Balancing ballistic protection against physiological strain: evidence from laboratory and field trials.

This project was based on the premise that decisions concerning the ballistic protection provided to defence personnel should derive from an evaluation of the balance between protection level and its impact on physiological function, mobility, and operational capability. Civilians and soldiers participated in laboratory- and field-based studies in which ensembles providing five levels of ballistic protection were evaluated, each with progressive increases in protection, mass (3.4-11.0 kg), and surface-area coverage (0.25-0.52 m(2)). Physiological trials were conducted on volunteers (N = 8) in a laboratory, under hot-dry conditions simulating an urban patrol: walking at 4 km·h(-1) (90 min) and 6 km·h(-1) (30 min or to fatigue). Field-based trials were used to evaluate tactical battlefield movements (mobility) of soldiers (N = 31) under tropical conditions, and across functional tests of power, speed, agility, endurance, and balance. Finally, trials were conducted at a jungle training centre, with soldiers (N = 32) patrolling under tropical conditions (averaging 5 h). In the laboratory, work tolerance was reduced as protection increased, with deep-body temperature climbing relentlessly. However, the protective ensembles could be grouped into two equally stressful categories, each providing a different level of ballistic protection. This outcome was supported during the mobility trials, with the greatest performance decrement evident during fire and movement simulations, as the ensemble mass was increased (-2.12%·kg(-1)). The jungle patrol trials similarly supported this outcome. Therefore, although ballistic protection does increase physiological strain, this research has provided a basis on which to determine how that strain can be balanced against the mission-specific level of required personal protection.

[1]  A fractionation of the physiological burden of the personal protective equipment worn by firefighters , 2012, European Journal of Applied Physiology.

[2]  Bradley C Nindl,et al.  Prediction of simulated battlefield physical performance from field-expedient tests. , 2008, Military medicine.

[3]  R. F. Goldman Physiological costs of body armor. , 1969, Military medicine.

[4]  D. Riebe,et al.  Urinary indices of hydration status. , 1994, International journal of sport nutrition.

[5]  N. Taylor,et al.  Load carriage, human performance, and employment standards. , 2016, Applied physiology, nutrition, and metabolism = Physiologie appliquee, nutrition et metabolisme.

[6]  Victoria L Richmond,et al.  The effect of cool water ingestion on gastrointestinal pill temperature. , 2008, Medicine and science in sports and exercise.

[7]  R. E. Sloan,et al.  Deep body temperature from aural canal with servo-controlled heating to outer ear. , 1975, Journal of applied physiology.

[8]  T D Noakes,et al.  The effects of different air velocities on heat storage and body temperature in humans cycling in a hot, humid environment. , 2005, Acta physiologica Scandinavica.

[9]  G. Kenny,et al.  Considerations for the measurement of core, skin and mean body temperatures. , 2014, Journal of thermal biology.

[10]  N. Secher,et al.  Pulmonary artery and intestinal temperatures during heat stress and cooling. , 2012, Medicine and science in sports and exercise.

[11]  R. Maughan,et al.  Response of unacclimatized males to repeated weekly bouts of exercise in the heat. , 1993, British journal of sports medicine.

[12]  Joanne N. Caldwell,et al.  The interaction of body armor, low-intensity exercise, and hot-humid conditions on physiological strain and cognitive function. , 2011, Military medicine.

[13]  Daniel C Billing,et al.  Effect of load carriage on performance of an explosive, anaerobic military task. , 2011, Military medicine.

[14]  Nigel A. S. Taylor,et al.  Military Clothing and Protective Material: Protection at the Limits of Physiological Regulation , 2014 .

[15]  Jeffrey M Schiffman,et al.  Use of body armor protection with fighting load impacts soldier performance and kinematics. , 2015, Applied ergonomics.

[16]  J D Hardy,et al.  Comfort and thermal sensations and associated physiological responses at various ambient temperatures. , 1967, Environmental research.

[17]  N. Taylor,et al.  Challenges to temperature regulation when working in hot environments. , 2006, Industrial health.

[18]  Brian F. Woods,et al.  Cardiovascular and thermal consequences of protective clothing: a comparison of clothed and unclothed states , 2004, Ergonomics.

[19]  Nigel A. S. Taylor,et al.  The topography of eccrine sweating in humans during exercise , 2004, European Journal of Applied Physiology and Occupational Physiology.

[20]  Paul M Vanderburgh,et al.  Load-carriage distance run and push-ups tests: no body mass bias and occupationally relevant. , 2011, Military medicine.

[21]  B. Franklin,et al.  American College of Sports Medicine position stand. Quantity and quality of exercise for developing and maintaining cardiorespiratory, musculoskeletal, and neuromotor fitness in apparently healthy adults: guidance for prescribing exercise. , 2011, Medicine and science in sports and exercise.

[22]  Tom M McLellan,et al.  Encapsulated environment. , 2013, Comprehensive Physiology.

[23]  C. Gordon,et al.  Does intramuscular thermal feedback modulate eccrine sweating in exercising humans? , 2014, Acta physiologica.

[24]  M Holewun,et al.  The influence of backpack design on physical performance , 1992 .

[25]  G. Borg Physical performance and perceived exertion , 1962 .