Longitudinally monitored immune biomarkers predict the timing of COVID-19 outcomes

Gorka Lasso; Saad Khan; Stephanie A. Allen; Margarette Mariano; Catalina Florez; Erika P. Orner; Jose A. Quiroz; Gregory Quevedo; Aldo Massimi; Aditi Hegde; Ariel S. Wirchnianski; Robert H. Bortz; Ryan J. Malonis; George I. Georgiev; Karen Tong; Natalia G. Herrera; Nicholas C. Morano; Scott J. Garforth; Avinash Malaviya; Ahmed Khokhar; Ethan Laudermilch; M. Eugenia Dieterle; J. Maximilian Fels; Denise Haslwanter; Rohit K. Jangra; Jason Barnhill; Steven C. Almo; Kartik Chandran; Jonathan R. Lai; Libusha Kelly; Johanna P. Daily; Olivia Vergnolle

doi:10.1371/journal.pcbi.1009778

Longitudinally monitored immune biomarkers predict the timing of COVID-19 outcomes

Gorka Lasso, Saad Khan, Stephanie A. Allen, Margarette Mariano, Catalina Florez, Erika P. Orner, Jose A. Quiroz, Gregory Quevedo, Aldo Massimi, Aditi Hegde, Ariel S. Wirchnianski, Robert H. Bortz, Ryan J. Malonis, George I. Georgiev, Karen Tong, Natalia G. Herrera, Nicholas C. Morano, Scott J. Garforth, Avinash Malaviya, Ahmed KhokharEthan Laudermilch, M. Eugenia Dieterle, J. Maximilian Fels, Denise Haslwanter, Rohit K. Jangra, Jason Barnhill, Steven C. Almo, Kartik Chandran, Jonathan R. Lai, Libusha Kelly, Johanna P. Daily, Olivia Vergnolle

Research output: Contribution to journal › Article › peer-review

11 Scopus citations

Abstract

The clinical outcome of SARS-CoV-2 infection varies widely between individuals. Machine learning models can support decision making in healthcare by assessing fatality risk in patients that do not yet show severe signs of COVID-19. Most predictive models rely on static demographic features and clinical values obtained upon hospitalization. However, time-dependent biomarkers associated with COVID-19 severity, such as antibody titers, can substantially contribute to the development of more accurate outcome models. Here we show that models trained on immune biomarkers, longitudinally monitored throughout hospitalization, predicted mortality and were more accurate than models based on demographic and clinical data upon hospital admission. Our best-performing predictive models were based on the temporal analysis of anti-SARS-CoV-2 Spike IgG titers, white blood cell (WBC), neutrophil and lymphocyte counts. These biomarkers, together with C-reactive protein and blood urea nitrogen levels, were found to correlate with severity of disease and mortality in a time-dependent manner. Shapley additive explanations of our model revealed the higher predictive value of day post-symptom onset (PSO) as hospitalization progresses and showed how immune biomarkers contribute to predict mortality. In sum, we demonstrate that the kinetics of immune biomarkers can inform clinical models to serve as a powerful monitoring tool for predicting fatality risk in hospitalized COVID-19 patients, underscoring the importance of contextualizing clinical parameters according to their time post-symptom onset.

Original language	English (US)
Article number	e1009778
Journal	PLoS Computational Biology
Volume	18
Issue number	1
DOIs	https://doi.org/10.1371/journal.pcbi.1009778
State	Published - Jan 2022

ASJC Scopus subject areas

Ecology, Evolution, Behavior and Systematics
Modeling and Simulation
Ecology
Molecular Biology
Genetics
Cellular and Molecular Neuroscience
Computational Theory and Mathematics

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10.1371/journal.pcbi.1009778

