Archive \ Volume.11 2020 Issue 1

 

Impact of different physical activity levels on academic performance of PSAU medical female students

 

Samah Alsaid Moawd1,2*, Shereen Hamed Elsayed2,3, Walid Kamal Abdelbasset1,4, Gopal Nambi1, Anju Verma1

 

 

1 Department of Physical Therapy and Health Rehabilitation, College of Applied Medical Sciences, Prince Sattam bin Abdulaziz University, Alkharj, Saudi Arabia. 2 Department of Physical Therapy for Cardiovascular/Respiratory Disorder and Geriatrics, Faculty of Physical Therapy, Cairo University, Giza, Egypt. 3 Department of Rehabilitation Sciences, Faculty of Health and Rehabilitation Sciences, Princess Nourah bint Abdulrahman University, Riyadh, Saudi Arabia.4 Department of Physical Therapy, Kasr Al-Aini Hospital, Cairo University, Giza, Egypt.

 

Abstract

 

Physical activity plays a pivotal part in gaining cardio respiratory fitness hence improving academic performance in medical students especially females. Accordingly, it is important to evaluate the effect of physical activity on academic performance of the students using cardio respiratory fitness as a mediator. The study aimed to detect that cardio respiratory fitness goes between physical activity and academic performance in PSAU medical female students. Methods: Assessment of cardio respiratory fitness was done by 20m Shuttle Run Test [SRT], physical activity levels were determined by International Physical Activity Questionnaire [IPAQ] and Academic Performance [AP] was detected by Grade Point Average [GPA] over past three consecutive semesters and the relationship between them was tested. Results: The statistical analysis confirmed a high significant correlation between cardio respiratory capacity, academic performance and physical activity (p<0.05) in moderate and high level physical activity without significant differences in low level physical activity in medical university female students (p > 0.05).The results of the bootstrapped mediation analysis indicated that physical activity had a direct effect on cardio respiratory fitness, which in turn influenced the academic performance among participants only in moderate to high physical activity. Conclusion: Consequently, the hypothesis that cardio respiratory fitness mediates the relationship between physical activity and academic performance in moderate to high activity was confirmed. Physical activity is a prerequisite for improved cardio respiratory capacity, leading to better academic performance for healthy academic life and future career in PSAU medical female students.

 

Keywords: physical activity; cardio respiratory fitness; academic performance; university students

 

INTRODUCTION

 

Health promotion and cardiopulmonary fitness are maintained by regular physical activity. This improves cardiovascular function [1]. Physical activity (PA) in the form of exercise program enhances body systems; including cardiovascular and respiratory systems. So, well-trained individuals have a decreasing sympathetic response and an increasing parasympathetic response leading to a decrease in resting heart rate [2]. Regular physical activity improves cognitive and physical function in adolescent and later in their life so decreasing the health complication that results from increased fatness and increased risk factors of cardiovascular diseases [3]. Cardio respiratory fitness (CRF) mirrors the capacity of the cardiovascular and respiratory systems. Students with high CRF have positive cardiovascular profile when compared to unfit colleagues as CRF is an indicator of students’ physiological state [4, 5].

Brain function and structure are affected by physical activity in the children and adolescent. Many studies found a strong relationship between exercises-induced improvement in physical fitness (PF) and cognition function & academic performance (AP). So, executive function is improved [6, 7]. Previous studies found a bidirectional relation between AP and PF, some of them proved that PF goes between PA and AP; while, other studies found that PA indirectly affects AP through enhancing PF [8]. Encouragement of physical activity in university-motivated students is very important as those students are excited to be superior in learning and activity. So, they are always engaged in routine physical activity to be physically fit [9-11]

In medical female students, decreasing the physical activity produces a negative effect on physical fitness due to weight gain. Overweight in those students results in high incidence of many health hazards as cardiovascular disease and musculoskeletal disorder which affect their performance. Sufficient knowledge about benefits of physical activity and hazards of decreasing activity level should be continuously informed [11-14].

Sedentary lifestyle is more common in academic life of university students especially females, so changes in cardio respiratory capacity and anthropometric measurements will be consequently resulted. A prior study by Gáldi [15] stated that participation in sports activities is decreased with aging. Only 50% of those aged over 15 years are regularly participated in routine activity; therefore, adiposity and associated complications are increased. Educational level in academic life is affected by the level of fitness; so, increased physical activity is required.

