Literature DB >> 31464088

Agreement of amyloid PET and CSF biomarkers for Alzheimer's disease on Lumipulse.

Daniel Alcolea^1,2, Jordi Pegueroles^1,2, Laia Muñoz^1,2, Valle Camacho³, Diego López-Mora³, Alejandro Fernández-León³, Nathalie Le Bastard⁴, Els Huyck⁴, Alicia Nadal⁵, Verónica Olmedo⁵, Frederic Sampedro², Victor Montal^1,2, Eduard Vilaplana^1,2, Jordi Clarimón^1,2, Rafael Blesa^1,2, Juan Fortea^1,2, Alberto Lleó^1,2.

Abstract

OBJECTIVE: To determine the cutoffs that optimized the agreement between 18 F-Florbetapir positron emission tomography (PET) and Aβ1-42, Aβ1-40, tTau, pTau and their ratios measured in cerebrospinal fluid (CSF) on the LUMIPULSE G600II instrument, we quantified the levels of these four biomarkers in 94 CSF samples from participants of the Sant Pau Initiative on Neurodegeneration (SPIN cohort) using the Lumipulse G System with available 18 F-Florbetapir imaging.
METHODS: Participants had mild cognitive impairment (n = 35), AD dementia (n = 12), other dementias or neurodegenerative diseases (n = 41), or were cognitively normal controls (n = 6). Levels of Aβ1-42 were standardized to certified reference material. Amyloid scans were assessed visually and through automated quantification. We determined the cutoffs of CSF biomarkers that optimized their agreement with 18 F-Florbetapir PET and evaluated concordance between markers of the amyloid category.
RESULTS: Aβ1-42, tTau and pTau (but not Aβ1-40) and the ratios with Aβ1-42 had good diagnostic agreement with 18 F-Florbetapir PET. As a marker of amyloid pathology, the Aβ1-42/Aβ1-40 ratio had higher agreement and better correlation with amyloid PET than Aβ1-42 alone.
INTERPRETATION: CSF biomarkers measured with the Lumipulse G System show good agreement with amyloid imaging in a clinical setting with heterogeneous presentations of neurological disorders. Combination of Aβ1-42 with Aβ1-40 increases the agreement between markers of amyloid pathology.

Entities: Chemical Disease Gene Species

Year: 2019 PMID： 31464088 PMCID： PMC6764494 DOI： 10.1002/acn3.50873

Source DB: PubMed Journal: Ann Clin Transl Neurol ISSN： 2328-9503 Impact factor: 4.511

Introduction

Advances in the field of biomarkers have pushed forward a redefinition of Alzheimer's disease (AD) as a biological construct.1 Under this definition, the ATN classification system recognizes three general groups of biomarkers for AD: biomarkers of β‐amyloid plaques (A), biomarkers of fibrillar tau (T) and biomarkers of neurodegeneration or neuronal injury (N).1 These categories can be assessed by using different modalities, but those that are more widely implemented are cerebrospinal fluid (CSF) biomarkers and imaging techniques. Amyloid positron emission tomography (PET), CSF Aβ1‐42 and the ratio Aβ1‐42/Aβ1‐40 correspond to the “A” category, Tau PET and CSF pTau to the “T” category, whereas 18F‐Fluorodeoxyglucose‐PET, anatomical MRI and tTau are considered markers of the “N” category.1 Within the “A” category, the concordance between CSF Aβ1‐42 and amyloid PET imaging is high, but not perfect.2, 3, 4, 5, 6 In fact, the Aβ1‐42/Aβ1‐40 ratio has shown to have better agreement with amyloid PET imaging compared to levels of Aβ1‐42 alone.4, 7, 8, 9 In recent years, fully automated platforms have been developed for the analysis of CSF biomarkers. Recently, four CSF analytes (Aβ1‐42, Aβ1‐40, tTau and pTau) have been implemented on the fully automated Lumipulse G System, but there are no validated cutoffs for these four AD CSF biomarkers using this platform. Our aims were to determine for the first time the cutoffs that optimized the agreement between 18F‐Florbetapir PET and Aβ1‐42, Aβ1‐40, tTau, pTau and their ratios measured in CSF on the LUMIPULSE G600II instrument, and to evaluate the concordance between markers of the amyloid category.

Methods

Study participants

We included 94 participants from the Sant Pau Initiative on Neurodegeneration (SPIN cohort) recruited between November 2013 and September 2017 who had available CSF samples and 18F‐Florbetapir PET imaging (Table 1). The SPIN cohort is a multimodal research cohort for biomarker discovery and validation that includes participants with different neurodegenerative dementias, mild cognitive impairment and cognitively normal controls. All participants receive an extensive neurological and neuropsychological evaluation and undergo structural 3T brain MRI, blood extraction, and lumbar puncture for CSF biomarkers. A subset of participants also receives molecular imaging such as 18F‐Fluorodeoxyglucose‐PET, amyloid and/or Tau PET. More information on the SPIN cohort can be found at https://santpaumemoryunit.com/our-research/spin-cohort (Alcolea et al., submitted). All participants gave written consent, and the ethics committee of Hospital Sant Pau approved all procedures included in this study.

