Evaluation of the relationship pattern of (MOPC) and (APFT) tests in measuring aerobic power of military students
الموضوعات :Hekmat Ehsan Baksh 1 , Reza Sabzevari Rad 2
1 - Department of Physical Education and Sport Sciences, Faculty of Basic Sciences, Imam Ali Officers' University, Tehran, Iran
2 - Assistant Professor, Department of Physical Education and Sport Sciences, Faculty of Basic Sciences, Imam Ali Officers' University, Tehran, Iran
الکلمات المفتاحية: MOPC, APFT, aerobic power, military students,
ملخص المقالة :
Background: military forces must be physically fit to perform the task in order to perform their specialized function properly and with minimal casualties in completely different and critical situations. So the purpose of this study was Evaluation of the relationship pattern of (MOPC) and (APFT) tests in measuring aerobic power of military students. Materials and Methods: 25 Officer Students (21-25 years) were purposefully selected. At first, the MOPC (3mile run, MOB, Bench Press, Barfix, Back Squat, Simulated Casualty Evacuation Test) was performed. next stage was to perform the APFT functional test (540 m run, sit-ups, modified barfix, push-ups, sit -reach, 45 m run and agility with 4 x 9-meter test). The test was performed at the 10-day interval as MOPC. Thirdly, after one week of performing the main tests, respiratory gases (VO2, VCO2), RQ, lactate threshold (equivalent to 92% of VO2max), THR, intensity (VO2max%), O2pluse and aerobic power (VO2max) of subjects were assessed by Bruce's progressive and exhaustive test. the assumption of normality was verified using the Kolmogorov-Smirnov test. Also, linear regression analysis was used to examine the relationship between the two performance tests and Statistical analysis was performed at the significant level (p <0.05). Results: : Subjects' VO2max had a relatively weak correlation with MOPC (R = 0.26 and SEE = 0.05) and APFT (R=0.06 and SEE=0.18), which was not statistically significant. A moderate correlation(R=0.49) was observed between the two students' performance tests, however, this proportion was not significant with respect to the coefficient of determination (R2 = 0.28). Conclusion: However, having adequate aerobic power for the military forces indicates optimal levels of cardiopulmonary fitness. But in terms of the level of specialized performance when performing the test, it is not able to evaluate proper motor readiness It is therefore suggested that the components of military performance tests be reviewed and refined. by increasing Ceramide expression.
1. KORDI M., GHADAMI M., EDALATKHAH F.. EVALUATING EFFECTIVENESS OF EXECUTING SUGGESTION SYSTEM ON FACILITATING EXECUTIVE PROCESS OF TEHRAN MUNICIPALITY. URBAN MANAGEMENT STUDIES[Internet]. 2011;3(7):79-92. Available from: https://sid.ir/paper/199315/en .
2. Ghanbarzadeh, M. (2017). The Effect of an Intensity Interval Training (Hit) on the Fitness and Body Composition of the Military Personnel. Journal of Military Medicine, 18, 367-374. https://www.semanticscholar.org/paper/The-Effect-of-an-Intensity-Interval-Training-(Hit)-Ghanbarzadeh/fbf1a435523d343c3a3dbb7476899fe041c06dc2 .
3. Knapik JJ, Canham-Chervak M, Hoedebecke E, Hewitson WC, Hauret K, Held C, Sharp MA. The fitness training unit in U.S. Army basic combat training: physical fitness, training outcomes, and injuries. Mil Med. 2001 Apr;166(4):356-61. doi: 10.21236/ada400610. PMID: 11315481.
4. Grier T, Canham-Chervak M, McNulty V, Jones BH. Extreme conditioning programs and injury risk in a US Army Brigade Combat Team. US Army Med Dep J. 2013 Oct-Dec:36-47. PMID: 24146241.
5. Harman EA, Gutekunst DJ, Frykman PN, Nindl BC, Alemany JA, Mello RP, Sharp MA. Effects of two different eight-week training programs on military physical performance. J Strength Cond Res. 2008 Mar;22(2):524-34. doi: 10.1519/JSC.0b013e31816347b6. PMID: 18550970.
6. Mohammadi, S., Rostamkhani, F., Riyahi Malayeri, S. et al. High-intensity interval training with probiotic supplementation decreases gene expression of NF-κβ and CXCL2 in small intestine of rats with steatosis. Sport Sci Health 18, 491–497 (2022). https://doi.org/10.1007/s11332-021-00829-5.
7. Knapik J, Daniels W, Murphy M, Fitzgerald P, Drews F, Vogel J. Physiological factors in infantry operations. Eur J Appl Physiol Occup Physiol. 1990;60(3):233-8. doi: 10.1007/BF00839165. PMID: 2347328.
8. Riyahi Malayeri, S., Nikbakht, H, Gaeini (2014). Serum Chemerin Levels and Insulin Resistance Response to High- Intensity Interval Training in Overweight Men. Bulletin of Environment, Pharmacology and Life Sciences, 3(2), pp. 385-389.
9. Riyahi Malayeri S, Kaka Abdullah Shirazi S, Behdari R, mousavi Sadati K. Effect of 8-week Swimming training and garlic intake on serum ICAM and VCAM adhesion molecules in male obese rats. . JSSU 2019; 26 (10) :867-878.URL: http://jssu.ssu.ac.ir/article-1-4695-en.html.
