Abstract
BackgroundLongitudinal gene expression analysis and survival modeling have been proved to add valuable biological and clinical knowledge. This study proposes a novel framework to discover gene signatures and patterns in a high-dimensional time series transcriptomics data and to assess their association with hospital length of stay.MethodsWe investigated a longitudinal and high-dimensional gene expression dataset from 168 blunt-force trauma patients followed during the first 28 days after injury. To model the length of stay, an initial dimensionality reduction step was performed by applying Cox regression with elastic net regularization using gene expression data from the first hospitalization days. Also, a novel methodology to impute missing values to the genes selected previously was proposed. We then applied multivariate time series (MTS) clustering to analyse gene expression over time and to stratify patients with similar trajectories. The validation of the patients’ partitions obtained by MTS clustering was performed using Kaplan-Meier curves and log-rank tests.ResultsWe were able to unravel 22 genes strongly associated with hospital’s discharge. Their expression values in the first days after trauma showed to be good predictors of the length of stay. The proposed mixed imputation method allowed to achieve a complete dataset of short time series with a minimum loss of information for the 28 days of follow-up. MTS clustering enabled to group patients with similar genes trajectories and, notably, with similar discharge days from the hospital. Patients within each cluster have comparable genes’ trajectories and may have an analogous response to injury.ConclusionThe proposed framework was able to tackle the joint analysis of time-to-event information with longitudinal multivariate high-dimensional data. The application to length of stay and transcriptomics data revealed a strong relationship between gene expression trajectory and patients’ recovery, which may improve trauma patient’s management by healthcare systems. The proposed methodology can be easily adapted to other medical data, towards more effective clinical decision support systems for health applications.
Highlights
Temporal data has been frequently used in medical research to follow disease progression over a few time points or prolonged periods
The methods used for missing data imputation and for multivariate time series clustering are explained
Identification of relevant genes To unravel the most relevant genes in trauma patients to predict the discharge hospital day since the injury, an analysis of the gene expression was performed for the first days after injury, taken independently
Summary
Temporal data has been frequently used in medical research to follow disease progression over a few time points or prolonged periods. Timeseries gene expression data have shown to be important in discovering complex biological interactions and clinical mechanisms [3]. The number of genetic markers measured in these types of studies, which has ranged from thousands of genes to millions of genetic variants, leads to significant computational challenges, specially when analysing temporal omics data. In high-dimensional omics data, the number of variables (genes) measured in these experiments is usually much higher than the sample size (number of subjects included in the study). Identifying accurate and relevant biomarkers in a high-dimensional data set has become one of the key challenges today for the advance of precision medicine. This study proposes a novel framework to discover gene signatures and patterns in a high-dimensional time series transcriptomics data and to assess their association with hospital length of stay
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