Table 1

Clinical and demographic characteristics of all participants and based on visual amyloid PET status.

	All participants	Amyloid positive	Amyloid negative	P value
n (%)	94 (100%)	59 (63%)	35 (37%)	–
Age, years	73.0 (7.6)	73.5 (7)	72.1 (8.5)	0.405^*
Sex, female/male (% female)	50/44 (53%)	32/27 (54%)	18/17 (51%)	0.960^†
APOEε4 +/− (% +)	56/37 (60%)	30/28 (52%)	7/28 (20%)	0.004^†
MMSE score	24.7 (4.1)	24.1 (4.3)	25.7 (3.6)	0.052^*
Time difference between amyloid PET and lumbar puncture, days	152 (86)	151 (78)	156 (100)	0.792^*
Clinical diagnosis, n (%)				0.067^†
Cognitively normal	6 (100%)	3 (50%)	3 (50%)	–
Mild cognitive impairment	35 (100%)	23 (66%)	12 (34%)	–
AD dementia	12 (100%)	11 (92%)	1 (8%)	–
Dementia with Lewy bodies	30 (100%)	18 (60%)	12 (40%)	–
Frontotemporal dementia	9 (100%)	3 (33%)	6 (67%)	–
Other diagnoses	2 (100%)	1 (50%)	1 (50%)	–
CSF biomarkers
Aβ1‐42, pg/mL	745 (379)	608 (213)	985 (474)	<0.001^*
Aβ1‐40, pg/mL	12252 (3944)	12782 (3954)	11360 (3816)	0.089^*
tTau, pg/mL	566 (363)	667 (375)	397 (273)	<0.001^*
pTau, pg/mL	93 (71)	114 (71)	58 (58)	0.001^*
Aβ1‐42/Aβ1‐40	0.064 (0.028)	0.049 (0.015)	0.088 (0.027)	<0.001^*
tTau/Aβ1‐42	0.95 (0.76)	1.17 (0.63)	0.57 (0.81)	<0.001^*
pTau/Aβ1‐42	0.16 (0.15)	0.20 (0.12)	0.09 (0.16)	<0.001^*

Unless otherwise specified, results are presented as mean (standard deviation).

MMSE, Mini‐mental state examination; AD, Alzheimer's disease; CSF, cerebrospinal fluid; PET, positron emission tomography.

P‐values were calculated by comparing amyloid–positive and amyloid–negative participants using Welch two‐sample t‐test (*) or Fisher's exact test (†).

Clinical and demographic characteristics of all participants and based on visual amyloid PET status. Unless otherwise specified, results are presented as mean (standard deviation). MMSE, Mini‐mental state examination; AD, Alzheimer's disease; CSF, cerebrospinal fluid; PET, positron emission tomography. P‐values were calculated by comparing amyloid–positive and amyloid–negative participants using Welch two‐sample t‐test (*) or Fisher's exact test (†).

CSF samples acquisition and analysis

CSF samples were collected in 10 mL polypropylene tubes (Sarstedt, Ref#62.610.018) and transferred to the Sant Pau Memory Unit's laboratory where they were processed within the first 2 h after acquisition. After centrifugation (2000g × 10 min, 4°C), volumes of 0.5 mL of CSF were aliquoted into polypropylene tubes (Sarstedt, Ref#72.694.007) and stored at −80°C until analysis. On the day of the analysis, samples were thawed at room temperature and the tubes were vortexed for 5–10 sec. To avoid the effect of multiple freeze‐thaw cycles, aliquots used in this study had not been thawed before. Aβ1‐42, Aβ1‐40, tTau and pTau were quantified directly from the storage tubes containing 0.5 mL of CSF using the Lumipulse G β‐Amyloid 1‐42, β‐Amyloid 1‐40, Total Tau and pTau 181 assays on LUMIPULSE G600II automated platform (Fujirebio) and following the manufacturer's instructions. We used an adapter to fit the tubes in the equipment. We used the same batch of reagents for each biomarker throughout the study, and for each sample, we measured all four analytes from the same aliquot and in the same run. The platform was configured to start the analysis with Aβ1‐42, followed by Aβ1‐40, tTau and pTau. Buffer‐based quality control testing was performed at the beginning of each test day to ensure that all measured values of each control level (low, medium and high) were within the target ranges. The results of the Lumipulse G β‐Amyloid 1‐42 presented in this study have been standardized according to certified reference material developed by the International Federation of Clinical Chemistry and Laboratory Medicine as recommended by their working group for CSF proteins.10 Briefly, values of the calibration standards of the LUMIPULSE G600II were adapted to the certified reference material resulting in an adjustment of concentrations that was linearly proportional throughout the range. The aim of standardization to certified reference material is to harmonize immunoassays of Aβ1‐42 to make results comparable across different platforms. Aβ1‐42, Aβ1‐40, tTau and pTau levels in CSF from participants of this study had been measured previously using other immunoassays (INNOTEST β‐AMYLOID(1‐42), INNOTEST hTAU Ag, and INNOTEST PHOSPHO‐TAU(181P), Fujirebio Europe; and High Sensitivity Human Amyloid β40, Merck‐Millipore), and these results were available in our database for their comparison with the LUMIPULSE analyses.11, 12, 13, 14, 15 The personnel involved in the CSF analyses for this study were blinded to the clinical diagnosis and to previous biomarker determinations.