Physical activity (PA) stimulates brain activity and encourages cognitive function leading to better academic performance [15-17]. Gaining health by regular physical activity relieves depression, yields higher self-confidence, helps to make better relations, prevents cardiovascular diseases and reduces mortality rate [18]. We hypothesize that physical activity positively affects academic performance. So, the aim of this study is to evaluate the relationship between physical activity, physical fitness and academic performance in female students in PSAU.

MATREIAL AND METHOD

Study Design

This is a cross-sectional study aimed to evaluate the effect of physical activity on cardio respiratory fitness and academic performance from October to December 2019.  The study sample comprised of 100 medical female university students, volunteered to participate in the study.

Subjects

All participants were university female student from medical colleges, born between 1996 and 2002 and, enrolled in last year of their academic life, and free of any chronic disease or medical condition. Their mean body height was 159.55 ± 5.33 cm and mean body mass was 60.7 ± 6.24 kg.

Materials

Body composition

The participants were instructed not to take any food or drink 10-12 hours before testing. A digital scale and a stadiometer with the accuracy of 0.1 kg and 1 mm were used to measure body weight and height. BMI is a calculation suing body weight/ (height) [19].

Cardio respiratory fitness (CRF)

CRF was evaluated by 20m shuttle run test by running between two lines 20m apart. Audio signal from CD was kept at initial speed 8.5 km/h and increased by 0.5 km/h/min. The students were informed to run as long as possible in straight line while they listen to the signal. And they were asked to stop continuing the test either if they fail to reach the line two times with the audio signal or feel fatigue [20]

Academic performance

Measurement of academic performance for university medical students was done by taking their GPA over last three consecutive semesters for which the reliability was 0.966 using test-retest method [21].

Physical Activity

The International Physical Activity Questionnaire (IPAQ) [22] which is a self-reported physical activity level that includes seven questions with three levels of activity (light, moderate, and vigorous) was used for calculating the test-retest reliability. The coefficient for that was 0.882 [Appendix 1].

Statistical analysis

The data analysis was undertaken using the SPSS for windows version 22.0 (IBM Corp, Armonk, NY, USA). Frequencies and medians were used for basic descriptors whereas; the association between the variables was detailed and analyzed using t-test and analysis of variance (ANOVA). In addition, the regression analysis was developed in order to determine the relationship between the variables. The significance level was set at p˂0.05.

RESULTS

Table 1 summarizes the comparison of demographic data (age, weight, height, and BMI) between three groups. The three groups were homogenous related to these variables. While there was a significant difference in cardio respiratory fitness which evaluated by estimating VO2max and academic performance (GPA) between the two groups.

Table 2 shows a high significant correlation between moderate & high physical activity and CRF as well as academic performance (p˂0.001). While, low physical activity exhibited a non-significant correlation (p=0.09).

Table 3 exhibits indirect effects of CRF on AP, unstandardized coefficients (standard error). Bias corrected 95% CI based on bootstrap sample. The level of statistical significance was set at p<0.05. The results of the bootstrapped mediation analysis showed that PA has a direct effect on CRF, which in turn affects the AP among students in moderate to high PA. After adjusting for CRF, the association between PA and AP does not appear prominently; while, the relation between CRF with AP is still the same. Neither PA nor CRF was related with the AP of low physical activity.

DISCUSSION

Health promotion is achieved by regular practicing of physical activity in academic life.  Besides, physical activity promotes cardio respiratory fitness and enhances academic performance. Universities should provide suitable environment for activity for students so as to gain proper fitness and reduce health complication of inactivity [13].

The results of the current study confirmed the hypothesis that cardio respiratory fitness intervenes the relationship between PA and AP in medical female PSAU student. Every student individually accomplished her physical activity questionnaire by marking her own physical activity and academic performance. The results stated a significant correlation representing that student who more active would accomplish more results in academic achievements.

