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Negative energy balance and loss of body mass and fat-free mass in military personnel subsisting on combat rations during training and combat operations: a comment on Tassone and Baker

Published online by Cambridge University Press:  26 April 2017

Stefan M. Pasiakos
Affiliation:
Military Nutrition Division, US Army Research Institute of Environmental Medicine, Natick, MA 01760, USA
Lee M. Margolis
Affiliation:
Military Nutrition Division, US Army Research Institute of Environmental Medicine, Natick, MA 01760, USA
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Abstract

Type
Invited Commentary
Copyright
© The Authors 2017 

The inability for military service members to achieve energy balance while subsisting primarily combat rations during strenuous military operations is well documented( Reference Keys 1 Reference Montain and Young 4 ), and military leaders have recognised this problem for centuries( Reference Manchester 5 ). For decades, the militaries of many nations have sponsored considerable research to understand the consequences of severe negative energy balance and to develop nutritional interventions to enhance field-feeding and increase total energy intake( 6 , Reference Pandolf, Francesconi and Sawka 7 ).

In this issue of the journal, Tassone & Baker( Reference Tassone and Baker 8 ) present a systematic review of the literature assessing the effects of combat ration use on body mass and body composition during military training and combat operations. They searched ten databases and aggregated information from thirty studies, published between 1976 and 2016 that focused on energy balance and alterations in body mass and composition in military personnel subsisting solely on combat rations for periods lasting 3–40 d( Reference Tassone and Baker 8 ). Tassone and Baker subsequently analysed each investigation for risk of bias, study quality and strength of evidence using validated scoring systems. Overwhelmingly, the studies were judged to be of neutral quality, at moderate risk of bias (i.e. methodological limitations), with strength of evidence ranging low to high (only six of thirty were judged high)( Reference Tassone and Baker 8 ). The most commonly cited limitations in the studies reviewed were that they lacked dietary controls, balanced study designs (i.e. control group), and often failed to control the timing of study measurements, and the conditions during which the measures were performed. Although the majority of studies were appropriately critiqued for methodological limitations, the authors rightfully acknowledged that conducting research studies during field training exercises designed to achieve a military, not scientific, objective is challenging, often forcing researchers to choose lower quality analytical methods and collect potentially flawed data because they cannot impact the overarching military mission.

Tassone & Baker( Reference Tassone and Baker 8 ) categorise and present their findings according to the duration of the training exercise and use of combat rations. They reported that during 3–7 d training exercises, where military personnel subsisted primarily on combat rations, energy expenditures were high and result in severe energy deficits( Reference Margolis, Murphy and Martini 9 , Reference Margolis, Murphy and Martini 10 ). However, when training exercises are this short, body mass losses were small (<3 % of initial body mass), and generally not considered to be detrimental to performance( Reference Friedl 11 ). However, during longer training exercises, that is, 8–12 d of near-continuous physical activities and limited time to eat, the energy deficits were large (−9 to −10 MJ/d), resulting in total body mass losses exceeding 5 % of initial body mass( Reference Alemany, Nindl and Kellogg 12 , Reference Nindl, Alemany and Kellogg 13 ). In contrast, during even longer training exercises, that is 20–30 d, energy deficits observed were lower and body mass losses were less than observed during shorter training exercises, largely because energy expenditures were not as high as those commonly reported during short-term training exercises( Reference Tassone and Baker 8 ).

