Machine learning prediction of combat basic training injury from 3D body shape images

Introduction Athletes and military personnel are both at risk of disabling injuries due to extreme physical activity. A method to predict which individuals might be more susceptible to injury would be valuable, especially in the military where basic recruits may be discharged from service due to injury. We postulate that certain body characteristics may be used to predict risk of injury with physical activity. Methods US Army basic training recruits between the ages of 17 and 21 (N = 17,680, 28% female) were scanned for uniform fitting using the 3D body imaging scanner, Human Solutions of North America at Fort Jackson, SC. From the 3D body imaging scans, a database consisting of 161 anthropometric measurements per basic training recruit was used to predict the probability of discharge from the US Army due to injury. Predictions were made using logistic regression, random forest, and artificial neural network (ANN) models. Model comparison was done using the area under the curve (AUC) of a ROC curve. Results The ANN model outperformed two other models, (ANN, AUC = 0.70, [0.68,0.72], logistic regression AUC = 0.67, [0.62,0.72], random forest AUC = 0.65, [0.61,0.70]). Conclusions Body shape profiles generated from a three-dimensional body scanning imaging in military personnel predicted dischargeable physical injury. The ANN model can be programmed into the scanner to deliver instantaneous predictions of risk, which may provide an opportunity to intervene to prevent injury.

[1]  Joseph J. Knapik,et al.  Stress Fracture Risk Factors in Basic Combat Training , 2012, International Journal of Sports Medicine.

[2]  Joseph J Knapik,et al.  Seasonal variations in injury rates during US Army Basic Combat Training. , 2002, The Annals of occupational hygiene.

[3]  Joseph J. Knapik,et al.  Injury Incidence, Injury Risk Factors, and Physical Fitness of U.S. Army Basic Trainees at Ft. Jackson, South Carolina , 1998 .

[4]  B. Jones,et al.  Impact of physical fitness and body composition on injury risk among active young adults: A study of Army trainees. , 2017, Journal of science and medicine in sport.

[5]  J. Knapik,et al.  A multiple intervention strategy for reducing femoral neck stress injuries and other serious overuse injuries in U.S. Army Basic Combat Training. , 2012, Military medicine.

[6]  M. Posner,et al.  Bone Stress Injuries in the Military: Diagnosis, Management, and Prevention. , 2017, American journal of orthopedics.

[7]  R. Wilder,et al.  Overuse injuries: tendinopathies, stress fractures, compartment syndrome, and shin splints. , 2004, Clinics in sports medicine.

[8]  Peter Ahnert,et al.  Novel Anthropometry Based on 3D-Bodyscans Applied to a Large Population Based Cohort , 2016, PloS one.

[9]  Eduardo Rivo,et al.  Cross-Industry Standard Process for data mining is applicable to the lung cancer surgery domain, improving decision making as well as knowledge and quality management , 2012, Clinical and Translational Oncology.

[10]  J. Knapik,et al.  Stress Fractures: Etiology, Epidemiology, Diagnosis, Treatment, and Prevention. , 2018, Journal of special operations medicine : a peer reviewed journal for SOF medical professionals.

[11]  Maciej Henneberg,et al.  Comparison of 3D laser-based photonic scans and manual anthropometric measurements of body size and shape in a validation study of 123 young Swiss men , 2017, PeerJ.

[12]  D M Thomas,et al.  A review of machine learning in obesity , 2018, Obesity reviews : an official journal of the International Association for the Study of Obesity.

[13]  M A Sharp,et al.  Risk factors for training-related injuries among men and women in basic combat training. , 2001, Medicine and science in sports and exercise.

[14]  J. Knapik,et al.  Discharges during U.S. Army basic training: injury rates and risk factors. , 2001, Military medicine.

[15]  Joseph J. Knapik,et al.  Exercise, Training and Injuries , 1994, Sports medicine.

[16]  J. Knapik,et al.  Outcomes of Fort Jackson's Physical Training and Rehabilitation Program in army basic combat training: return to training, graduation, and 2-year retention. , 2004, Military medicine.

[17]  Markus Scholz,et al.  Reliability of 3D laser-based anthropometry and comparison with classical anthropometry , 2016, Scientific Reports.

[18]  Kelly W. Williams,et al.  Risk factors for medical discharge from United States Army Basic Combat Training. , 2011, Military medicine.

[19]  Radford M. Neal Pattern Recognition and Machine Learning , 2007, Technometrics.

[20]  William F. Scully,et al.  Femoral Neck Stress Injuries: Analysis of 156 Cases in a U.S. Military Population and Proposal of a New MRI Classification System. , 2018, AJR. American journal of roentgenology.

[21]  A. Nevill,et al.  Fitness, performance, and risk of injury in British Army officer cadets. , 1999, Military medicine.

[22]  Bernadette M. Marriott,et al.  Body Composition and Physical Performance: Applications For the Military Services , 1992 .

[23]  Joseph J Knapik Tools to Assess and Reduce Injury Risk (Part 1). , 2017, Journal of special operations medicine : a peer reviewed journal for SOF medical professionals.

[24]  S B Heymsfield,et al.  Automated anthropometric phenotyping with novel Kinect-based three-dimensional imaging method: comparison with a reference laser imaging system , 2016, European Journal of Clinical Nutrition.

[25]  K. Reynolds,et al.  Injuries associated with strenuous road marching. , 1992, Military medicine.