s we were able to identify synaptic proteins in CSF from the key synaptic compartments, including the presynaptic vesicle proteins synaptotagmin and rab3a, the presynaptic membrane protein SNAP-25, and the dendritic protein neurogranin [77, 78]. These discoveries served as the motivation to initiate a project on production on novel antibodies and detailed mass spectrometric characterization of synaptic proteins in human CSF aiming at developing quantitative immunoassays for reliable quantification in individual samples. A first pilot study in 2010, based on semi-quantitative immunoprecipitation combined with western blotting showed promising results with a marked increase in CSF neurogranin in AD [79].

Dendritic proteins: Neurogranin

Dendritic spines are specialized protrusions on the dendrites, the point where neurons receive and integrate information. Neurogranin is a dendritic protein, expressed in the cortex and hippocampus by excitatory neurons [80, 81], and is known to play an important role in long-term potentiation [82, 83]. Neurogranin expression is highest in associative cortical areas, but levels are markedly reduced in the hippocampus and the frontal cortex in AD, indicating loss of post-synaptic elements [84, 85]. Thus, measurement of neurogranin in CSF may serve as a biomarker for dendritic instability and synaptic degeneration.

After developing novel monoclonal antibodies to measure neurogranin by ELISA, high CSF levels were found to predict prodromal AD in MCI [86]. High CSF neurogranin in AD dementia and prodromal AD has been confirmed in several subsequent papers [87, 88], including in the ADNI study [89]. High CSF neurogranin also correlates with future rate of hippocampal trophy measured by MRI and rate of metabolic reductions on FDG-PET [89]. Interestingly, a recent study suggests that high CSF neurogranin may be specific for AD, and not found in other neurodegenerative disorders such as frontotemporal dementia, Lewy body dementia, Parkinson’s disease, progressive supranuclear palsy, or multiple system atrophy [90]. A recent large study confirms that increased CSF neurogranin levels is found in AD dementia and prodromal AD, but not in other neurodegenerative disorders such as frontotemporal dementia, Lewy body dementia, Parkinson’s disease, progressive supranuclear palsy, corticobasal degeneration, or amyotrophic lateral sclerosis (Portelius et al., unpublished).

Mass spectrometry characterization of neurogranin in CSF suggests that it is present in CSF as a series of C-terminal peptides [86], while other studies using a sandwich immunoassay combining N- and C-terminal antibodies, which thus measures full-length neurogranin [91], as well as an assay specific for neurogranin peptides ending at position 75 [92], also found high CSF levels in AD and MCI as compared with controls Thus, we need further studies on how neurogranin is processed and released from neurons into the CSF, including studies comparing the diagnostic potential of full-length versus C-terminal neurogranin peptides.

Presynaptic biomarkers

In the presynaptic terminal, the SNARE complex proteins, including synaptosomal-associated protein 25 (SNAP-25), syntaxin-1, and vesicle-associated membrane protein (VAMP)/synaptobrevin, are key components of the molecular machinery that drives fusion of membranes in neurotransmitter exocytosis [93]. While SNAP-25 is located at the synaptic vesicles, synaptotagmin-1 (SYT1) is found in the presynaptic plasma membrane, and is essential for synaptic vesicle exocytosis, and thus neurotransmitter release [94].

The levels of both SNAP-25 and SYT1 are reduced in cortical areas in the AD brain [84, 95], reflecting the synaptic degeneration and loss in AD. Interestingly, using immunoprecipitation mass spectrometry methods, a marked increase in the CSF levels of both SNAP-25 and SYT1 was found in AD dementia and prodromal AD cases [95, 96]. These promising results need validation in future studies, but suggest that a set of synaptic proteins covering different components of the synaptic unit (dendrites – neurogranin, presynaptic plasma membrane – SNAP-25, synaptic vesicles – SYT1) may be valuable tools in clinical studies on the relevance of synaptic dysfunction and degeneration in AD pathogenesis, and maybe also in the clinical evaluation of patients.

Aβ in plasma

While numerous papers on CSF Aβ₄₂ consistently have found a high concordance with amyloid PET measures of plaque burden [23], and a marked decrease in AD, studies on plasma Aβ₄₂ as a biomarker reflecting brain amyloid pathology (and thus AD) have been disappointing, with contradictory results, with no or minor changes and large overlaps in both Aβ₄₂ and Aβ₄₀ levels between patients and controls [18]. This lack of association with disease pathology may be due to the contribution from peripheral tissues to plasma Aβ, as also evidenced by the lack of correlation between plasma and CSF Aβ concentrations [116]. The poor disease association might also be related to analytical shortcomings using ELISA methods or other standard immunoassays, e.g., epitope masking by hydrophobic Aβ peptides binding to plasma proteins [117], or other interferences that might be mitigated by analytical improvements.