Two critical issues become apparent when reading the review by Tassone & Baker( Reference Tassone and Baker 8 ). First, the overwhelming number of studies demonstrating that military personnel subsisting primarily on combat rations will underfeed, lose body mass and fat-free mass (FFM), were conducted during training exercises designed to expose military personnel to a variety of stressors, including intentional underfeeding( Reference Montain and Young 4 , Reference Margolis, Murphy and Martini 9 , Reference Margolis, Murphy and Martini 10 , Reference Margolis, Rood and Champagne 14 Reference Margolis, Crombie and McClung 16 ). Therefore, results from those studies must be interpreted in the context of that type of training, understanding that the stressors imposed, including environment, physical activity level, sleep and food availability, are designed to elicit a military-specific adaptation. The duration of the training, metabolic stress, and food availability during those programmes vary greatly, resulting in considerably different physiological and psychological responses. In fact, while the study of US Army Ranger students reported dramatic losses of body mass and FFM, the students were intentionally grossly underfed, those observations were reported over 20 years ago, and combat ration provisions during US Army Ranger School have since been increased to at least 9·2 MJ/d (two Meal Ready to EatTM per day)( 17 ). Failing to appreciate how specific nuances to each training exercise could affect physiological and psychological outcomes, and how they may differ from actual combat/deployment operations, may lead to erroneous recommendations by nutrition researchers and military nutrition policy makers. More importantly, Tassone & Baker( Reference Tassone and Baker 8 ) focus their review solely on changes in body mass and body composition when military personnel subsist on combat rations. There is no discussion on whether the observed losses of body mass or FFM, actually affected performance. They do highlight a report by the Institute of Medicine that attempts to define tolerable upper limits of body mass loss before appreciable decrements in performance are observed( Reference Friedl 11 ). However, many of the papers they reviewed did report changes in performance. What remains unclear is whether the performance declines observed were a direct result of negative energy balance, body mass and FFM loss. In addition, whether the performance metrics reported in most papers (i.e. vertical jump, lower-body peak power, mood, vigilance, etc.) are at all relevant for performance of military duties and functions are not clear. It very well may be that occasional exposure to severe negative energy balance is associated with only minimal performance impairment. The real risk of impaired performance for military personnel subsisting solely on combat rations probably only manifests after many back-to-back episodes of negative energy balance, without recovery periods with adequate recovery nutrition.

Tassone & Baker( Reference Tassone and Baker 8 ) suggest some actionable recommendations. One recommendation was to provide nutrition education relevant to the training exercise military personnel perform, as a better understanding of the importance of energy and nutrients to fuel performance may improve dietary intake (i.e. macronutrient type and energy). However, while education may help military personnel develop coping strategies, education alone will not prevent negative energy balance and its associated effects on body mass and body composition, when the energy expended exceeds the amount of energy provided in a full daily allotment of most combat rations (in the USA, i.e. equal to three Meal Ready to EatTM or approximately 15 MJ/d)( Reference Tharion, Lieberman and Montain 15 ). During some short-term training operations energy expenditures exceeded approximately 19 MJ/d. Unless supplemental nutrition, or additional combat rations are provided to personnel participating in those types of training or operations, energy balance will not be achieved, and energy deficits of approximately 4 MJ/d will be sustained. What exacerbates this problem is that military personnel will generally ‘field-strip’ their rations, choosing to carry only particular ration components, while discarding the remainder of the food products provided, to limit the total amount of weight carried during the mission (e.g. weapons, body armor, ammunition, water, food, etc.)( Reference Nindl, Castellani and Warr 18 ). Developing a tailorable education programme that recognises these realities and provides more effective ‘field-stripping’ strategies could help. Such an education programme would have to (1) acknowledge how the challenges they might encounter during operations would limit dietary intake and how poor nutrition might influence those challenges, (2) provide relevant examples of the consequences of underfeeding during operations that would be meaningful to them, to include muscle loss and military-specific performance declines (i.e. decision making capabilities, marksmanship, ability to perform long sustained patrols while carrying heavy loads), particularly if the operations are repeated with limited time to recover between missions and (3) offer simple, non-technical, mitigation strategies to enhance field-feeding.

Tassone & Baker( Reference Tassone and Baker 8 ) also suggested a need to ensure military personnel are consuming the recommended level of dietary protein (1·5–2·0 g/kg per d) to minimise FFM loss( Reference Pasiakos, Austin and Lieberman 19 ). However, for dietary protein to be effectively used for protein-requiring body processes instead of serving as a substrate for energy metabolism, a critical amount of dietary energy intake must be consumed. One study showed that Soldiers who simply ate more during a 4-d winter training exercise were not only able to attenuate the severity of the energy deficit to approximately 40 % of total daily energy needs (an energy deficit level typically used to induce about a 1 kg weight loss per week in overweight and obese individuals), but were also able to minimise the effects of underfeeding on whole-body protein balance( Reference Margolis, Murphy and Martini 9 ). They did so while meeting protein recommendations for military operations( Reference Pasiakos, Austin and Lieberman 19 ) and carbohydrate recommendations by the American College of Sports Medicine, the Academy of Nutrition and Dietetics, and the Dietitians of Canada( Reference Thomas, Erdman and Burke 20 ). While that study was only 4 d, the data suggest that there is an acceptable level of energy deficit (approximately 40 %) during strenuous military operations as long as both protein and carbohydrate are consumed within recommended levels.