Amyloid‐PET imaging acquisition, visual assessment and quantitative analysis

All participants underwent amyloid PET imaging with 18F‐Florbetapir as described elsewhere.13 PET data were acquired using a Philips Gemini TF scan 50 min after injection of 370mBq of 18F‐Florbetapir. After obtaining the transmission data, brain PET dynamic acquisition was performed (2 × 5 min frames). The reconstruction method was iterative (LOR RAMBLA, three iterations and 33 subsets) with a 128 × 128 image size, 2 mm pixel size and slice thickness. Three expert readers (V.C., D.L‐M. and A.F‐L.) blind to clinical diagnosis and to CSF biomarkers visually rated all PET scans. Following manufacturer's protocol, scans were classified as “positive” when one or more areas showed increased cortical gray matter signal resulting in reduced or absent contrast between gray matter and white matter. Scans were classified as “negative” when the contrast between gray matter and white matter was clear. Final classification as “positive” or “negative” was decided upon agreement of at least two of three readers. Mean inter‐reader overall agreement was 88.4% (Min = 87.0%, Max = 90.2%). We also quantified amyloid deposition. Each participant's PET scan was spatially normalized to a MNI152 18F‐Florbetapir template using a linear and nonlinear transformation.16 Mean 18F‐Florbetapir uptake was measured across frontal, lateral parietal, lateral temporal and anterior/posterior cingulate. Then, the 18F‐Florbetapir standardized uptake value ratio (SUVR) map was extracted using the whole cerebellum as reference.17 The PET scans of five participants were not suitable for 18F‐Florbetapir quantification and excluded of quantitative analyses.

Statistical analysis

We performed receiver operating characteristic (ROC) analysis for Aβ1‐42, Aβ1‐40, tTau, pTau and the ratios Aβ1‐42/Aβ1‐40, tTau/Aβ1‐42 and pTau/Aβ1‐42 to calculate areas under the curve (AUC) with 95% confidence intervals (DeLong). We compared ROC curves by two‐sided bootstrapping with 2000 replications. For biomarkers and ratios that showed AUC higher than 0.70, we determined positive percent agreement (PPA or sensitivity) and negative percent agreement (NPA or specificity) and calculated optimal cutoffs maximizing their Youden J index (PPA + NPA − 1). We calculated overall percent agreement (OPA) between CSF biomarker cutoffs and amyloid PET visual interpretation as the sum of participants classified as “positive” or as “negative” by both modalities over the total number of participants. We also analyzed the correlation of CSF biomarkers with global amyloid accumulation by fitting quadratic models and calculated the agreement of CSF biomarkers cutoffs with the PET scans quantification status applying a previously described SUVR cutoff of 1.11.17 Level of significance was set at α = 0.05. We used Analyse‐it® statistical software for the selection of optimal cutoffs and packages “car” (v.3.0‐3, Fox&Weisberg 2019), “pROC” (v.1.15.0, Robin et al 2011), “grid” (R core team 2019) and “ggplot2” (v.3.1.1, Wickham 2016) as implemented in R statistical software (v 3.6.0) for plots and statistical analyses.

Results

We included 94 participants in the study. Table 1 summarizes demographic characteristics and biomarker results. There were no differences in age or sex between both groups. As expected, the amyloid–positive group had a higher proportion of APOEε4 carriers compared to the amyloid–negative group (52% and 20%, respectively; P = 0.004).

Quantification of Aβ1‐42, Aβ1‐40, tTau and pTau concentrations on the LUMIPULSE G600II

We measured Aβ1‐42, Aβ1‐40, tTau and pTau levels simultaneously on the Lumipulse G System. Their levels in the overall study population ranged from 315 to 2280 pg/mL for Aβ1‐42, 4585 to 25925 pg/mL for Aβ1‐40, 141 to 1902 pg/mL for tTau, and 18 to 340 pg/mL for pTau. The analyses were divided over three calibration runs on the LUMIPULSE G600II, and the calibration status was valid for all samples. Mean interassay coefficients of variation are displayed in Figure S1. Most CSF samples included in this study had previously been analyzed using other immunoassays, and their results were available in our database. Although these historic results were obtained in the context of routine clinical assessment by using different batches, and therefore a side‐to‐side precision analysis could not be performed, we explored their correlation with the Lumipulse G quantifications. The Lumipulse G assays for Aβ1‐42, tTau and pTau showed very high correlation with values previously measured with Fujirebio's INNOTEST ELISA (Pearson's r of 0.94, 0.95 and 0.95, respectively, all P < 0.001). The Lumipulse G assay for Aβ1‐40 showed moderate correlation with values measured with Merck‐Millipore's ELISA (Pearson's r of 0.76, P < 0.001). On the Lumipulse G system, tTau and pTau were highly correlated (Pearson's r of 0.98, P < 0.001).