10. Sharp MA, Legg SJ. Effects of psychophysical lifting training on maximal repetitive lifting capacity. Am Ind Hyg Assoc J. 1988 Dec;49(12):639-44. doi: 10.1080/15298668891380385. PMID: 3213818.
11. Vanderburgh PM. Occupational relevance and body mass bias in military physical fitness tests. Med Sci Sports Exerc. 2008 Aug;40(8):1538-45. doi: 10.1249/MSS.0b013e31817323ee. PMID: 18614935.
12. Crowder TA, Ferrara AL, Levinbook MD. Creation of a criterion-referenced Military Optimal Performance Challenge. Mil Med. 2013 Oct;178(10):1085-101. doi: 10.7205/MILMED-D-13-00081. PMID: 24083922.
13. Fakourian A, Azarbaijani M, Peeri M. Effect a period of selective military training on physical fitness, body mass index, mental health and mood in officer students. 2012. https://www.researchgate.net/publication/289520972_EFFECT_A_PERIOD_OF_SELECTIVE_MILITARY_TRAINING_ON_PHYSICAL_FITNESS_BODY_MASS_INDEX_MENTAL_HEALTH_AND_MOOD_IN_OFFICER_STUDENTS .
14. Artero EG, Lee DC, Lavie CJ, España-Romero V, Sui X, Church TS, Blair SN. Effects of muscular strength on cardiovascular risk factors and prognosis. J Cardiopulm Rehabil Prev. 2012 Nov-Dec;32(6):351-8. doi: 10.1097/HCR.0b013e3182642688. PMID: 22885613; PMCID: PMC3496010.
15. Roy TC, Springer BA, McNulty V, Butler NL. Physical fitness. Military medicine. 2010;175(suppl_8):14-20 . https://www.researchgate.net/publication/278000131_Military_Medicine_Volume_175_August_2010_Supplement_Total_Force_Fitness_for_the_21st_Century_A_New_Paradigm /
16. Welk GJ, Going SB, Morrow JR Jr, Meredith MD. Development of new criterion-referenced fitness standards in the FITNESSGRAM® program: rationale and conceptual overview. Am J Prev Med. 2011 Oct;41(4 Suppl 2):S63-7. doi: 10.1016/j.amepre.2011.07.012. PMID: 21961614.
17. Heydari S T, Khoshdel A, Sabayan B, Abtahi F, Zamirian M, et al. Prevalence of Cardiovascular Risk Factors Among Military Personnel in Southern Iran. Int Cardio Res J. 2010;4(1):e67653 . https://brieflands.com/articles/ircrj-67653.html.
18. Knapik JJ, Bullock SH, Canada S, Toney E, Wells JD, Hoedebecke E, Jones BH. Influence of an injury reduction program on injury and fitness outcomes among soldiers. Inj Prev. 2004 Feb;10(1):37-42. doi: 10.1136/ip.2003.002808. PMID: 14760025; PMCID: PMC1756537.
19. Barlow CE, Kohl HW 3rd, Gibbons LW, Blair SN. Physical fitness, mortality and obesity. Int J Obes Relat Metab Disord. 1995 Oct;19 Suppl 4:S41-4. PMID: 8581093.
20. Kianmehr P, Nazem F. Evaluation of validity and capability of professional function test of Iranian firemen. Journal Mil Med. 2011;13(3):147-53 . https://www.magiran.com/paper/919197/evaluation-of-validity-and-capability-of-professional-function-test-of-iranian-firemen?lang=en .
21. 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. doi: 10.2165/00007256-200636070-00005. PMID: 16796397.
22. Knapik J. The Army Physical Fitness Test (APFT): a review of the literature. Mil Med. 1989 Jun;154(6):326-9. PMID: 2498771.
23. Barapour E, Jajalvand M, samet M. Evaluation of physical and motor readiness of cadets based on army international norms. EBNESINA 2016; 18 (3) :18-25
URL: http://ebnesina.ajaums.ac.ir/article-1-421-fa.html.
24. Colmenero MH, Vicente GF, Ruíz JR. Assessment of physical fitness in military and security forces: a systematic review. European Journal of Human Movement. 2014(32):3-28.https://www.eurjhm.com/index.php/eurjhm/article/view/317.
25. Knapik JJ, Harman EA, Steelman RA, Graham BS. A systematic review of the effects of physical training on load carriage performance. J Strength Cond Res. 2012 Feb;26(2):585-97. doi: 10.1519/JSC.0b013e3182429853. PMID: 22130400.
26. Marić L, Krsmanović B, Mraović T, Gogić A, Sente J, Smajić M. The effectiveness of physical education of the Military Academy cadets during a 4-year study. Vojnosanit Pregl. 2013 Jan;70(1):16-20. doi: 10.2298/vsp1301016m. PMID: 23401924.
27. Nikroo, H., Barancheshme, & Azoore (2014). The comparison of the effects of combined selection of exercises and current sports activities on the improvement of physical fitness of soldiers during the training term of national service. Journal of Military Medicine, 16, 9-16.
28. Riyahi Malayeri, S., Saei, M. (2019). 'Changes in Insulin resistance and serum levels of resistin after 10 weeks high intensity interval training in overweight and obese men.', Sport Physiology & Management Investigations, 10(4), pp. 31-42.
29. Mohammadi H, Sahebazamani M. Changes in soldiers’ aerobic fitness and muscle endurance during initial basic training of police. International journal of applied exercise physiology. 2012 Dec 16;1(2).