How sex differences influence energy, macronutrient and micronutrient requirements during military operations remains poorly understood. Combat roles are no longer exclusive to males, and of the thirty studies identified by Tassone and Baker, only one included female service members. Total energy expenditures will likely be lower for females than males because of their lower body mass( Reference Castellani, Delany and O’Brien 21 , Reference Hoyt, Opstad and Haugen 22 ) and these lower energy requirements may make achievement of energy balance more attainable for females than males when both are subsisting on the same rations. Beyond total energy needs, females also oxidise fat at a higher rate and carbohydrate at a lower rate than males( Reference Devries, Hamadeh and Phillips 23 , Reference Carter, Rennie and Tarnopolsky 24 ). Differences in substrate oxidation may contribute to differences in body composition responses to military training between male and female military personnel. Hoyt et al. ( Reference Hoyt, Opstad and Haugen 22 ) reported that training in a semi-starved state (energy intake=0·2–2·2 MJ/d) for 7 d caused greater FFM loss in male (4·0 kg) v. female (2·5 kg) Soldiers. Females were able to more efficiently use body fat (7·3 mg fat/min per kg FFM, 89 % of total daily energy expenditure was attributed to fat) compared to their male counterparts (5·2 mg fat/min per kg FFM and 74 %). This study, which is limited by a small sample size (males: n 10; females: n 6), highlights the potential for sex-based differences in how male and females respond to military training, which could affect how they should be fed.

The systematic review by Tassone & Baker( Reference Tassone and Baker 8 ) provides a contemporary review of the literature, describing the severity and impact of negative energy balance on body weight and composition during military operations spanning from 3 to 40 d. This review highlights that though inadequate energy intake has been an issue plaguing military operations for centuries, it remains a contemporary concern. In the context of actual mission objectives, some degree of negative energy balance, body mass and FFM loss are entirely expected and may also be well-tolerated, as long as protein and carbohydrate intakes are consistent with recommendations for periods of increased metabolic stress( Reference Margolis, Murphy and Martini 9 ). One limitation of the review by Tassone & Baker( Reference Tassone and Baker 8 ) is that there is no critical evaluation of the effects of negative energy balance, body mass and FFM loss on military performance. Thus, a literature review examining the impact of negative energy balance and combat rations on physical and psychological performance responses to military operations would be an excellent follow-on paper to compliment the Tassone & Baker report( Reference Margolis, Murphy and Martini 9 ). Finally, there is a clear need to capture more data on sex-specific dietary requirements, as the number of females taking on combat roles continues to grow in modern militaries.

Acknowledgements

The opinions or assertions contained herein are the private views of the authors and are not to be construed as official or as reflecting the views of the US Army or the US Department of Defense.

Any citations of commercial organisations and trade names in this report do not constitute an official US Department of the Army endorsement of approval of the products or services of these organisations. The authors had no funding associated with this commentary.

Both authors contributed equally.

The authors have no perceived conflicts of interest.