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Lasso, G., Khan, S., Allen, S. A., Mariano, M., Florez, C., Orner, E. P., Quiroz, J. A., Quevedo, G., Massimi, A., Hegde, A., Wirchnianski, A. S., Bortz, R. H., Malonis, R. J., Georgiev, G. I., Tong, K., Herrera, N. G., Morano, N. C., Garforth, S. J., Malaviya, A., ... Vergnolle, O. (2022). Longitudinally monitored immune biomarkers predict the timing of COVID-19 outcomes. PLoS Computational Biology, 18(1), Article e1009778. https://doi.org/10.1371/journal.pcbi.1009778

Lasso, G, Khan, S, Allen, SA, Mariano, M, Florez, C, Orner, EP, Quiroz, JA, Quevedo, G, Massimi, A, Hegde, A, Wirchnianski, AS, Bortz, RH, Malonis, RJ, Georgiev, GI, Tong, K, Herrera, NG, Morano, NC, Garforth, SJ, Malaviya, A, Khokhar, A, Laudermilch, E, Dieterle, ME, Fels, JM, Haslwanter, D, Jangra, RK, Barnhill, J, Almo, SC , Chandran, K , Lai, JR , Kelly, L , Daily, JP & Vergnolle, O 2022, 'Longitudinally monitored immune biomarkers predict the timing of COVID-19 outcomes', PLoS Computational Biology, vol. 18, no. 1, e1009778. https://doi.org/10.1371/journal.pcbi.1009778

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title = "Longitudinally monitored immune biomarkers predict the timing of COVID-19 outcomes",

abstract = "The clinical outcome of SARS-CoV-2 infection varies widely between individuals. Machine learning models can support decision making in healthcare by assessing fatality risk in patients that do not yet show severe signs of COVID-19. Most predictive models rely on static demographic features and clinical values obtained upon hospitalization. However, time-dependent biomarkers associated with COVID-19 severity, such as antibody titers, can substantially contribute to the development of more accurate outcome models. Here we show that models trained on immune biomarkers, longitudinally monitored throughout hospitalization, predicted mortality and were more accurate than models based on demographic and clinical data upon hospital admission. Our best-performing predictive models were based on the temporal analysis of anti-SARS-CoV-2 Spike IgG titers, white blood cell (WBC), neutrophil and lymphocyte counts. These biomarkers, together with C-reactive protein and blood urea nitrogen levels, were found to correlate with severity of disease and mortality in a time-dependent manner. Shapley additive explanations of our model revealed the higher predictive value of day post-symptom onset (PSO) as hospitalization progresses and showed how immune biomarkers contribute to predict mortality. In sum, we demonstrate that the kinetics of immune biomarkers can inform clinical models to serve as a powerful monitoring tool for predicting fatality risk in hospitalized COVID-19 patients, underscoring the importance of contextualizing clinical parameters according to their time post-symptom onset.",

author = "Gorka Lasso and Saad Khan and Allen, {Stephanie A.} and Margarette Mariano and Catalina Florez and Orner, {Erika P.} and Quiroz, {Jose A.} and Gregory Quevedo and Aldo Massimi and Aditi Hegde and Wirchnianski, {Ariel S.} and Bortz, {Robert H.} and Malonis, {Ryan J.} and Georgiev, {George I.} and Karen Tong and Herrera, {Natalia G.} and Morano, {Nicholas C.} and Garforth, {Scott J.} and Avinash Malaviya and Ahmed Khokhar and Ethan Laudermilch and Dieterle, {M. Eugenia} and Fels, {J. Maximilian} and Denise Haslwanter and Jangra, {Rohit K.} and Jason Barnhill and Almo, {Steven C.} and Kartik Chandran and Lai, {Jonathan R.} and Libusha Kelly and Daily, {Johanna P.} and Olivia Vergnolle",

note = "Publisher Copyright: {\textcopyright} 2022 This is an open access article, free of all copyright, and may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose. The work is made available under the Creative Commons CC0 public domain dedication.",

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doi = "10.1371/journal.pcbi.1009778",

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T1 - Longitudinally monitored immune biomarkers predict the timing of COVID-19 outcomes

AU - Lasso, Gorka

AU - Khan, Saad

AU - Allen, Stephanie A.