30. Spartali I, Kostantinos H, Ioannis K, Thrasivoulos P. Body fat percentage and body mass index as predictors of cadets’ physical performance. The Open Sports Sciences Journal. 2014;7(1).. https://www.researchgate.net/publication/260868934_Body_Fat_Percentage_and_Body_Mass_Index_as_Predictors_of_Cadets'_Physical_Performance.
31. Jones, K., DeBeliso, M., Sevene, T.G., Berning, J.M., & Adams, K.J. (2012). Body Mass Index and Army Physical Fitness Test Standards in ROTC Cadets. https://www.semanticscholar.org/paper/Body-Mass-Index-and-Army-Physical-Fitness-Test-in-Jones-DeBeliso/e51fa0d3b707d2c9f4f1218845935ba5a257e82d?utm_source=direct_link.
32. Monyeki MA, Koppes LL, Monyeki KD, Kemper HC, Twisk JW. Longitudinal relationships between nutritional status, body composition, and physical fitness in rural children of South Africa: The Ellisras longitudinal study. Am J Hum Biol. 2007 Jul-Aug;19(4):551-8. doi: 10.1002/ajhb.20616. PMID: 17546607.
33. Bompa T, Buzzichelli C. Periodization Training for Sports, 3E: Human kinetics; 2015. https://a.co/d/4WXBbnO.
Received: 24 July 2023 Revised: 27 August 2023 Accepted: 7 September 2023
Keywords: MOPC, APFT, aerobic power, military students
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Abstract
Background: military forces must be physically fit to perform the task in order to perform their specialized function properly and with minimal casualties in completely different and critical situations. So the purpose of this study was Evaluation of the relationship pattern of (MOPC) and (APFT) tests in measuring aerobic power of military students. Materials and Methods: 25 Officer Students (21-25 years) were purposefully selected. At first, the MOPC (3mile run, MOB, Bench Press, Barfix, Back Squat, Simulated Casualty Evacuation Test) was performed. next stage was to perform the APFT functional test (540 m run, sit-ups, modified barfix, push-ups, sit -reach, 45 m run and agility with 4 x 9-meter test). The test was performed at the 10-day interval as MOPC. Thirdly, after one week of performing the main tests, respiratory gases (VO2, VCO2), RQ, lactate threshold (equivalent to 92% of VO2max), THR, intensity (VO2max%), O2pluse and aerobic power (VO2max) of subjects were assessed by Bruce's progressive and exhaustive test. the assumption of normality was verified using the Kolmogorov-Smirnov test. Also, linear regression analysis was used to examine the relationship between the two performance tests and Statistical analysis was performed at the significant level (p <0.05). Results: : Subjects' VO2max had a relatively weak correlation with MOPC (R = 0.26 and SEE = 0.05) and APFT (R=0.06 and SEE=0.18), which was not statistically significant. A moderate correlation(R=0.49) was observed between the two students' performance tests, however, this proportion was not significant with respect to the coefficient of determination (R2 = 0.28). Conclusion: However, having adequate aerobic power for the military forces indicates optimal levels of cardiopulmonary fitness. But in terms of the level of specialized performance when performing the test, it is not able to evaluate proper motor readiness It is therefore suggested that the components of military performance tests be reviewed and refined. by increasing Ceramide expression. |
Hekmat ehsan baksh1, Reza sabzevari rad 1* 1. Department of Physical Education and Sport Sciences, Faculty of Basic Sciences, Imam Ali Officers' University, Tehran, Iran 2. Assistant Professor, Department of Physical Education and Sport Sciences, Faculty of Basic Sciences, Imam Ali Officers' University, Tehran, Iran
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Evaluation of the relationship pattern of (MOPC) and (APFT) tests in measuring aerobic power of military students |
Research Article |
* Corresponding author: Reza sabzevari rad Address: , Imam Ali Officers' University,Imam Khomeini Street, Hor Square, Post Box 131789-3471, Tehran, Iran Email: sabzevarireza63@email.com Tell: 00982167933381 R S R: 0000-0002-5397-1244
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Journal of Sports Physiology and Athletic Conditioning Talk |
Journal of Exercise&
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such as Casualty Evacuation Test, intermittent lifting, obstacle crossing, casualty transport and other military tests are improved with increased fitness (4-10). Vanderburgh et al. (2008) stated that in the United States, ground, naval, and air forces require regular physical fitness tests to enter the military and perform their duties. In most of their physical fitness tests, upper body strength and And endurance of the trunk muscles are evaluated (11). The difference in scores obtained in the various tests can also be attributed to the criteria for recruiting individuals, including optimal levels of fitness and anthropometric characteristics of military forces in different countries (12). Fakourian et al. Examined the impact of a selected military training course on aerobic performance with the 1600-meter run test, agility with 4 x 9-meter test, and muscular endurance with the sit-up and barfix tests. Based on the findings, it was found that the indicators of military physical performance are more responsive to selected military training (13). Improving the quality of physical training and military tests is also important to improve the military fitness. Recent Army Instructions and Doctrine Guidelines on Army Physical Fitness Exercises Based on Global Views, Army Units in Physical Planning Should Focus on Endurance, Strength, and Mobility as Key Factors (14). Unfortunately, some commanders still rely heavily on comprehensive APFT scores (both individuals and units) as a screening method when examining unit combat readiness (14) Herman et al. (2008) noted that when commanders are responsible for military units, they should focus on improving physical fitness based on the physical fitness scale. They also found that long-distance run, sit-up and push-ups tests were not a robust scale for determining military-related tasks. In recent decades, in order to improve the physical fitness of soldiers, tests and other factors such as speed, agility, coordination, strength and power have usually been considered (5) Among the tests and studies available to assess military readiness, the main focus is on assessing general fitness skills. And the |