References

1. Keys, A (1950) The residues of malnutrition and starvation. Science 112, 371373.Google Scholar
2. Taylor, HL & Keys, A (1950) Adaptation to caloric restriction. Science 112, 215218.Google Scholar
3. Hehir, P (1922) Effects of chronic starvation during the Siege of Kut. Br Med J 1, 865868.Google Scholar
4. Montain, SJ & Young, AJ (2003) Diet and physical performance. Appetite 40, 255267.Google Scholar
5. Manchester, KEC (1976) General Washington and the patriot soldiers. They won a war with little food. A Bicentennial study. J Am Diet Assoc 68, 421433.Google Scholar
6. North Atlantic Treaty Organization (2010) Nutrition Science and Food Standards for Military Operations (TR-HFM-154). Neuilly-sur-Seine Cedex: North Atlantic Treaty Organization.Google Scholar
7. Pandolf, KB, Francesconi, R, Sawka, MN, et al. (2011) United States Army Research Institute of Environmental Medicine: Warfighter research focusing on the past 25 years. Adv Physiol Educ 35, 353360.Google Scholar
8. Tassone, EC & Baker, BA (2017) Body weight and body composition changes during military training and deployment involving the use of combat rations: a systematic literature review. Br J Nutr, doi:10.1017/S0007114517000630.CrossRefGoogle Scholar
9. Margolis, LM, Murphy, NE, Martini, S, et al. (2016) Effects of supplemental energy on protein balance during 4-d Arctic Military Training. Med Sci Sports Exerc 48, 16041612.Google Scholar
10. Margolis, LM, Murphy, NE, Martini, S, et al. (2014) Effects of winter military training on energy balance, whole-body protein balance, muscle damage, soreness, and physical performance. Appl Physiol Nutr Metab 39, 13951401.CrossRefGoogle ScholarPubMed
11. Friedl, KE (1995) When does energy deficit affect soldier physical performance? In Not Eating Enough: A Report of the Committee on Military Nutrition Research, Food and Nutrition Board, Institute of Medicine. Washington, DC: National Academies Press.Google Scholar
12. Alemany, JA, Nindl, BC, Kellogg, MD, et al. (2008) Effects of dietary protein content on IGF-I, testosterone, and body composition during 8 days of severe energy deficit and arduous physical activity. J Appl Physiol (1985) 105, 5864.Google Scholar
13. Nindl, BC, Alemany, JA, Kellogg, MD, et al. (2007) Utility of circulating IGF-I as a biomarker for assessing body composition changes in men during periods of high physical activity superimposed upon energy and sleep restriction. J Appl Physiol (1985) 103, 340346.Google Scholar
14. Margolis, LM, Rood, J, Champagne, C, et al. (2013) Energy balance and body composition during US Army special forces training. Appl Physiol Nutr Metab 38, 396400.Google Scholar
15. Tharion, WJ, Lieberman, HR, Montain, SJ, et al. (2005) Energy requirements of military personnel. Appetite 44, 4765.Google Scholar
16. Margolis, LM, Crombie, AP, McClung, HL, et al. (2014) Energy requirements of US Army Special Operation Forces during military training. Nutrients 6, 19451955.Google Scholar
17. Ranger Training Brigade (2000) Ranger Handbook, Soldiers Handbook (SH) 21-76, April. Fort Benning, GA: United States Army Infantry School.Google Scholar
18. Nindl, BC, Castellani, JW, Warr, BJ, et al. (2013) Physiological Employment Standards III: physiological challenges and consequences encountered during international military deployments. Eur J Appl Physiol 113, 26552672.Google Scholar
19. Pasiakos, SM, Austin, KG, Lieberman, HR, et al. (2013) Efficacy and safety of protein supplements for U.S. Armed Forces personnel: consensus statement. J Nutr 143, 1811S1814S.Google Scholar
20. Thomas, DT, Erdman, KA & Burke, LM (2016) American College of Sports Medicine Joint Position Statement. Nutrition and athletic performance. Med Sci Sports Exerc 48, 543568.Google Scholar
21. Castellani, JW, Delany, JP, O’Brien, C, et al. (2006) Energy expenditure in men and women during 54 h of exercise and caloric deprivation. Med Sci Sports Exerc 38, 894900.Google Scholar
22. Hoyt, RW, Opstad, PK, Haugen, AH, et al. (2006) Negative energy balance in male and female rangers: effects of 7 d of sustained exercise and food deprivation. Am J Clin Nutr 83, 10681075.Google Scholar
23. Devries, MC, Hamadeh, MJ, Phillips, SM, et al. (2006) Menstrual cycle phase and sex influence muscle glycogen utilization and glucose turnover during moderate-intensity endurance exercise. Am J Physiol Regul Integr Comp Physiol 291, R11201128.Google Scholar
24. Carter, SL, Rennie, C & Tarnopolsky, MA (2001) Substrate utilization during endurance exercise in men and women after endurance training. Am J Physiol Endocrinol Metab 280, E898E907.CrossRefGoogle ScholarPubMed