Gender differences in load carriage injuries of Australian army soldiers

Musculoskeletal physical training-related injuries are a major problem in military populations. Injuries are important in terms of loss of time from work and training and decreased military readiness. The implications of these injuries in terms of patient morbidity, attrition rates, and training costs for military personnel are staggering. This article reviews: (1) pertinent epidemiologic literature on musculoskeletal injury rates; (2) injury type and location; and (3) risk factors for military populations. Suggestions for injury surveillance and prevention are also offered. Existing military and civilian epidemiologic studies were used to estimate and compare the size of the injury problem, identify risk factors, and test preventive measures. Most of the military research data obtained was from Marine and Army recruits, Army Infantry soldiers, and Naval Special Warfare candidates. Additional studies conducted in operational forces provided documentation of the injury problem in these populations as well. Injury rates during military training are high, ranging from 6 to 12 per 100 male recruits per month during basic training to as high as 30 per 100 per month for Naval Special Warfare training. Data collected show a wide variation in injury rates that are dependent largely on the following risk factors: low levels of current physical fitness, low levels of previous occupational and leisure time physical activity, previous injury history, high running mileage, high amount of weekly exercise, smoking, age, and biomechanical factors. (Data are contradictory with respect to age.) Considering the magnitude of training injuries in military populations, there is a substantial amount of work that remains to be performed, especially in the areas of surveillance, prevention, and treatment. Modifiable risk factors have been identified suggesting that overuse and other training injuries could be decreased with proper interventions. Outpatient surveillance systems are available to capture musculoskeletal injury data but need to be refined. Given the size of the problem, a systematic process of prevention should be initiated starting with routine surveillance to identify high-risk populations for the purpose of prioritizing research and prevention. Properly planned interventions should then be implemented with the expectation of dramatically reduced lost work/training time, attrition, and medical costs, while increasing military readiness.

This study reviews historical and biomedical aspects of soldier load carriage. Before the 18th century, foot soldiers seldom carried more than 15 kg while on the march, but loads have progressively risen since then. This load increase is presumably due to the weight of weapons and equipment that incorporate new technologies to increase protection, firepower, communications, and mobility. Research shows that locating the load center of mass as close as possible to the body center of mass results in the lowest energy cost and tends to keep the body in an upright position similar to unloaded walking. Loads carried on other parts of the body result in higher energy expenditures: each kilogram added to the foot increases energy expenditure 7% to 10%; each kilogram added to the thigh increases energy expenditure 4%. Hip belts on rucksacks should be used whenever possible as they reduce pressure on the shoulders and increase comfort. Low or mid-back load placement might be preferable on uneven terrain but high load placement may be best for even terrain. In some tactical situations, combat load carts can be used, and these can considerably reduce energy expenditure and improve performance. Physical training that includes aerobic exercise, resistance training targeted at specific muscle groups, and regular road marching can considerably improve road marching speed and efficiency. The energy cost of walking with backpack loads increases progressively with increases in weight carried, body mass, walking speed, or grade; type of terrain also influences energy cost. Predictive equations have been developed, but these may not be accurate for prolonged load carriage. Common injuries associated with prolonged load carriage include foot blisters, stress fractures, back strains, metatarsalgia, rucksack palsy, and knee pain. Load carriage can be facilitated by lightening loads, improving load distribution, optimizing load-carriage equipment, and taking preventive action to reduce the incidence of injury.