Physical-motor fitness and Suitable body composition is a major concern of all armies and one of the determining factors in the efficiency and performance of military forces. The nature of military operation requires that the military person (whether in peacetime or during war) be physically fit(1) Activity and living in areas with limited facilities (in highlands, plains and forests) or undesirable geographical areas, having heavy physical activity, prolonged work, and the need to endure difficulties due to occupational nature are evidences of this claim(1). The physical fitness of a military is defined as the capacity to perform continuous and skillful movements, the ability to return to baseline after high pressure, the willingness to complete the intended tasks and the confidence to face any situation (2).Success or failure in missions and operations, in addition to advanced equipment and technology, depends on the physical and mental health and fitness level of the troops (1, 2). For example, the inadequacy of American troops on July 5, 1950, in the fight with Korean troops in the early days of the war led to American troops leaving the war zone and leaving their wounded companions and valuable equipment. Because their training to prepare inadequate physical-motor parameters could barely carry heavy cargo. The valuable lessons learned by the Smithsonian Task Force in Korea have led to a great deal of attention being paid to the physical fitness and fitness of the military at educational institutions throughout the United States (3) Research evidence suggests that high levels of physical fitness, especially cardio and respiratory endurance, and the ability to perform long-term exercises, have a significant effect on removing and modifying burnout and maintaining physical and mental health. On the other hand, the results of numerous studies indicate that military performance tests |
1. Introduction |
Journal of Exercise&
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should use optimal military performance tests to enhance these two factors. In order to record the results and evaluate the performance of individuals, comparing the individual with his or her own past and comparing them with other people, the need for classified tests is felt. The purpose of this study was to evaluate the accuracy and capability of MOPC and APFT according to cardiovascular fitness level in military students. |
performance or combat readiness of the military in their real environment has been underestimated. In other words, in the past, more emphasis has been placed on 2-mile running, sit-down, push-ups tests to increase physical fitness. However, these tests were used for the 1970s and 1980s when the soldier had no physical fitness and also had many opportunities to reach the desired level of fitness (15). Studies conducted at the Army Health Research Center (Military Epidemiology Research Institute) have shown that some military exercises and training are not efficient in achieving physical fitness (16). Anthropometric and body composition studies are currently not included in Iranian physical fitness tests. In the other armies, however, these studies are only periodic examinations and tests (17). In addition, technological advances have also led to increased body strength and potential overload of military personnel. As the weight of personnel equipment increases, metabolic and physiological demand increases (1). The Military Optimal Performance Challenge (MOPC) is a novel test that examines the capability of individuals in the military with physical fitness factors and deals with the examination, recording, and comparison of individuals in a specialized manner (1). Given the completeness and accuracy of the MOPC test package over other similar specimens, in recent years various countries have used this MOPC test kit as a standard norm to enhance the capability of their troops. In addition to physical factors, this test evaluates the cases in which a fighter may be exposed to the combat environment (1). Given the importance of physical fitness and body composition in the armed forces, all military units and personnel in all ranks
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Test 4. Barfix/Horizontal bar for Middle Shoulder. This test measures the muscular endurance of the hands Test 5. Ankles to the Bar. This test evaluated the lower trunk strength.Test 6. Back Squat. This test evaluated the lower trunk strength.Test 7. Simulated Casualty Evacuation Test. This test evaluates high- intensity desirable performance. Each error in the execution of each item was added to the time of execution of each individual task. The test was conducted under the supervision of a sports officer with all safety-training tips. The next stage was to perform the APFT functional test (540 m run, sit-ups, modified barfix, push-ups, sit -reach, 45 m run and 4 x 9-meter test). The test was performed by two referees at the 10-day interval as the first functional test. The first referee, recording errors at each station, and the second referee, had the task of announcing the start and recording time. The results of each subject were recorded in the performance test based on the errors of each subject (18). In the third stage, after one week of the main tests, the students were randomly divided into 5 groups include 5 subjects. Subjects' cardiovascular variables included respiratory gas (VO2, VCO2), respiratory rate (RQ), lactate threshold (equivalent to 92% of maximal oxygen consumption), exercise heart rate, work intensity (VO2max%), oxygen pulse (O2pluse) and Aerobic power (VO2max) was evaluated by standard methods by a sports physiologist at the National Olympic Laboratory. Aerobic capacity measurement by analyzing respiratory gases (VO2, VCO2), Target Heart rate (THR), and RQ at the last 15 seconds of each 3-minute step (activity on treadmill under ambient load conditions) by observing both RQ> 1.1 and HRmax THR> 0.90 Measured by an automated machine (Quark-B2, Italy) (20-23). The information of the subjects working on the treadmill (Bruce's progressive and exhaustive program) was measured in STPD (Standard Pressure and Temperature, Dry) in the Computer Memory of the Device (COSMED; US Made) Record.