Agreement between 18F‐Florbetapir visual status and CSF biomarkers

As displayed in Figure 1A, of individual biomarkers, tTau and pTau had the highest accuracy and showed AUC of 0.80 (95%CI 0.70–0.89, P < 0.001) and 0.84 (95%CI 0.75–0.93, P < 0.001), respectively. Aβ1‐42 had fair accuracy with an AUC of 0.76 (95%CI 0.65–0.86, P < 0.001) and Aβ1‐40 alone was not useful for the detection of the visual status of amyloid scans (AUC 0.59; 95%CI 0.47–0.71, P = 0.134).

Figure 1

Receiver operating characteristic analysis of individual (A) and combined (B) CSF biomarkers' diagnostic utility to detect amyloid visual status. AUC, Area under the curve.

Receiver operating characteristic analysis of individual (A) and combined (B) CSF biomarkers' diagnostic utility to detect amyloid visual status. AUC, Area under the curve. Figure 1B shows that the combination of Aβ1‐42 with a second analyte resulted in significant increases of accuracy. The AUC of Aβ1‐42/Aβ1‐40 was 0.86 (95%CI 0.77–0.96, P < 0.001), higher than that of Aβ1‐42 alone (D = −2.5; P = 0.01) or Aβ1‐40 alone (D = −4.0; P < 0.001). tTau/Aβ1‐42 had an AUC of 0.87 (95%CI 0.78–0.95, P < 0.001), higher than that of tTau (D = −2.2; P = 0.03), and pTau/Aβ1‐42 had an AUC of 0.88 (95%CI 0.79–0.97, P < 0.001), higher than that of pTau alone (D = −1.9; P = 0.05). There were no significant differences in the AUC of the three ratios, and combining a third biomarker in the ratios did not improve their accuracy (data not shown).

CSF biomarker cutoffs based on visual interpretation of amyloid status

For those biomarkers and ratios that showed AUC higher than 0.70, we used ROC analysis to obtain PPA, NPA and OPA for all possible cutoffs. As displayed in Figure 2, in the case of single biomarkers, Aβ1‐42, tTau and pTau, the selection was based on clear Youden peaks at 916, 456 and 63 pg/mL, respectively. For the ratios Aβ1‐42/Aβ1‐40, tTau/Aβ1‐42 and pTau/Aβ1‐42, plots showed plateau stages indicating that a wide range of cutoffs yielded similar Youden indices. Best cutoffs for ratios were 0.062 for Aβ1‐42/Aβ1‐40, 0.62 for tTau/Aβ1‐42, and 0.068 for pTau/Aβ1‐42.

Figure 2

Accuracy of all possible cutoff levels of individual (A, C, E) and combined (B, D, F) CSF biomarkers. Only those biomarkers that yielded areas under the curve above 0.70 and their ratios with Aβ1‐42 are shown. Vertical dotted lines indicate cutoffs with maximum Youden J index. PPA, Positive Percent Agreement; NPA, Negative Percent Agreement; OPA, Overall Percent Agreement. Figure 3 displays the agreement between visual status of 18F‐Florbetapir and CSF biomarker cutoffs. For Aβ1‐42, tTau and pTau, the OPA values between visual status and CSF biomarkers status were 79%, 78% and 81%, respectively. The ratio of Aβ1‐42 with Aβ1‐40, tTau and pTau increased the OPA to 84%, 82% and 88%, respectively.

Figure 3

Agreement of visual amyloid status with single and combined CSF biomarkers. Panels A, B and C display scatterplots of CSF biomarker levels. Dashed lines indicate cutoffs that yielded maximum Youden J Index in the receiver operating characteristic analysis for each biomarker or ratio. PPA, Positive Percent Agreement; NPA, Negative Percent Agreement; OPA, Overall Percent Agreement.

Markers of amyloid and importance of assessing a second biomarker

Within each CSF biomarker status, the proportion of positive amyloid scans varied when a second biomarker or ratio was taken into account. Figure S2 shows the proportion of positive amyloid scans within each combination of two CSF biomarkers or ratios, and illustrates the importance of considering a second biomarker. Of all participants with low CSF levels of Aβ1‐42, regardless of the Aβ1‐42/Aβ1‐40 ratio status, 77% (56 out of 73) had a positive amyloid scan. This proportion increased to 87% (52 out of 60) within this group when the Aβ1‐42/Aβ1‐40 ratio was also low but decreased to 31% (four out of 13) when the Aβ1‐42/Aβ1‐40 ratio was high. In the group of participants with high CSF levels of Aβ1‐42, the impact of considering the Aβ1‐42/Aβ1‐40 status had no effect, as in all participants within this group the Aβ1‐42/Aβ1‐40 ratio was also high. These results highlight the importance of using the Aβ1‐42/Aβ1‐40 ratio over Aβ1‐42 alone in the assessment of brain amyloidosis, especially in patients with low CSF levels of Aβ1‐42.