In 2011, we published a novel method based on the Single Molecule Array (Simoa) technique for measurement of Aβ₄₂ in plasma [118]. This technique is based on immunocapture of the protein biomarker on magnetic beads, which are trapped in femto-liter volume wells, followed by addition of enzyme-labelled detection antibody and digital quantification that allows for exact quantification of Aβ₄₂ down to sub-picogram per mL levels (limit of quantification of 0.04 pg/mL). The high analytical sensitivity allows for pre-dilution of samples that may reduce matrix interferences. When evaluating this assay in the large Swedish BioFINDER study cohort, weak but significant correlations were found between both plasma Aβ₄₂ and the Aβ_42/40 ratio and the corresponding CSF measures, as well as to cortical ^[18F]flutemetamol PET retention [119]. Significantly lower plasma Aβ_42/40 ratio (p < 0.002) was found in both MCI and AD cases as compared with controls.

In an attempt to evaluate if mass spectrometric analysis may give a more accurate quantification of Aβ peptides in plasma, we developed an immunoprecipitation (IP) mass spectrometry (MS) selected reaction monitoring method for quantification of Aβ₄₂ and Aβ₄₀, where stable isotope-labeled Aβ peptides are added to the sample before analysis (and thus processed and analyzed simultaneously with endogenous Aβ peptides) and using the detergent octyl-glucopyranoside to disrupt complexes between Aβ and plasma proteins such as albumin [120]. In a small pilot clinical study based on clinically diagnosed cases, we were not able to find any significant change, even if there was an apparent trend for a reduction on both plasma Aβ₄₂ and the Aβ_42/40 ratio in AD [120]. Interestingly, using a similar IP-MS method, also involving LysN proteolytic digestion of Aβ peptides before analysis, significantly lower Aβ₄₂ concentration and Aβ_42/40 ratio was found in amyloid PET-positive compared with negative cases [121]. The Aβ_42/40 ratio was 14% lower in the amyloid PET positive group, which gave an impressive ROC value of 0.89 [121]. These very promising results call for further studies to evaluate plasma Aβ as a screening tool for brain amyloidosis and AD, also including larger clinical cohorts and comparisons of different analytical platforms for measurement.

Tau protein in plasma

Ultrasensitive immunoassay techniques also allow for measurement of tau protein in blood samples [115], with increased tau levels in plasma in AD found using both the immuno-magnetic reduction [122] and Simoa [123], methods. A large study on both the ADNI and BIOFINDER cohorts could confirm an increase in plasma tau concentrations in AD dementia, although with a substantial overlap in levels with controls [124]. Interestingly, longitudinal data showed significant correlations between plasma tau levels and future cognitive decline, as well as increases in atrophy measured by MRI and in hypometabolism measured by FDG PET during follow-up [124]. Thus, current data suggest a minor increase in plasma tau in AD, although with too large overlap with controls to be diagnostically useful. Tau protein in CSF has been found to be present as truncated fragments [125], and it is possible that development of assays based on antibodies for specific tau fragments will improve performance. Alternatively, measurement of T-tau or P-tau in neuron-enriched exosome preparations may improve performance for tau as a blood biomarker [126], but further studies are needed to validate this finding.

Neurofilament light in plasma

We have also developed a highly sensitive Simoa method for the axonal protein neurofilament light (NFL) protein [127]. This assay has many-fold higher analytical sensitivity than assays using the same anti-NFL antibodies based on the electrochemiluminescence (ECL) Meso Scale Diagnostics (MSD) technique or standard ELISA [128], meaning that NFL can be measured also in blood samples from normal individuals who have plasma NFL concentrations that are below the level for accurate quantification when using ECL-MSD or ELISA. In contrast to tau protein, the correlation between plasma and CSF levels of NFL protein is tight [127].

A recent study on the ADNI cohort showed a marked increase in plasma NFL in AD cases (149% of control levels), with a ROC AUC value of 0.87, which is comparable to the core AD CSF biomarkers [129]. While the change in the MCI group was less pronounced, plasma NFL was highest MCI cases with positive amyloid PET scans, and predicted faster cognitive deterioration, higher rate of future both brain atrophy (measured by MRI) and hypometabolism as measured by FDG-PET [129]. Importantly, in a study on 48 familial AD mutation carriers and non-carriers, blood NFL was increased in symptomatic familial FAD cases, but also in pre-symptomatic mutation carriers, with levels correlating with expected estimated year of symptom onset as well as both cognitive and MRI measures of disease stage [130]. These results indicate that blood NFL detects neurodegeneration also in the preclinical stage of AD.

In this context, an important piece of knowledge is that high plasma (or CSF) NFL is not a feature that is specific for AD. Instead, increased levels are found in many neurodegenerative disorders, such as frontotemporal dementia, progressive supranuclear palsy and corticobasal syndrome [131, 132]. Thus, a possible future application for plasma NFL is as a screening test at the first clinical evaluation of patients with cognitive disturbances, e.g., at the primary care unit. Here, plasma NFL might serve as simple, non-invasive, and cheap screening tool, primarily to rule out neurodegeneration.