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2. Materials and Methods |
Subjects This study was a descriptive-analytical study which was carried out in autumn 2018. Participants in this study were Officer Students (21-25 years old) of Imam Ali University of Tehran. 25 volunteers were purposefully selected using Morgan et al.'s sample size estimation table. All subjects completed PAR-Q (Physical Activity Readiness Questionnaire). Inclusion criteria included general health and initial physical fitness and non-use of medication by subjects. In addition, a rest electrocardiogram was performed at the National Olympic Laboratory. Exercise protocol Prior to the exercise protocol, participants performed warm up exercises, upper and lower leg stretching exercises. The MOPC test was held in the 60*40 m multifunctional hall along with a standard track and field track at Imam Ali's Officer University. In order to standardize and increase the reliability of the test results with emphasis on the Arranging the test run, the test was conducted in two sessions. At each station, elementary education was given precise and sufficient training to increase participants' assistance with Test recipients. Exclusion criteria included non-co-operation and incomplete data of participants for any reason, as well as possible injury or history of musculoskeletal injury in recent months. None of the participants met the exclusion criteria. The MOPC test components consisting of 7 tests were implemented as follows: Test 1. 3mile run (4827m Run): This test was performed at a designated distance around the track and the cardiopulmonary endurance capacity was measured. Test 2. Mobility for Battle: This test measures high-intensity motor performance. This test consists of a series of high-intensity motor barriers and tasks that a soldier must successfully complete within a specified time (Figure 1). Test 3. Number of Repetitions with Fixed Weight of Bench Press. This test evaluated the high intensity physical work capacity (high trunk strength). and shoulder gridle.
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In the Bruce protocol, the first person walked (at 22.3 ° C) for 5 minutes at Heart Rate= 95- 118 beats per minute. Then the speed of the machine started at 3 km / h and every minute was added to the previous speed of 1 km/h. subjects near the lactate threshold level were verbally encouraged to reach maximal voluntary fatigue (19, 20). Statistical analysis All data are reported as means and standard deviations. Before using parametric tests, the assumption of normality was verified using the Kolmogorov-Smirnov test. Also, linear regression analysis was used to examine the relationship between the two performance tests. The difficulty level of test performance in proportion to the time spent on each of the two test components, which was dependent on the parameters of speed, accuracy, agility, muscle endurance, and subject coordination, was measured by histograms and Q-Q diagrams. The relationship between the cardiac performance index of subjects, aerobic power (VO2max) with both tests was investigated by linear regression method. Statistical analysis was performed at the significant level (p <0.05).
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3. Results |
The anthropometric indices and the results of the functional test of the subjects are presented in Table 1. Their record in the MOPC and APFT tests was 161.7 and 263.2, respectively. Direct aerobic capacity values were 39 to 53 ml/kg for two minutes and Target heart rate (THR) was 161 to 199 bpm equal to 49 to 80% of the subjects' aerobic power (Table 2). A moderate correlation was observed between the two students' performance tests (Table 3), however,this proportion was not significant with respect to the coefficient of determination (R2 = 0.28).
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Table 1. The anthropometric indices and the results of the functional test of the subject |
Weight(kg) | Height(cm) | BMI (kg/cm2) | Performance Test (Score) |
Variable
Statistics | |
MOPC | APFT | ||||
66.075 | 171.9 | 18 | 161.7 | 263.2 | Mean |
9.23 | 5.18 | 16.4 | 37.9 | 29.6 | SD |
59.48 | 167.53 | 15.7 | 148.3 | 230.6 | Minimum value |
72.66 | 176.27 | 20.3 | 202.1 | 291.7 | maximum value |
Pulse O2 | VO2max (ml/kg/min) |
Heart Rate (bpm) | Intensity (VO2max%) |
Variable
Statistics |
18.1 | 46.05 | 180.61 | 64.12 | Mean |
2.15 | 3.21 | 8.98 | 9.63 | SD |
13.2 | 39.01 | 161 | 49 | Minimum value |
23 | 53 | 199 | 79 | maximum value |
Table2. Physiological variables During the exhausting test
Table 3: Relationship of mean APFT performance tests with MOPC
P value | R2 | R | SEE | Mean | Statistics
Performance test |
0.005 | 0.28 | 0.49 | 0.128 | 263.2 | APFT |
161.7 | MOPC |
Abbreviations: SD; The standard deviation, APFT; Army physical fitness test, MOPC; Military Optimal Performance
Challenge, BMI; body mass index.
Figure 1. Mobility for Battle. This test measures high-intensity motor performance. This test consists of a series of high-intensity obstacles and tasks that a soldier must successfully complete within the specified time.