Agreement of CSF cutoffs with amyloid quantification

We next processed amyloid PET scans to obtain quantification values of amyloid deposition. In our study, the previously validated SUVR value of 1.11,17 showed 83% PPA, 76% NPA, and 81% OPA with visual classification. As displayed in Figure 4, scans that were divergently classified as “negative” or “positive” by one of the three raters showed intermediate SUVR values compared to scans that were unanimously classified.

Figure 4

Agreement between raters' visual classification and amyloid quantification. OPA, Overall Percent Agreement; SUVR, Standardized Uptake Value Ratio. Panel A shows the agreement between amyloid quantification and rater's individual and global visual assessments. Panel B shows the agreement between amyloid quantification and visual assessment stratified by the number of raters that assessed scans as positive. As seen in Figure 5, the agreement of CSF cutoffs with amyloid PET quantification was similar to that with visual classification for all biomarkers. We studied the correlation between each CSF biomarker and global amyloid accumulation by fitting quadratic models. In these models, the adjusted coefficients of determination (R) were higher for all ratios compared to individual biomarkers. The combination of Aβ1‐42 with Aβ1‐40 increased the R value to 0.44 (P < 0.001), indicating that this ratio reflects the amyloid deposition better than Aβ1‐42 alone. Stratified analysis by 18F‐Florbetapir visual status showed lower R values for all biomarkers, which suggests that the correlation observed between CSF biomarkers and amyloid PET quantification is partially mediated by an amyloid‐status effect. In this stratified analysis, the highest correlation of SUVR values was found with the Aβ1‐42/Aβ1‐40 ratio in the amyloid–negative group (R = 0.42; P < 0.001).

Figure 5

Scatterplots and correlations of amyloid quantification values with individual biomarkers (A, C, E) and ratios (B, D, F). Correlation between SUVR values and CSF biomarkers was assessed by fitting quadratic models for all participants (black) and after stratifying by visual amyloid status (red and green). Shaded areas indicate 95% confidence intervals. Dashed vertical lines indicate the SUVR cutoff of 1.11 as in Landau et al. Horizontal lines correspond to cutoffs for each CSF biomarker and ratio. PPA, NPA and OPA values correspond to the agreement between amyloid quantification and CSF biomarkers. PPA, Positive Percent Agreement; NPA, Negative Percent Agreement; OPA, Overall Percent Agreement; SUVR, Standardized Uptake Value Ratio.