AU - Mariano, Margarette

AU - Florez, Catalina

AU - Orner, Erika P.

AU - Quiroz, Jose A.

AU - Quevedo, Gregory

AU - Massimi, Aldo

AU - Hegde, Aditi

AU - Wirchnianski, Ariel S.

AU - Bortz, Robert H.

AU - Malonis, Ryan J.

AU - Georgiev, George I.

AU - Tong, Karen

AU - Herrera, Natalia G.

AU - Morano, Nicholas C.

AU - Garforth, Scott J.

AU - Malaviya, Avinash

AU - Khokhar, Ahmed

AU - Laudermilch, Ethan

AU - Dieterle, M. Eugenia

AU - Fels, J. Maximilian

AU - Haslwanter, Denise

AU - Jangra, Rohit K.

AU - Barnhill, Jason

AU - Almo, Steven C.

AU - Chandran, Kartik

AU - Lai, Jonathan R.

AU - Kelly, Libusha

AU - Daily, Johanna P.

AU - Vergnolle, Olivia

N1 - Publisher Copyright: © 2022 This is an open access article, free of all copyright, and may be freely reproduced, distributed, transmitted, modified, built upon, or otherwise used by anyone for any lawful purpose. The work is made available under the Creative Commons CC0 public domain dedication.

PY - 2022/1

Y1 - 2022/1

N2 - The clinical outcome of SARS-CoV-2 infection varies widely between individuals. Machine learning models can support decision making in healthcare by assessing fatality risk in patients that do not yet show severe signs of COVID-19. Most predictive models rely on static demographic features and clinical values obtained upon hospitalization. However, time-dependent biomarkers associated with COVID-19 severity, such as antibody titers, can substantially contribute to the development of more accurate outcome models. Here we show that models trained on immune biomarkers, longitudinally monitored throughout hospitalization, predicted mortality and were more accurate than models based on demographic and clinical data upon hospital admission. Our best-performing predictive models were based on the temporal analysis of anti-SARS-CoV-2 Spike IgG titers, white blood cell (WBC), neutrophil and lymphocyte counts. These biomarkers, together with C-reactive protein and blood urea nitrogen levels, were found to correlate with severity of disease and mortality in a time-dependent manner. Shapley additive explanations of our model revealed the higher predictive value of day post-symptom onset (PSO) as hospitalization progresses and showed how immune biomarkers contribute to predict mortality. In sum, we demonstrate that the kinetics of immune biomarkers can inform clinical models to serve as a powerful monitoring tool for predicting fatality risk in hospitalized COVID-19 patients, underscoring the importance of contextualizing clinical parameters according to their time post-symptom onset.

AB - The clinical outcome of SARS-CoV-2 infection varies widely between individuals. Machine learning models can support decision making in healthcare by assessing fatality risk in patients that do not yet show severe signs of COVID-19. Most predictive models rely on static demographic features and clinical values obtained upon hospitalization. However, time-dependent biomarkers associated with COVID-19 severity, such as antibody titers, can substantially contribute to the development of more accurate outcome models. Here we show that models trained on immune biomarkers, longitudinally monitored throughout hospitalization, predicted mortality and were more accurate than models based on demographic and clinical data upon hospital admission. Our best-performing predictive models were based on the temporal analysis of anti-SARS-CoV-2 Spike IgG titers, white blood cell (WBC), neutrophil and lymphocyte counts. These biomarkers, together with C-reactive protein and blood urea nitrogen levels, were found to correlate with severity of disease and mortality in a time-dependent manner. Shapley additive explanations of our model revealed the higher predictive value of day post-symptom onset (PSO) as hospitalization progresses and showed how immune biomarkers contribute to predict mortality. In sum, we demonstrate that the kinetics of immune biomarkers can inform clinical models to serve as a powerful monitoring tool for predicting fatality risk in hospitalized COVID-19 patients, underscoring the importance of contextualizing clinical parameters according to their time post-symptom onset.

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Longitudinally monitored immune biomarkers predict the timing of COVID-19 outcomes

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