4. Discussion |
Researchers report improvement in fitness level by assessing military fitness during 1975- 2003. It has also been stated that high-level physical fitness enables the military to carry out targeted missions with minimal fatigue and energy (21). Regular exercise also improves individual ability and general health (22). In the military forces, high levels of physical fitness are essential not only for health but also for special military functions and injury prevention. Experimental and field research has shown that soldiers with higher physical fitness have better performance in actual or simulated military operations, and those with lower fitness are more susceptible to injury (23-28)In more than 20 case studies, factors such as muscular strength and endurance and cardiovascular fitness have been reported as key elements in military service during combat. In recent years, researchers have been designing and implementing various tests that have yielded different results at different times, and these results have contributed greatly to the growing military trend of different countries. But gathering data, evaluating and quantifying the position of the military in real battle scenes and maneuvers is a difficult task. The weaknesses of the organizations involved in standardizing the functions and formulation of the norms of fitness of the armed forces of the country are barriers that do not provide a detailed description of the physical needs of the military and the factors contributing to its problems (21). In planning military exercises, trainers need information such as determining the level of fitness required of different combat units and units according to the type of duty and responsibility and performing physical fitness tests to determine individuals' physical fitness. The necessity of physical activity and physical tests in the military has been emphasized by Knapik (1989). Heydari et al. |
(2009), based on the findings of their research, concluded that the physical fitness of soldiers increases during training, but this amount does not provide all the dimensions of physical fitness required for successful military operations (29). Muscle strength plays a key role in carrying heavy ammunition and performing military duties and cardiovascular fitness (25, 28)In a study comparing the effect of selected combined exercise and current exercise training on improving physical fitness levels, Nikroo et al(2014) Suggested that selected combination exercise training program more effective response to improved physical fitness levels in soldiers than current exercise training(27). Colmenero et al. (2014), investigate a relatively large number of experiments evaluating muscular endurance (eg sit-ups), maximal strength (eg grip strength, vertical jump, etc.) and flexibility (eg sit and reach) in military. They stated that the major problem when assessing skeletal muscle fitness is that there is no appropriate standard for the test. For example, different types of sit-ups (a number of tests in one minute, a number of tests in two minutes, and a number of tests to fatigue, etc.) have been prevented from comparing studies(24). It should be noted that many of the tests in this study have focused on assessing skeletal muscle fitness in the upper body. The upper-level power seems to have a greater impact on military duties. However, low trunk evaluation is also of great importance with regard to the combat duties of military or security forces (23). Considering the high endurance and muscle strength needed to carry the injured, lifting the ammunition box, carrying military equipment on the sidewalks, as well as moving equipment, officers and ground forces And this is an important factor in military activity. Marić et al (2013) stated that physical activity programs over a four-year |
results obtained for the best possible performance along with the militarization system, the countries are using different systems to enhance the capability of their forces. In most countries, physical fitness factors (speed, agility, coordination, strength, power and endurance) have been used (33). According to the present studies in Iran, unfortunately, there is no proper field test model to measure the military performance. Among the tests and studies available in assessing military readiness, tests have focused more on assessing general fitness skills and less on military performance or combat readiness in their actual environment. The purpose of this study was to evaluate the accuracy and capability of MOPC and APFT according to cardiovascular fitness level. The results of this study showed that 25 military students with BMI equall 15.7-20.3 kg/m2 and with average body composition of 18 kg/m2 showed moderate correlation with APFT functional test (R = 0.49 and SEE = 0.12). Note that the distribution of test record time in MOPC tends to be negatively skewed. This is considered an indicator for assessing speed and coordination during battle and maneuvers, so that fewer people were able to achieve acceptable standard scores than the APFT test. As a result, subjects reported performing the MOPC test a bit more difficult than the APFT test. Given that (R2 = 0.28), that is, the dependency between the two functional tests of alliance is influenced by other confounding factors that are outside of the existing components and that the role-play tests. In other words, even the 50% runtime or record of military fitness scores in the APFT test cannot be predicted from the MOPC test score. Therefore, in spite of the subjects having the best body composition and optimal cardiovascular endurance, |
period only slightly improve students' physical abilities (26). Bararpour et al (2016) found that the highest scores in cardiovascular tests and the lowest scores in endurance and muscle strength tests, respectively, were found in In assessing the physical and motor fitness of the officers, students(23). Spartali et al. (2014) examined anthropometric indices as predictors of physical performance in Greek military students. Their results showed that students with lower BMI and body fat achieved better results during performance tests. Body fat percentage was a more accurate predictor of performance than BMI. In general, the use of more than one component of anthropometric characteristics was emphasized to classify students' physical status, and the case is not purely based on BMI values (30). Jones et al. (2012) also examined the results of individual tests of the US Army Physical Fitness Test (PFT) and BMI of military students. They stated that if there was a correlation between BMI scores and the military fitness test, more accurate commanders could organize future fitness assessments (31). Their results showed no significant relationship between BMI and push-ups, sit-ups, or 2-miles run. .BMI does not accurately predict students' military fitness test scores. They said further studies are needed to determine the relationship between military fitness test scores and other anthropometric measures. In addition, in the research on non-military, the results of Monyeki et al. (2007) showed that there is a significant relationship between physical composition and physical fitness. Of course, this is not always the case in the expected direction and it is important to note that BMI should not be considered as a measure of obesity or overweight and can be an indicator of muscle mass (32). According to the research conducted on the military in different countries over the years and the |
the essential factors of physical fitness that are power-based military exercises. Bompa believed that based on an exercise model, more strengh, endurance, speed and power were needed to maintain the best performance (33). All of these factors have been applied to the MOB test and it can be stated that the specificity of the MOB test for the military skills in the present study can be justified. In this study, among the controllable limitations to age and sex of subjects, time and place of training, subject's living conditions and uncontrollable limitations to individual differences, Subjects' levels of motivation, variations in interest, and physical and physiological characteristics of the subjects were noted. |
However, having adequate aerobic power for the military forces indicates optimal levels of cardiopulmonary fitness. But in terms of the level of specialized performance when performing the test, it is not able to evaluate proper motor readiness It is therefore suggested that the components of military performance tests be reviewed and refined. |
Conclusion
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Author contributions
Conceptualization: MS., KH.J.D F.T.; Methodology: MS.., KH.J.D, F.T.,.; Software: MS.,., KH.J.D., FT Validation: MS., KH.J.D., F.T.; Formal analysis: KH.J.D., F.T.; Investigation:., KH.J.D., F.T.; Resources: MS., KH.J.D ,F.T. Data curation: MS., F.T., KH.J.D.,.; Writing - original draft: MS., F.T., KH.J.D.; Writing - review & editing: MS., KH.J.D ,F.T.,.; Visualization: MS., F.T., KH.J.D.; Supervision: MS.,., KH.J.D., F.T.; Project administration: MS., KH.J.D., FT.; Funding acquisition: MS.,., KH.J.D., F.T
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Acknowledgements |
The authors would like to thank all the participant for their time and effort during the tests.also thank From the assistance of the commander of Imam Ali's officer's university and Research Assistant. |
Funding This study did not have any funds. |
Compliance with ethical standards |
Ethical approval the research was conducted with regard to the ethical principles. Informed consent Informed consent was obtained from all participants.
