Data-driven distillation and precision prognosis in traumatic brain injury with interpretable machine learning

Andrew Tritt; John K. Yue; Adam R. Ferguson; Abel Torres Espin; Lindsay D. Nelson; Esther L. Yuh; Amy J. Markowitz; Geoffrey T. Manley; Kristofer E. Bouchard; C. Dirk Keene; Christopher Madden; Michael McCrea; Randall Merchant; Pratik Mukherjee; Laura B. Ngwenya; Claudia Robertson; David Schnyer; Sabrina R. Taylor; Ross Zafonte

doi:10.1038/s41598-023-48054-z

Data-driven distillation and precision prognosis in traumatic brain injury with interpretable machine learning

Andrew Tritt, John K. Yue, Adam R. Ferguson, Abel Torres Espin, Lindsay D. Nelson, Esther L. Yuh, Amy J. Markowitz, Geoffrey T. Manley, Kristofer E. Bouchard, C. Dirk Keene, Christopher Madden, Michael McCrea, Randall Merchant, Pratik Mukherjee, Laura B. Ngwenya, Claudia Robertson, David Schnyer, Sabrina R. Taylor, Ross Zafonte

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

Abstract

Traumatic brain injury (TBI) affects how the brain functions in the short and long term. Resulting patient outcomes across physical, cognitive, and psychological domains are complex and often difficult to predict. Major challenges to developing personalized treatment for TBI include distilling large quantities of complex data and increasing the precision with which patient outcome prediction (prognoses) can be rendered. We developed and applied interpretable machine learning methods to TBI patient data. We show that complex data describing TBI patients' intake characteristics and outcome phenotypes can be distilled to smaller sets of clinically interpretable latent factors. We demonstrate that 19 clusters of TBI outcomes can be predicted from intake data, a ~ 6× improvement in precision over clinical standards. Finally, we show that 36% of the outcome variance across patients can be predicted. These results demonstrate the importance of interpretable machine learning applied to deeply characterized patients for data-driven distillation and precision prognosis.

Original language	English (US)
Article number	21200
Journal	Scientific reports
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41598-023-48054-z
State	Published - Dec 2023

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Tritt, A., Yue, J. K., Ferguson, A. R., Torres Espin, A., Nelson, L. D., Yuh, E. L., Markowitz, A. J., Manley, G. T., Bouchard, K. E., Keene, C. D., Madden, C., McCrea, M., Merchant, R., Mukherjee, P., Ngwenya, L. B., Robertson, C., Schnyer, D., Taylor, S. R., & Zafonte, R. (2023). Data-driven distillation and precision prognosis in traumatic brain injury with interpretable machine learning. Scientific reports, 13(1), Article 21200. https://doi.org/10.1038/s41598-023-48054-z

Tritt, A, Yue, JK, Ferguson, AR, Torres Espin, A, Nelson, LD, Yuh, EL, Markowitz, AJ, Manley, GT, Bouchard, KE, Keene, CD, Madden, C, McCrea, M, Merchant, R, Mukherjee, P, Ngwenya, LB, Robertson, C, Schnyer, D, Taylor, SR & Zafonte, R 2023, 'Data-driven distillation and precision prognosis in traumatic brain injury with interpretable machine learning', Scientific reports, vol. 13, no. 1, 21200. https://doi.org/10.1038/s41598-023-48054-z

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abstract = "Traumatic brain injury (TBI) affects how the brain functions in the short and long term. Resulting patient outcomes across physical, cognitive, and psychological domains are complex and often difficult to predict. Major challenges to developing personalized treatment for TBI include distilling large quantities of complex data and increasing the precision with which patient outcome prediction (prognoses) can be rendered. We developed and applied interpretable machine learning methods to TBI patient data. We show that complex data describing TBI patients' intake characteristics and outcome phenotypes can be distilled to smaller sets of clinically interpretable latent factors. We demonstrate that 19 clusters of TBI outcomes can be predicted from intake data, a ~ 6× improvement in precision over clinical standards. Finally, we show that 36% of the outcome variance across patients can be predicted. These results demonstrate the importance of interpretable machine learning applied to deeply characterized patients for data-driven distillation and precision prognosis.",

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AU - Madden, Christopher

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AU - Merchant, Randall

AU - Mukherjee, Pratik

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Data-driven distillation and precision prognosis in traumatic brain injury with interpretable machine learning

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