Not just a rural occurrence: differences in agricultural equipment crash characteristics by rural-urban crash site and proximity to town.

PURPOSE Although approximately one-third of agricultural equipment-related crashes occur near town, these crashes are thought to be a rural problem. This analysis examines differences between agricultural equipment-related crashes by their urban-rural distribution and distance from a town. METHODS Agricultural equipment crashes were collected from nine Midwest Departments of Transportation (2005-2008). Crash zip code was assigned as urban or rural (large, small and isolated) using Rural-Urban Commuting Areas. Crash proximity to a town was estimated with ArcGIS. Multivariable logistic regression was used to estimate the odds of crashing in an urban versus rural zip codes and across rural gradients. ANOVA analysis estimated mean distance (miles) from a crash site to a town. FINDINGS Over four years, 4444 crashes involved agricultural equipment. About 30% of crashes occurred in urban zip codes. Urban crashes were more likely to be non-collisions (aOR=1.69[1.24-2.30]), involve ≥2 vehicles (2 vehicles: aOR=1.58[1.14-2.20], 3+ vehicles: aOR=1.68[0.98-2.88]), occur in a town (aOR=2.06[1.73-2.45]) and within one mile of a town (aOR=1.65[1.40-1.95]) than rural crashes. The proportion of crashes within a town differed significantly across rural gradients (P<0.0001). Small rural crashes, compared to isolated rural crashes, were 1.98 (95%CI[1.28-3.06]) times more likely to be non-collisions. The distance from the crash to town differed significantly by the urban-rural distribution (P<0.0001). CONCLUSIONS Crashes with agricultural equipment are unexpectedly common in urban areas and near towns and cities. Education among all roadway users, increased visibility of agricultural equipment and the development of complete rural roads are needed to increase road safety and prevent agricultural equipment-related crashes.

[1]  Paul P Jovanis,et al.  Estimation of the Safety Effectiveness of Lane and Shoulder Width: Case-Control Approach , 2007 .

[2]  H. Frumkin Urban Sprawl and Public Health , 2002, Public health reports.

[3]  S G Gerberich,et al.  An epidemiological study of roadway fatalities related to farm vehicles: United States, 1988 to 1993. , 1996, Journal of occupational and environmental medicine.

[4]  Samuel Labi,et al.  Efficacies of roadway safety improvements across functional subclasses of rural two-lane highways. , 2011, Journal of safety research.

[5]  Corinne Peek-Asa,et al.  Characteristics of crashes with farm equipment that increase potential for injury. , 2007, The Journal of rural health : official journal of the American Rural Health Association and the National Rural Health Care Association.

[6]  S Pinzke,et al.  Slow-moving vehicles in Swedish traffic. , 2004, Journal of agricultural safety and health.

[7]  Charles V. Schwab,et al.  Agricultural Equipment on Public Roads , 2009 .

[8]  R C Luginbuhl,et al.  Farmers' perceptions and concerns: the risks of driving farm vehicles on rural roadways in North Carolina. , 2003, Journal of agricultural safety and health.

[9]  Neal Hawkins,et al.  An empirical analysis of farm vehicle crash injury severities on Iowa's public road system. , 2010, Accident; analysis and prevention.

[10]  Corinne Peek-Asa,et al.  Rural roadway safety perceptions among rural teen drivers living in and outside of towns. , 2013, The Journal of rural health : official journal of the American Rural Health Association and the National Rural Health Care Association.

[11]  Theresa M Costello,et al.  Risk factors for a farm vehicle public road crash. , 2009, Accident; analysis and prevention.