AbstractBackgroundClinical diagnosis of Alzheimer’s disease (AD) increasingly incorporate CSF biomarkers. However due to the intrinsic variability of the immunodetection techniques used to measure these biomarkers, it is recommended to establish in‐house cutoffs defining the positivity/negativity of CSF biomarkers.MethodWe quantified CSF Aβ1‐42, t‐Tau, p181Tau and Aβ1‐40 with standard INNOTEST® ELISA and Lumipulse G® chemiluminescence enzyme‐immunoassay (CLEIA) performed on automated Lumipulse G600II. Determination of cutoffs included patients clinically diagnosed with Alzheimer Disease (AD, n=37) and amyloid‐negative Subjective Cognitive Decline subjects (SCD, n=45), cognitively stable during 3‐years and with no evidence of brain amyloidosis in ¹⁸F‐Florbetaben‐labeled positron emission tomography (FBB‐PET). To compare both methods, a subset of samples for Aβ1‐42 (n=519), t‐Tau (n=399), p181Tau (n=77) and Aβ1‐40 (n=44) were analyzed. Kappa agreement of single biomarkers and Aβ1‐42/Aβ1‐40 was performed in an independent group of mild cognitive impairment (MCI) and dementia patients (n=68).ResultCutoffs values of Aβ1‐42 and t‐Tau were higher for CLEIA than for ELISA and similar for p181Tau. Spearman coefficients ranged between 0.81 for Aβ1‐40 and 0.96 for p181TAU. Passing‐Bablok analysis showed a systematic and proportional difference for all biomarkers but only systematic for Aβ1‐40. Bland‐Altman analysis showed an average difference between methods in favor of CLEIA. Kappa agreement for single biomarkers were good but lower for Aβ1‐42/Aβ1‐40.ConclusionWe established internal cutoffs to discriminate AD patients from amyloid‐negative SCD individuals. Results obtained by both methods are not interchangeable but showed good agreement. We propose automated CLEIA as a good alternative to manual ELISA together with Aβ1‐42/Aβ1‐40 to classify amyloidosis.