|
Author contributions
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None declared.
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10. Sharp MA, Legg SJ. Effects of psychophysical lifting training on maximal repetitive lifting capacity. Am Ind Hyg Assoc J. 1988 Dec;49(12):639-44. doi: 10.1080/15298668891380385. PMID: 3213818.
11. Vanderburgh PM. Occupational relevance and body mass bias in military physical fitness tests. Med Sci Sports Exerc. 2008 Aug;40(8):1538-45. doi: 10.1249/MSS.0b013e31817323ee. PMID: 18614935.
12. Crowder TA, Ferrara AL, Levinbook MD. Creation of a criterion-referenced Military Optimal Performance Challenge. Mil Med. 2013 Oct;178(10):1085-101. doi: 10.7205/MILMED-D-13-00081. PMID: 24083922.
13. Fakourian A, Azarbaijani M, Peeri M. Effect a period of selective military training on physical fitness, body mass index, mental health and mood in officer students. 2012. https://www.researchgate.net/publication/289520972_EFFECT_A_PERIOD_OF_SELECTIVE_MILITARY_TRAINING_ON_PHYSICAL_FITNESS_BODY_MASS_INDEX_MENTAL_HEALTH_AND_MOOD_IN_OFFICER_STUDENTS .
14. Artero EG, Lee DC, Lavie CJ, España-Romero V, Sui X, Church TS, Blair SN. Effects of muscular strength on cardiovascular risk factors and prognosis. J Cardiopulm Rehabil Prev. 2012 Nov-Dec;32(6):351-8. doi: 10.1097/HCR.0b013e3182642688. PMID: 22885613; PMCID: PMC3496010.
15. Roy TC, Springer BA, McNulty V, Butler NL. Physical fitness. Military medicine. 2010;175(suppl_8):14-20 . https://www.researchgate.net/publication/278000131_Military_Medicine_Volume_175_August_2010_Supplement_Total_Force_Fitness_for_the_21st_Century_A_New_Paradigm / 16. Welk GJ, Going SB, Morrow JR Jr, Meredith MD. Development of new criterion-referenced fitness standards in the FITNESSGRAM® program: rationale and conceptual overview. Am J Prev Med. 2011 Oct;41(4 Suppl 2):S63-7. doi: 10.1016/j.amepre.2011.07.012. PMID: 21961614.
17. Heydari S T, Khoshdel A, Sabayan B, Abtahi F, Zamirian M, et al. Prevalence of Cardiovascular Risk Factors Among Military Personnel in Southern Iran. Int Cardio Res J. 2010;4(1):e67653 . https://brieflands.com/articles/ircrj-67653.html.
18. Knapik JJ, Bullock SH, Canada S, Toney E, Wells JD, Hoedebecke E, Jones BH. Influence of an injury reduction program on injury and fitness outcomes among soldiers. Inj Prev. 2004 Feb;10(1):37-42. doi: 10.1136/ip.2003.002808. PMID: 14760025; PMCID: PMC1756537. 19. Barlow CE, Kohl HW 3rd, Gibbons LW, Blair SN. Physical fitness, mortality and obesity. Int J Obes Relat Metab Disord. 1995 Oct;19 Suppl 4:S41-4. PMID: 8581093. |
1. KORDI M., GHADAMI M., EDALATKHAH F.. EVALUATING EFFECTIVENESS OF EXECUTING SUGGESTION SYSTEM ON FACILITATING EXECUTIVE PROCESS OF TEHRAN MUNICIPALITY. URBAN MANAGEMENT STUDIES[Internet]. 2011;3(7):79-92. Available from: https://sid.ir/paper/199315/en . 2. Ghanbarzadeh, M. (2017). The Effect of an Intensity Interval Training (Hit) on the Fitness and Body Composition of the Military Personnel. Journal of Military Medicine, 18, 367-374. https://www.semanticscholar.org/paper/The-Effect-of-an-Intensity-Interval-Training-(Hit)-Ghanbarzadeh/fbf1a435523d343c3a3dbb7476899fe041c06dc2 . 3. Knapik JJ, Canham-Chervak M, Hoedebecke E, Hewitson WC, Hauret K, Held C, Sharp MA. The fitness training unit in U.S. Army basic combat training: physical fitness, training outcomes, and injuries. Mil Med. 2001 Apr;166(4):356-61. doi: 10.21236/ada400610. PMID: 11315481. 4. Grier T, Canham-Chervak M, McNulty V, Jones BH. Extreme conditioning programs and injury risk in a US Army Brigade Combat Team. US Army Med Dep J. 2013 Oct-Dec:36-47. PMID: 24146241. 5. Harman EA, Gutekunst DJ, Frykman PN, Nindl BC, Alemany JA, Mello RP, Sharp MA. Effects of two different eight-week training programs on military physical performance. J Strength Cond Res. 2008 Mar;22(2):524-34. doi: 10.1519/JSC.0b013e31816347b6. PMID: 18550970. 6. Mohammadi, S., Rostamkhani, F., Riyahi Malayeri, S. et al. High-intensity interval training with probiotic supplementation decreases gene expression of NF-κβ and CXCL2 in small intestine of rats with steatosis. Sport Sci Health 18, 491–497 (2022). https://doi.org/10.1007/s11332-021-00829-5. 