A longitudinal analysis of the U.S. Air Force Reserve Officers’ Training Corps physical fitness assessment

Cameron S. Mackey; Jason M. DeFreitas

doi:10.1186/s40779-019-0219-4

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A longitudinal analysis of the U.S. Air Force Reserve Officers’ Training Corps physical fitness assessment

RESEARCH | Updated：2023-06-05

- A longitudinal analysis of the U.S. Air Force Reserve Officers’ Training Corps physical fitness assessment
- A longitudinal analysis of the U.S. Air Force Reserve Officers’ Training Corps physical fitness assessment
- MMR 2020年7卷第2期页码：166-173
- Affiliations：
  
  Applied Neuromuscular Physiology Laboratory, Oklahoma State University, 192 CRC, Stillwater, OK 74078, USA
- Author bio：
  
  * Jason.defreitas@okstate.edu
- Funds：
- DOI：10.1186/s40779-019-0219-4
  中图分类号：
- 纸质出版：2020-06
- Accepted：
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A longitudinal analysis of the U.S. Air Force Reserve Officers’ Training Corps physical fitness assessment[J]. MMR, 2020,7(2):166-173.

Cite this article as: Mackey et al.: A longitudinal analysis of the U.S. Air Force reserve officers’ training corps physical fitness assessment. Mil Med Res, 2019, 6: 30
A longitudinal analysis of the U.S. Air Force Reserve Officers’ Training Corps physical fitness assessment[J]. MMR, 2020,7(2):166-173. DOI： 10.1186/s40779-019-0219-4.

Cite this article as: Mackey et al.: A longitudinal analysis of the U.S. Air Force reserve officers’ training corps physical fitness assessment. Mil Med Res, 2019, 6: 30 DOI： 10.1186/s40779-019-0219-4.

摘要

Abstract

Background:

The U.S. Air Force physical fitness assessment (PFA) is used to determine the overall fitness of their personnel. It is currently unknown to what extent the PFA scores of Reserve Officers’ Training Corps (ROTC) cadets are affected by mandatory physical training. The purpose of this investigation was to longitudinally examine the PFAs of ROTC cadets over a four-year period

evaluate the results across class ranks

and evaluate the sensitivity of the classification of the tests.

Methods:

Air Force ROTC cadets performed the PFAs (abdominal circumference

1-min pushups

1-min sit-ups

and a 1.5-mile run) in both the spring (

=26) and fall (

=22) semesters. PFAs were compiled over a four-year period (Spring 2014 – Fall 2017) and were performed in accordance with Air Force Instruction 36–2905. A oneway repeated measures ANOVA was performed separately for the fall and spring groups for each dependent variable across the 4 years. Additionally

a one-way between groups ANOVA was performed for each dependent variable during the time point (fall 2015;

=46) with the most recorded cadets for each class rank.

Results:

Longitudinal assessments revealed a main effect of time (

=0.010) on abdominal circumference; cadets had a smaller abdominal circumference in their freshman year than in their senior year. A main effect of time (

=0.006) was also observed on sit-up quantity; cadets performed more sit-ups in their junior year than in their freshman year. Examining between class ranks during the same year (between-subjects ANOVA) revealed a main effect of class rank on sit-up quantity (

=0.003); the freshmen completed fewer repetitions than the sophomores (

=0.018) and the juniors did (

=0.001).

Conclusions:

The results indicated that only the sit-up component showed differences between class ranks. These findings suggest that the Air Force PFA may not be sensitive enough to detect changes in physical fitness or distinguish between class ranks regarding physical performance

even after years of training. This limitation may be in part due to the limited duration of training incorporated by the ROTC program (2 h per week)

which provided a maintenance effect rather than improvement in physical performance. We recommend that more attention be directed to the efficacy of physical training

the sensitivity of measures included in the PFA

or both.