Discussion

In our study, we determined cutoffs for four CSF biomarkers for AD (Aβ1‐42, Aβ1‐40, tTau and pTau) and their ratios measured on the fully automated LUMIPULSE G600II platform to optimize their concordance with 18F‐Florbetapir PET. We calibrated Aβ1‐42 levels to certified reference material, recently developed to harmonize immunoassays across different platforms, and found that the ratios Aβ1‐42/Aβ1‐40, tTau/Aβ1‐42 and pTau/Aβ1‐42 had better diagnostic agreement with visual assessment of amyloid scans than single biomarkers. As a marker of amyloid pathology, the Aβ1‐42/Aβ1‐40 ratio had higher agreement with amyloid PET visual status and showed better correlation with amyloid load quantification compared to Aβ1‐42 alone. The agreement between amyloid imaging and AD CSF biomarkers has previously been studied by using other automated immunoassays.3, 4, 8 Our results are in line with previous studies showing a good overall agreement between amyloid imaging and AD CSF biomarkers, higher for ratios than for single analytes.3, 4 However, specific cutoff points for CSF biomarkers differ between these studies, and several methodological differences can explain these discrepancies. First, preanalytical conditions, such as the type of collection and storage tubes, are different between studies, and these factors are known to have a great impact on the absolute values of CSF biomarkers, especially for Aβ1‐42.18, 19 Second, some analytical particularities for each immunoassay and platform used in these studies (specificity of the antibodies, time of incubation) result in diverse CSF biomarker measures. Calibration of all automated platforms to certified reference material, currently underway, will minimize this issue in the future. Likewise, differences in the affinity of PET radiotracers (11C‐Pittsburg compound B, 18F‐Flutemetamol or 18F‐Florbetapir) can lead to disparities in the selection of cutoffs. Third, the composition of the populations was not the same across studies. Schindler et al. analyzed data from community–dwelling volunteers,4 whereas Janelidze et al. obtained their results from patients with mild cognitive impairment and subjective cognitive decline from the BioFINDER cohort.8 Hansson et al. studied CSF of participants from ADNI and BioFINDER cohorts, that included cognitively normal volunteers, patients with mild cognitive impairment and patients with AD dementia.3 In our study, we additionally included patients with other dementias or neurodegenerative diseases, which might reflect more realistically the application of biomarkers in daily clinical practice. As in a number of other studies, the cutoffs in our study were selected by maximization of Youden J index. This approach balances sensitivity and specificity and is equivalent to maximize accuracy for a pre‐test disease prevalence of 50%.20 However, other strategies might be useful in certain clinical scenarios.21 For instance, for screening purposes, it might be helpful to apply cutoffs with high sensitivity, even when their specificity is lower. For patients with clinically challenging diagnoses or in clinical trials, however, high specificity might be preferable. Other possible approaches include the sequential application of biomarker cutoffs. The LUMIPULSE G600II has incorporated the possibility of measuring CSF levels of Aβ1‐40. In previous studies, and ours, this biomarker alone was not useful for the detection of brain amyloid.4, 7, 9 Both Aβ1‐42 and the Aβ1‐42/Aβ1‐40 ratio are included in the “A” category of the ATN classification system together with amyloid PET, but in line with other studies,7, 9, 22, 23 we found that the Aβ1‐42/Aβ1‐40 ratio had better agreement with visual amyloid status and higher correlation with brain amyloid quantification. Our results are in line with previous literature that suggests that the use of the Aβ1‐42/Aβ1‐40 ratio could compensate individual differences in amyloid precursor protein processing that otherwise might lead to false positive or false negative Aβ1‐42 CSF levels.24, 25 This information adds to the fact that using the Aβ1‐42/Aβ1‐40 ratio has proven to partially mitigate the effect of some preanalytical confounders that have been described to alter the results of amyloid levels.26, 27, 28 Altogether, our data suggest that the use of the Aβ1‐42/Aβ1‐40 ratio would be more reliable in clinical practice than Aβ1‐42 alone as a marker of amyloidosis and that this combination should be used in routine. The main strength of our study is that four AD CSF biomarkers (Aβ1‐42, Aβ1‐40, tTau and pTau) measured simultaneously with the automated Lumipulse G System were compared for the first time to 18F‐Florbetapir PET to calculate amyloid–based cutoffs. In addition, this is, to our knowledge, the first study to present Aβ1‐42 levels that have been standardized to certified reference material, recently developed to harmonize immunoassays across different platforms. Standardized values will make our study more easily comparable to future studies. Moreover, to avoid possible sources of variability, we followed homogeneous CSF preanalytical and analytical procedures and used the same batch of reagents for all measurements. Also, the inclusion of participants with neurodegenerative diseases outside the AD spectrum provides a more realistic application of biomarkers in daily clinical practice. However, we are aware of some limitations. We did not test the effect that deviations from our preanalytical protocol would have on the final cutoffs, and therefore, the cutoffs that we report should be taken cautiously under other operating procedures. Some of the clinical categories in our study included a small number of participants. Although we used amyloid positivity/negativity as the gold standard in our study, the composition of the sample in terms of clinical diagnosis might be relevant for the interpretation and applicability of our results. Additionally, only very few participants had additional Tau imaging and/or 18F‐Fluorodeoxyglucose‐PET, and we could not compare the agreement of CSF pTau and tTau with molecular imaging markers of the “T” and the “N” categories of the ATN classification. Likewise, as participants in this study are part of a living cohort, neuropathological confirmation is not available at this moment. In this study, we found that the Aβ1‐42 ratios to Aβ1‐40, tTau and pTau in CSF show a good agreement with amyloid visual status and that the Aβ1‐42/Aβ1‐40 ratio had better correlation with the amount of amyloid burden compared to Aβ1‐42 alone. The understanding of the agreement between CSF biomarkers and amyloid imaging is crucial to identify situations in which these two modalities might not be interchangeable. This information has to be taken into consideration both in the diagnostic assessment in clinical practice and in the selection of participants in clinical trials.

Conflict of Interest

D.A. participated in advisory boards from Fujirebio‐Europe and received speaker honoraria from Fujirebio‐Europe, Nutricia and from Krka Farmacéutica S.L. R.B. participated in advisory boards from Lilly and Nutricia, and he received speaker honoraria and travel funding from Novartis and Nutricia. A.L. participated in advisory boards from Fujirebio‐Europe, Nutricia, Biogen, and received speaker honoraria from Lilly. N.LB. and E.H. are employed by Fujirebio Europe. N.V. A.N. and V.O. are employed by Fujirebio Iberia, S.L. Figure S1. Interassay coefficients of Aβ1‐42 (A), Aβ1‐40 (B), tTau (C) and pTau (D). Figure S2. Agreement of visual amyloid PET with the combination of two CSF biomarkers or ratios. Click here for additional data file.

28 in total

1. Amyloid beta peptide ratio 42/40 but not A beta 42 correlates with phospho-Tau in patients with low- and high-CSF A beta 40 load.

Authors: Jens Wiltfang; Hermann Esselmann; Mirko Bibl; Michael Hüll; Harald Hampel; Holger Kessler; Lutz Frölich; Johannes Schröder; Oliver Peters; Frank Jessen; Christian Luckhaus; Robert Perneczky; Holger Jahn; Magdalena Fiszer; Juan Manuel Maler; Rüdiger Zimmermann; Ralf Bruckmoser; Johannes Kornhuber; Piotr Lewczuk
Journal: J Neurochem Date: 2007-01-24 Impact factor: 5.372

2. Decreased cerebrospinal fluid Abeta(42) correlates with brain atrophy in cognitively normal elderly.

Authors: Anne M Fagan; Denise Head; Aarti R Shah; Daniel Marcus; Mark Mintun; John C Morris; David M Holtzman
Journal: Ann Neurol Date: 2009-02 Impact factor: 10.422

Review 3. Determining cut-points for Alzheimer's disease biomarkers: statistical issues, methods and challenges.

