XGBoost, a Machine Learning Method, Predicts Neurological Recovery in Patients with Cervical Spinal Cord Injury

The accurate prediction of neurological outcomes in patients with cervical spinal cord injury (SCI) is difficult because of heterogeneity in patient characteristics, treatment strategies, and radiographic findings. Although machine learning algorithms may increase the accuracy of outcome predictions in various fields, limited information is available on their efficacy in the management of SCI. We analyzed data from 165 patients with cervical SCI, and extracted important factors for predicting prognoses. Extreme gradient boosting (XGBoost) as a machine learning model was applied to assess the reliability of a machine learning algorithm to predict neurological outcomes compared with that of conventional methodology, such as a logistic regression or decision tree. We used regularly obtainable data as predictors, such as demographics, magnetic resonance variables, and treatment strategies. Predictive tools, including XGBoost, a logistic regression, and a decision tree, were applied to predict neurological improvements in the functional motor status (ASIA [American Spinal Injury Association] Impairment Scale [AIS] D and E) 6 months after injury. We evaluated predictive performance, including accuracy and the area under the receiver operating characteristic curve (AUC). Regarding predictions of neurological improvements in patients with cervical SCI, XGBoost had the highest accuracy (81.1%), followed by the logistic regression (80.6%) and the decision tree (78.8%). Regarding AUC, the logistic regression showed 0.877, followed by XGBoost (0.867) and the decision tree (0.753). XGBoost reliably predicted neurological alterations in patients with cervical SCI. The utilization of predictive machine learning algorithms may enhance personalized management choices through pre-treatment categorization of patients.

[1]  Qing-Guo Wang,et al.  XGBoost Model for Chronic Kidney Disease Diagnosis , 2020, IEEE/ACM Transactions on Computational Biology and Bioinformatics.

[2]  Novruz Allahverdi,et al.  Deep Learning on Computerized Analysis of Chronic Obstructive Pulmonary Disease , 2020, IEEE Journal of Biomedical and Health Informatics.

[3]  T. Wong,et al.  Logistic regression was as good as machine learning for predicting major chronic diseases. , 2020, Journal of clinical epidemiology.

[4]  C. Rivers,et al.  Development of an unsupervised machine learning algorithm for the prognostication of walking ability in spinal cord injury patients. , 2020, The spine journal : official journal of the North American Spine Society.

[5]  J. Mac-Thiong,et al.  The use of classification and regression tree analysis to identify the optimal surgical timing for improving neurological outcomes following motor-complete thoracolumbar traumatic spinal cord injury , 2020, Spinal Cord.

[6]  Jefferson R. Wilson,et al.  Early Surgery for Traumatic Spinal Cord Injury: Where Are We Now? , 2020, Global spine journal.

[7]  Eiji Kohmura,et al.  Machine Learning to Predict In-hospital Morbidity and Mortality after Traumatic Brain Injury. , 2020, Journal of neurotrauma.

[8]  Fan Jiang,et al.  Predictive Modeling of Outcomes After Traumatic and Nontraumatic Spinal Cord Injury Using Machine Learning: Review of Current Progress and Future Directions , 2019, Neurospine.

[9]  Samuel K. Cho,et al.  Applications of Machine Learning Using Electronic Medical Records in Spine Surgery , 2019, Neurospine.

[10]  Huiying Liang,et al.  Early and Accurate Prediction of Clinical Response to Methotrexate Treatment in Juvenile Idiopathic Arthritis Using Machine Learning , 2019, Front. Pharmacol..

[11]  C. Rivers,et al.  Highlighting discrepancies in walking prediction accuracy for patients with traumatic spinal cord injury: an evaluation of validated prediction models using a Canadian Multicenter Spinal Cord Injury Registry. , 2019, The spine journal : official journal of the North American Spine Society.

[12]  Adam R Ferguson,et al.  Convolutional Neural Network–Based Automated Segmentation of the Spinal Cord and Contusion Injury: Deep Learning Biomarker Correlates of Motor Impairment in Acute Spinal Cord Injury , 2019, American Journal of Neuroradiology.

[13]  Hazem Elzarka,et al.  Early detection of faults in HVAC systems using an XGBoost model with a dynamic threshold , 2019, Energy and Buildings.

[14]  Tadahiro Goto,et al.  Machine Learning–Based Prediction of Clinical Outcomes for Children During Emergency Department Triage , 2019, JAMA network open.

[15]  Yi Pan,et al.  An interpretable boosting model to predict side effects of analgesics for osteoarthritis , 2018, BMC Systems Biology.

[16]  Yu Wang,et al.  Intersection Traffic Prediction Using Decision Tree Models , 2018, Symmetry.

[17]  Tadahiro Goto,et al.  Machine learning approaches for predicting disposition of asthma and COPD exacerbations in the ED , 2018, The American journal of emergency medicine.

[18]  Shivayogi V. Hiremath,et al.  Longitudinal Prediction of Quality-of-Life Scores and Locomotion in Individuals With Traumatic Spinal Cord Injury. , 2017, Archives of physical medicine and rehabilitation.

[19]  Ben Wellner,et al.  Predicting Unplanned Transfers to the Intensive Care Unit: A Machine Learning Approach Leveraging Diverse Clinical Elements , 2017, JMIR medical informatics.

[20]  T. Roberts,et al.  Classifications In Brief: American Spinal Injury Association (ASIA) Impairment Scale , 2017, Clinical orthopaedics and related research.

[21]  Marcela Perrone-Bertolotti,et al.  Machine learning–XGBoost analysis of language networks to classify patients with epilepsy , 2017, Brain Informatics.

