PROJECT SUMMARY/ABSTRACT Alzheimer's disease (AD) represents an emerging global health threat and is a expected to double in prevalence by 2050. AD is a disease of malformed proteins, and significant progress has been made characterizing the AD proteome with mass spectrometery. However, data missingness represents a significant barrier to the interpretation of existing AD mass spectrometry experiments. Missingness refers to peptides or proteins that are present in the biological sample but are not detected by the mass spectrometer due to various technical factors. This project will address missingness by developing machine learning methods for imputing, or estimating, missing values in quantitative mass spectrometry data. The project will develop two separate imputation methods, one using non-negative matrix factorization and the other deep neural networks. These imputation methods will increase the reproducibility and statistical power of mass spectrometry experiments and will enable new discoveries in existing proteomics experiments. These imputation methods will be applicable to virtually any kind of mass spectrometry experiment – tandem mass tag, data dependent acquisition, data independent acquisition, spectral counts, label-free quantification, etc. These imputation methods will be released as lightweight, open-source and easy-to-use software packages and may be incorporated into existing data processing workflows. I will demonstrate the utility of these imputation methods by reanalysing data from several existing AD proteomic studies. My imputation methods will identify novel differentially expressed proteins, co-expression modules and AD biomarkers in these existing datasets. I will also analyze unpublished data-independent acquisition (DIA) proteomics data derived from AD patient cerebrospinal fluid samples. Here I will focus on identifying biomarkers that differentiate between patients based on genetic background and co-morbidity status. I will also identify biomarkers of patients with asymptomatic AD. The imputation methods developed by this proposal will enable future discoveries by independent AD researchers. This proposal aligns with the NIA Strategic Direction seeking to "identify and understand the genetic, molecular and cellular mechanisms underlying the pathogenesis of AD."