Authors: Jonathan W Bartlett; Chris Frost; Niklas Mattsson; Tobias Skillbäck; Kaj Blennow; Henrik Zetterberg; Jonathan M Schott
Journal: Biomark Med Date: 2012-08 Impact factor: 2.851

4. Nonlinear Association Between Cerebrospinal Fluid and Florbetapir F-18 β-Amyloid Measures Across the Spectrum of Alzheimer Disease.

Authors: Jon B Toledo; Maria Bjerke; Xiao Da; Susan M Landau; Norman L Foster; William Jagust; Clifford Jack; Michael Weiner; Christos Davatzikos; Leslie M Shaw; John Q Trojanowski
Journal: JAMA Neurol Date: 2015-05 Impact factor: 18.302

5. Concordance Between Different Amyloid Immunoassays and Visual Amyloid Positron Emission Tomographic Assessment.

Authors: Shorena Janelidze; Josef Pannee; Alvydas Mikulskis; Ping Chiao; Henrik Zetterberg; Kaj Blennow; Oskar Hansson
Journal: JAMA Neurol Date: 2017-12-01 Impact factor: 18.302

6. Relationship between β-Secretase, inflammation and core cerebrospinal fluid biomarkers for Alzheimer's disease.

Authors: Daniel Alcolea; María Carmona-Iragui; Marc Suárez-Calvet; M Belén Sánchez-Saudinós; Isabel Sala; Sofía Antón-Aguirre; Rafael Blesa; Jordi Clarimón; Juan Fortea; Alberto Lleó
Journal: J Alzheimers Dis Date: 2014 Impact factor: 4.472

Review 7. CSF Aβ_1-42 - an excellent but complicated Alzheimer's biomarker - a route to standardisation.

Authors: Julia Kuhlmann; Ulf Andreasson; Josef Pannee; Maria Bjerke; Erik Portelius; Andreas Leinenbach; Tobias Bittner; Magdalena Korecka; Rand G Jenkins; Hugo Vanderstichele; Erik Stoops; Piotr Lewczuk; Leslie M Shaw; Ingrid Zegers; Heinz Schimmel; Henrik Zetterberg; Kaj Blennow
Journal: Clin Chim Acta Date: 2016-05-20 Impact factor: 3.786

8. Amyloid β peptides are differentially vulnerable to preanalytical surface exposure, an effect incompletely mitigated by the use of ratios.

Authors: Jamie Toombs; Martha S Foiani; Henrietta Wellington; Ross W Paterson; Charles Arber; Amanda Heslegrave; Michael P Lunn; Jonathan M Schott; Selina Wray; Henrik Zetterberg
Journal: Alzheimers Dement (Amst) Date: 2018-03-22

Review 9. NIA-AA Research Framework: Toward a biological definition of Alzheimer's disease.

Authors: Clifford R Jack; David A Bennett; Kaj Blennow; Maria C Carrillo; Billy Dunn; Samantha Budd Haeberlein; David M Holtzman; William Jagust; Frank Jessen; Jason Karlawish; Enchi Liu; Jose Luis Molinuevo; Thomas Montine; Creighton Phelps; Katherine P Rankin; Christopher C Rowe; Philip Scheltens; Eric Siemers; Heather M Snyder; Reisa Sperling
Journal: Alzheimers Dement Date: 2018-04 Impact factor: 21.566

10. CSF Aβ42/Aβ40 and Aβ42/Aβ38 ratios: better diagnostic markers of Alzheimer disease.

Authors: Shorena Janelidze; Henrik Zetterberg; Niklas Mattsson; Sebastian Palmqvist; Hugo Vanderstichele; Olof Lindberg; Danielle van Westen; Erik Stomrud; Lennart Minthon; Kaj Blennow; Oskar Hansson
Journal: Ann Clin Transl Neurol Date: 2016-01-01 Impact factor: 4.511

33 in total

Review 1. Detection of Alzheimer Disease Pathology in Patients Using Biochemical Biomarkers: Prospects and Challenges for Use in Clinical Practice.

Authors: Leslie M Shaw; Magdalena Korecka; Michal Figurski; Jon Toledo; David Irwin; Ju Hee Kang; John Q Trojanowski
Journal: J Appl Lab Med Date: 2020-01-01

2. Biomarkers of Alzheimer Disease.

Authors: Melissa M Budelier; Randall J Bateman
Journal: J Appl Lab Med Date: 2020-01-01

3. Cost-effectiveness of Alzheimer's disease CSF biomarkers and amyloid-PET in early-onset cognitive impairment diagnosis.