[22]  J. Simard,et al.  Intramedullary Lesion Length on Postoperative Magnetic Resonance Imaging is a Strong Predictor of ASIA Impairment Scale Grade Conversion Following Decompressive Surgery in Cervical Spinal Cord Injury , 2017, Neurosurgery.

[23]  Adam R Ferguson,et al.  Multivariate Analysis of MRI Biomarkers for Predicting Neurologic Impairment in Cervical Spinal Cord Injury , 2016, American Journal of Neuroradiology.

[24]  S. Negahban,et al.  Analysis of Machine Learning Techniques for Heart Failure Readmissions , 2016, Circulation. Cardiovascular quality and outcomes.

[25]  Tianqi Chen,et al.  XGBoost: A Scalable Tree Boosting System , 2016, KDD.

[26]  Jiaming Liu,et al.  Is Urgent Decompression Superior to Delayed Surgery for Traumatic Spinal Cord Injury? A Meta-Analysis. , 2016, World neurosurgery.

[27]  William Fleischman,et al.  Prediction of In-hospital Mortality in Emergency Department Patients With Sepsis: A Local Big Data-Driven, Machine Learning Approach. , 2016, Academic emergency medicine : official journal of the Society for Academic Emergency Medicine.

[28]  Rahul C. Deo,et al.  Machine Learning in Medicine , 2015, Mach. Learn. under Resour. Constraints Vol. 3.

[29]  F. Bajrović,et al.  Neurological Recovery after Traumatic Cervical Spinal Cord Injury Is Superior if Surgical Decompression and Instrumented Fusion Are Performed within 8 Hours versus 8 to 24 Hours after Injury: A Single Center Experience. , 2015, Journal of neurotrauma.

[30]  Adam R Ferguson,et al.  The Brain and Spinal Injury Center score: a novel, simple, and reproducible method for assessing the severity of acute cervical spinal cord injury with axial T2-weighted MRI findings. , 2015, Journal of neurosurgery. Spine.

[31]  Michael Y. Wang,et al.  Acute diagnostic biomarkers for spinal cord injury: review of the literature and preliminary research report. , 2015, World neurosurgery.

[32]  M. Bala,et al.  Evaluation of Traumatic Spine by Magnetic Resonance Imaging and Correlation with Neurological Recovery , 2015, Asian spine journal.

[33]  J. Steeves,et al.  Common data elements for spinal cord injury clinical research: a National Institute for Neurological Disorders and Stroke project , 2015, Spinal Cord.

[34]  H. Baba,et al.  Prognostic value of changes in spinal cord signal intensity on magnetic resonance imaging in patients with cervical compressive myelopathy. , 2014, The spine journal : official journal of the North American Spine Society.

[35]  G. Manley,et al.  Medical and surgical management after spinal cord injury: vasopressor usage, early surgerys, and complications. , 2014, Journal of neurotrauma.

[36]  Sejong Oh,et al.  A Machine Learning Approach for Specification of Spinal Cord Injuries Using Fractional Anisotropy Values Obtained from Diffusion Tensor Images , 2014, Comput. Math. Methods Medicine.

[37]  M. Fehlings,et al.  Incidence and Prevalence of Spinal Cord Injury in Canada: A National Perspective , 2012, Neuroepidemiology.

[38]  Michael Schuetz,et al.  Diagnosis and Prognosis of Traumatic Spinal Cord Injury , 2011, Global spine journal.

[39]  D. Cadotte,et al.  Timing of decompressive surgery of spinal cord after traumatic spinal cord injury: an evidence-based examination of pre-clinical and clinical studies. , 2011, Journal of neurotrauma.

[40]  J. Marcoux,et al.  The role of magnetic resonance imaging in the management of acute spinal cord injury. , 2011, Journal of neurotrauma.

[41]  J. Steeves,et al.  Outcome measures in spinal cord injury: recent assessments and recommendations for future directions , 2009, Spinal Cord.

[42]  Joseph Finkelstein,et al.  Using machine learning to predict asthma exacerbations. , 2007, AMIA ... Annual Symposium proceedings. AMIA Symposium.

[43]  R. Tibshirani,et al.  The Elements of Statistical Learning: Data Mining, Inference, and Prediction , 2004 .

[44]  Eric R. Ziegel,et al.  The Elements of Statistical Learning , 2003, Technometrics.

[45]  Y. Takakura,et al.  Sagittal Alignment of Cervical Flexion and Extension: Lateral Radiographic Analysis , 2002, Spine.

[46]  H. White,et al.  Logistic regression in the medical literature: standards for use and reporting, with particular attention to one medical domain. , 2001, Journal of clinical epidemiology.

[47]  E. Benzel,et al.  The optimal radiologic method for assessing spinal canal compromise and cord compression in patients with cervical spinal cord injury. Part II: Results of a multicenter study. , 1999, Spine.

[48]  R. Deyo,et al.  Adapting a clinical comorbidity index for use with ICD-9-CM administrative databases. , 1992, Journal of clinical epidemiology.

[49]  M. Kulkarni,et al.  Acute Spinal Cord Injury: A Study Using Physical Examination and Magnetic Resonance Imaging , 1990 .

[50]  T. Ryken,et al.  Guidelines for the management of acute cervical spine and spinal cord injuries. , 2002, Clinical neurosurgery.

[51]  C. Mackenzie,et al.  A new method of classifying prognostic comorbidity in longitudinal studies: development and validation. , 1987, Journal of chronic diseases.