Data from previous studies revealed that the lack of physical activity in students has many health consequences in the society, as diabetes and obesity. The effect of physical activity on learning process has conflicting views but recently positive results on brain and mental health had been shown by students’ physical activity [23]. Historically, a negative relation was found between nonacademic activity and academic performance [24].  Recently, Sallis et al. did not found a correlation between physical activity and academic performance [25]; while, Trudeau and Shephard compared between students involved in physical activity and students who did not involve on academic performance and found significant improvement in academic performance after conducting physical activity [26]. On the contrary, a study by Lindner [27] and Dwyer et al. [28], found a weak correlation between the results of the students and physical exercise. Other researchers studied the effect of physical activity and revealed better health without correlation with cognitive function [29].

Enhancement of academic performance by physical activity level of the students has many mechanisms as improvement in cognitive function that affects attention and arousal [30]. Also, stimulation of  cerebral blood flow and arousal levels, release of specific neurotransmitters (noradrenaline, adrenaline, and serotonin); growing and plasticity of neurons result for brain development of derived neurotrophic factor (BDNF) related to angiogenesis and neurogenesis in the hippocampus that is a part of the brain responsible for memory; as well as vascularization and neural growth and synaptic transmission in the prefrontal cortices in those regions of the brain are tied to executive function [31-34].

More satisfaction in life for university students is achieved by reasonable level of physical activity, this is important issue for psychological well-being and markers of cardiovascular health and more satisfaction later on in future career [35]. In addition, conflicting data about the association between cognitive function and physical activity exists but it is proved that exercise enhances long-term memory [36, 37]. This is by improved quantities of factors that has effect on increasing brain plasticity and cognition [38]. Physical activity in adult during academic life seems to save a person against memory loss in older age and minimize the risk of Alzheimer disease [39, 40]. Adolescence that usually are engaged in physical activity have improved nourishment of the brain, basal metabolic rate, self-confidence, and balanced behavior; all these factors help learning process and performance [41].

 The strengths of this study are objective assessment of cardio respiratory fitness and academic performance. In contrast, physical activity was measured by self-reporting. In the future research, using direct measures of physical activity, such as accelerometry would strengthen assessment that reports the relation between physical activity and academic performance. The limitation of the study is that other factors should be considered when assessing academic performance as social, personal and motivation factors. Furthermore, only the association has been discovered in female. This is because females have high academic achievement than males. Comparing male and female students is needed to explain the differences. Also there is a need to explain which type of activity could be effective in addition to home and leisure time activities.

CONCLUSIONS

Moderate to high physical activities have strong relation with CRF and so AP; while, neither PA nor CRF was related with the AP of low physical activity. Physical activity is considered as an important factor that affects the university students, especially medical students because of high load of practical courses. Cardio respiratory fitness is affected by the level of students’ physical activity and so the student academic performance could be affected. Hoping for successful career for those students in medical field is related to their level of physical activity.

ACKNOWLEDGMENTS

This publication was supported by the Deanship of Scientific Research at Prince Sattam bin Abdulaziz University. The authors acknowledge the important contribution to this study of all participants.