7. Knapik J, Daniels W, Murphy M, Fitzgerald P, Drews F, Vogel J. Physiological factors in infantry operations. Eur J Appl Physiol Occup Physiol. 1990;60(3):233-8. doi: 10.1007/BF00839165. PMID: 2347328. 8. Riyahi Malayeri, S., Nikbakht, H, Gaeini (2014). Serum Chemerin Levels and Insulin Resistance Response to High- Intensity Interval Training in Overweight Men. Bulletin of Environment, Pharmacology and Life Sciences, 3(2), pp. 385-389. 9. Riyahi Malayeri S, Kaka Abdullah Shirazi S, Behdari R, mousavi Sadati K. Effect of 8-week Swimming training and garlic intake on serum ICAM and VCAM adhesion molecules in male obese rats. . JSSU 2019; 26 (10) :867-878.URL: http://jssu.ssu.ac.ir/article-1-4695-en.html. |
References |
20. Kianmehr P, Nazem F. Evaluation of validity and capability of professional function test of Iranian firemen. Journal Mil Med. 2011;13(3):147-53 . https://www.magiran.com/paper/919197/evaluation-of-validity-and-capability-of-professional-function-test-of-iranian-firemen?lang=en .
21. 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. doi: 10.2165/00007256-200636070-00005. PMID: 16796397.
22. Knapik J. The Army Physical Fitness Test (APFT): a review of the literature. Mil Med. 1989 Jun;154(6):326-9. PMID: 2498771.
23. Barapour E, Jajalvand M, samet M. Evaluation of physical and motor readiness of cadets based on army international norms. EBNESINA 2016; 18 (3) :18-25 URL: http://ebnesina.ajaums.ac.ir/article-1-421-fa.html.
24. Colmenero MH, Vicente GF, Ruíz JR. Assessment of physical fitness in military and security forces: a systematic review. European Journal of Human Movement. 2014(32):3-28.https://www.eurjhm.com/index.php/eurjhm/article/view/317.
25. Knapik JJ, Harman EA, Steelman RA, Graham BS. A systematic review of the effects of physical training on load carriage performance. J Strength Cond Res. 2012 Feb;26(2):585-97. doi: 10.1519/JSC.0b013e3182429853. PMID: 22130400.
26. Marić L, Krsmanović B, Mraović T, Gogić A, Sente J, Smajić M. The effectiveness of physical education of the Military Academy cadets during a 4-year study. Vojnosanit Pregl. 2013 Jan;70(1):16-20. doi: 10.2298/vsp1301016m. PMID: 23401924.
27. Nikroo, H., Barancheshme, & Azoore (2014). The comparison of the effects of combined selection of exercises and current sports activities on the improvement of physical fitness of soldiers during the training term of national service. Journal of Military Medicine, 16, 9-16.
28. Riyahi Malayeri, S., Saei, M. (2019). 'Changes in Insulin resistance and serum levels of resistin after 10 weeks high intensity interval training in overweight and obese men.', Sport Physiology & Management Investigations, 10(4), pp. 31-42.
|
29. Mohammadi H, Sahebazamani M. Changes in soldiers’ aerobic fitness and muscle endurance during initial basic training of police. International journal of applied exercise physiology. 2012 Dec 16;1(2).
30. Spartali I, Kostantinos H, Ioannis K, Thrasivoulos P. Body fat percentage and body mass index as predictors of cadets’ physical performance. The Open Sports Sciences Journal. 2014;7(1).. https://www.researchgate.net/publication/260868934_Body_Fat_Percentage_and_Body_Mass_Index_as_Predictors_of_Cadets'_Physical_Performance.
31. Jones, K., DeBeliso, M., Sevene, T.G., Berning, J.M., & Adams, K.J. (2012). Body Mass Index and Army Physical Fitness Test Standards in ROTC Cadets. https://www.semanticscholar.org/paper/Body-Mass-Index-and-Army-Physical-Fitness-Test-in-Jones-DeBeliso/e51fa0d3b707d2c9f4f1218845935ba5a257e82d?utm_source=direct_link.
32. Monyeki MA, Koppes LL, Monyeki KD, Kemper HC, Twisk JW. Longitudinal relationships between nutritional status, body composition, and physical fitness in rural children of South Africa: The Ellisras longitudinal study. Am J Hum Biol. 2007 Jul-Aug;19(4):551-8. doi: 10.1002/ajhb.20616. PMID: 17546607.
33. Bompa T, Buzzichelli C. Periodization Training for Sports, 3E: Human kinetics; 2015. https://a.co/d/4WXBbnO. |