Authors: Jose Contador; Ana Magdalena Vargas-Martínez; Raquel Sánchez-Valle; Marta Trapero-Bertran; Albert Lladó
Journal: Eur Arch Psychiatry Clin Neurosci Date: 2022-06-16 Impact factor: 5.270

4. Establishing In-House Cutoffs of CSF Alzheimer's Disease Biomarkers for the AT(N) Stratification of the Alzheimer Center Barcelona Cohort.

Authors: Adelina Orellana; Pablo García-González; Sergi Valero; Laura Montrreal; Itziar de Rojas; Isabel Hernández; Maitee Rosende-Roca; Liliana Vargas; Juan Pablo Tartari; Ester Esteban-De Antonio; Urszula Bojaryn; Leire Narvaiza; Emilio Alarcón-Martín; Montserrat Alegret; Daniel Alcolea; Alberto Lleó; Lluís Tárraga; Vanesa Pytel; Amanda Cano; Marta Marquié; Mercè Boada; Agustín Ruiz
Journal: Int J Mol Sci Date: 2022-06-21 Impact factor: 6.208

5. Association of CSF Biomarkers With Hippocampal-Dependent Memory in Preclinical Alzheimer Disease.

Authors: Alexandra N Trelle; Valerie A Carr; Edward N Wilson; Michelle S Swarovski; Madison P Hunt; Tyler N Toueg; Tammy T Tran; Divya Channappa; Nicole K Corso; Monica K Thieu; Manasi Jayakumar; Ayesha Nadiadwala; Wanjia Guo; Natalie J Tanner; Jeffrey D Bernstein; Celia P Litovsky; Scott A Guerin; Anna M Khazenzon; Marc B Harrison; Brian K Rutt; Gayle K Deutsch; Frederick T Chin; Guido A Davidzon; Jacob N Hall; Sharon J Sha; Carolyn A Fredericks; Katrin I Andreasson; Geoffrey A Kerchner; Anthony D Wagner; Elizabeth C Mormino
Journal: Neurology Date: 2021-01-06 Impact factor: 9.910

6. P-tau/Aβ42 and Aβ42/40 ratios in CSF are equally predictive of amyloid PET status.

Authors: Michelle R Campbell; Susan Ashrafzadeh-Kian; Ronald C Petersen; Michelle M Mielke; Jeremy A Syrjanen; Argonde C van Harten; Val J Lowe; Clifford R Jack; Joshua A Bornhorst; Alicia Algeciras-Schimnich
Journal: Alzheimers Dement (Amst) Date: 2021-05-18

7. Tripartite Relationship Among Synaptic, Amyloid, and Tau Proteins: An In Vivo and Postmortem Study.

Authors: Kaitlin Blackstone Casaletto; Henrik Zetterberg; Kaj Blennow; Ann Brinkmalm; William Honer; Julie A Schneider; David A Bennett; Nina Djukic; Michelle You; Sophia Weiner-Light; Corrina Fonseca; Bruce L Miller; Joel Kramer
Journal: Neurology Date: 2021-05-04 Impact factor: 11.800

8. Development and validation of a high-sensitivity assay for measuring p217+tau in plasma.

Authors: Gallen Triana-Baltzer; Setareh Moughadam; Randy Slemmon; Kristof Van Kolen; Clara Theunis; Marc Mercken; Hartmuth C Kolb
Journal: Alzheimers Dement (Amst) Date: 2021-05-27

9. Phosphorylated tau181 in plasma as a potential biomarker for Alzheimer's disease in adults with Down syndrome.

Authors: Alberto Lleó; Henrik Zetterberg; Jordi Pegueroles; Thomas K Karikari; María Carmona-Iragui; Nicholas J Ashton; Victor Montal; Isabel Barroeta; Juan Lantero-Rodríguez; Laura Videla; Miren Altuna; Bessy Benejam; Susana Fernandez; Silvia Valldeneu; Diana Garzón; Alexandre Bejanin; Maria Florencia Iulita; Valle Camacho; Santiago Medrano-Martorell; Olivia Belbin; Jordi Clarimon; Sylvain Lehmann; Daniel Alcolea; Rafael Blesa; Kaj Blennow; Juan Fortea
Journal: Nat Commun Date: 2021-07-14 Impact factor: 14.919

10. VAMP-2 is a surrogate cerebrospinal fluid marker of Alzheimer-related cognitive impairment in adults with Down syndrome.

Authors: Alberto Lleó; Maria Carmona-Iragui; Laura Videla; Susana Fernández; Bessy Benejam; Jordi Pegueroles; Isabel Barroeta; Miren Altuna; Silvia Valldeneu; Mei-Fang Xiao; Desheng Xu; Raúl Núñez-Llaves; Marta Querol-Vilaseca; Sònia Sirisi; Alexandre Bejanin; M Florencia Iulita; Jordi Clarimón; Rafael Blesa; Paul Worley; Daniel Alcolea; Juan Fortea; Olivia Belbin
Journal: Alzheimers Res Ther Date: 2021-06-28 Impact factor: 6.982