关键词

Keywords

references

Knapik JJ , Daniels W , Murphy M , Fitzgerald P , Drews F , Vogel J . Physiological factors in infantry operations . Europ J Appl Physiol Occup Physiol. 1990 ; 60 ( 3 ): 233 – 8 .

Knapik JJ , Sharp MA , Darakjy S , Jones SB , Hauret KG , Jones BH . Temporal changes in the physical fitness of US Army recruits . Sports Med. 2006 ; 36 ( 7 ): 613 – 34 .

U.S. Department of the Army . Army Physical Readiness Training . Field Manual 7 – 22 . Washington, DC : Department of the Army headquarters ; 2013 .

Department of the Air Force . Fitness Program: AFI 36-2905 . Washington, DC : HQ USAF/SGO ; 2013 . Available at http://www.au.af.mil/au/awc/awcgate/af/afi36-2905.pdf; http://www.au.af.mil/au/awc/awcgate/af/afi36-2905.pdf; Accessed 29 Jan 2018

Thomas DQ , Lumpp SA , Schreiber JA , Keith JA . Physical fitness profile of Army ROTC cadets . J Strength Cond Res. 2004 ; 18 ( 4 ): 904 – 7 .

American College of Sports Medicine Position Stand . The recommended quantity and quality of exercise for developing and maintaining cardiorespiratory and muscular fitness, and flexibility in healthy adults . Med Sci Sports Exerc. 1998 ; 30 ( 6 ): 975 – 91 .

Crombie AP , Lue PY , Ormsbee MJ , Llich JZ . Weight and body-composition change during the college freshman year in male general-population students and Army reserve officer training corps (ROTC) cadets . Int J Sport Nutr Exerc Metab. 2012 ; 22 ( 6 ): 412 – 21 .

Gist NH , Freese EC , Ryan TE , Cureton KJ . Effects of low-volume, highintensity whole-body calisthenics on Army ROTC cadets . Mil Med. 2015 ; 180 ( 5 ): 492 – 8 .

Jones K , DeBeliso M , Sevene TG , Berning JM , Adams KJ . Body mass index and Army physical fitness test standards in ROTC cadets . Int J Sci Eng Invest. 2012 ; 1 ( 10 ): 54 – 8 .

Liguori G , Krebsbach K , Schuna J . Decreases in maximal oxygen uptake among Army reserve officers’ training corps cadets following three months without mandatory physical training . Int J Exerc Sci. 2012 ; 5 ( 4 ): 354 – 9 .

Schiotz MK , Potteiger JA , Huntsinger PG , Denmark DC . The short-term effects of periodized and constant-intensity training on body composition, strength, and performance . J Strength Cond Res. 1998 ; 12 ( 3 ): 173 – 8 .

Steed CL , Krull BR , Morgan AL , Tucker RM , Ludy MJ . Relationship between body fat and physical fitness in Army ROTC cadets . Mil Med. 2016 ; 181 ( 9 ): 1007 – 12 .

Crawley AA , Sherman RA , Crawley WR , Cosio-Lima LM . Physical fitness of police academy cadets: baseline characteristics and changes during a 16-week academy . J Strength Cond Res. 2015 ; 30 ( 5 ): 1416 – 24 .

Oliver JM , Stone JD , Holt C , Jenke SC , Jagim AR , Jones MT . The effect of physical readiness training on reserve officers’ training corps freshman cadets . Mil Med. 2017 ; 182 ( 11 ): 1981 – 6 .

Heyward VH , Gibson A . Advanced fitness assessment and exercise prescription . Champaign : Human Kinetics ; 2014 .

David JA . Direct determination of aerobic power . In: Maud PJ , Foster C , editors . Physiological assessment of human fitness . Champaign : Human Kinetics ; 1995 . p. 9 – 17 .

Gibbons RA , Balady GJ , Beasely JW , Bricker T , Duvernoy WFC , Froelicher DC , et al . ACC/AHA guidelines for exercise testing . J Am Coll Cardiol. 1997 ; 30 ( 1 ): 260 – 315 .

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