REFERENCES

  1. Khurana E, Oomenn ER. Cardiovascular response to exercise in young healthy medical students IAIM, 2016; 3(7): 115-119.
  2. Guo Y, Zhou AQ, Gao W, Li F, Li Y, Yang JP, Zhu M, Zhang HY. Evaluation of physiological index on treadmill exercise testing of 294 healthy children in Shanghai area. Zhonghua ErKe ZaZhi., 2003; 41(5): 338-43.
  3. Biddle SJ, Asare M. Physical activity and mental health in children and adolescents: A review of reviews. British Journal of Sports Medicine 2011; 45(11), 886–895.
  4. Taylor HL, Buskirk E, Henschel A. Maximal oxygen intake as an objective measure of cardio-respiratory performance. J Appl Physiol 1955; 8:73–80.
  5. Ortega FB, Ruiz JR, Castillo MJ, Sjostrom M. Physical fitness in childhood and adolescence: a powerful marker of health. Int J Obes 2008; 32:1–11.
  6. Abdelkarim O, Ammar A, Chtourou H, Wagner M, Knisel E, Hökelmann A, Bös K. Relationship between motor and cognitive learning abilities among primary school-aged children. Alexandria Journal of Medicine, 2017; 53(4), 325–331.
  7. Donnelly JE, Hillman CH, Castelli D, Etnier JL, Lee S, Tomporowski P, Szabo-Reed AN. Physical activity, fitness, cognitive function, and academic achievement in children: A systematic review. Medicine and Science in Sports and Exercise 2016; 48(6):1197–1222.
  8. Lambourne K, Hansen DM, Szabo AN, Lee J, Herrmann SD, Donnelly JE. Indirect and direct relations between aerobic fitness, physical activity, and academic achievement in elementary school students. Mental Health and Physical Activity 2013;6(3):165–171.
  9. Lopes PC, Prado SR, Colombo P. Risk factors associated with obesity and overweight in school children. Rev Bras Enferm 2010;  63(1):73-78.
  10. Duncan GE, Li SM, Zhou X. Prevalence and trends of a metabolic syndrome phenotype among 2000 U.S adolescents, 1999. Diabetes Care 2004;27(10):2438-2443.
  11. Thøgersen-Ntoumani C, Ntoumanis N. The role of self-determined motivation in the understanding of exercise-related behaviors, cognitions and physical self-evaluations. Journal of Sports Sciences 2006; 24(4): 393–404.
  12. Salvara MI, Bognár J, Biróné NE. Elementary school physical education curriculum in Greece. Int J Phys Educ 2002; 39(3):29-37.
  13. Mohammad E, Saberi A. The relationship between body composition, anthropometry, and physical fitness in female university students. Sport Sciences 2016; 3(23): 155-158.
  14. Padilla-Moledo C, Castro-Pin˜ero, Ortega FB, Mora J, Ma´ rquez S, Sjo¨ stro¨m M, Ruiz JR. Positive health, cardiorespiratory fitness and fatness in children and adolescents. European Journal of Public Health; 22(1): 52–56.
  15. Gáldi G. Fizikaiaktivitás Magyarországonazezred fordulón. [Physical activity in Hungary at the turn of the century] Magyar Sporttud Szemle 2002; 3-4: 16-18.
  16. Booth JN, Leary SD, Joinson C, Ness AR, Tomporowski PD, Boyle JM, et al. Associations between objectively measured physical activity and academic attainment in adolescents from a UK cohort. Br J Sports Med 2014; 48:265–70.
  17. Chaddock L, Pontifex MB, Hillman CH, et al. A review of the relation of aerobic fitness and physical activity to brain structure and function in children. J Int Neuropsychol Soc 2011; 17:975–85.
  18. Lees C, Hopkins J. Effect of aerobic exercise on cognition, academic achievement, and psychosocial function in children: a systematic review of randomized control trials. Prev Chronic Dis 2013; 10:130010.
  19. Kharbanda M, Kumar GI, Shah SK. Effect of BMI and nutritional status on physical fitness index in response to short term moderate intensity exercise in sedentary young adults. International Journal of Recent Research and Technology 2014; 13(2): 298-30.
  20. Léger LA, Mercier D, Gadoury C, Lambert J. The multistage 20 metre shuttle run test for aerobic fitness. J Sports Sci 1988; 6(2):93–101.
  21. Kayani S, Kiyani T, Wang J, Luisa Zagalaz Sánchez M, Kayani S, Qurban H. Physical activity and academic performance: the mediating effect of self-esteem and depression. Sustainability 2018;10:1.
  22. Craig CL, Marshall AL, Sjorstrom M, Bauman AE, Booth ML, Ainsworth BE, Pratt M, Ekelund U, Yngve A, Sallis JF. International physical activity questionnaire: 12-country reliability and validity. Med Sci Sports Exerc 2003; 35:1381–1395.
  23. Tyson P, Wilson K, Crone D, Brailsford R, Laws K. Physical activity and mental health in a student population. J Ment Health 2010;19:492–499.
  24. Lindner KJ. The physical activity participation–academic performance relationship revisited: Perceived and actual performance and the effect of banding (academic tracking). Pediatr Exerc Sci 2002; 14:155–169.
  25. Sallis  JF, McKenzie TL, Kolody B, Lewis M, Marshall S, Rosengard P. Effects of health-related physical education on academic achievement: Project SPARK Res Q Exerc. Sport 1999; 70: 127–134.
  26. Trudeau F, Shephard RJ. Physical education, school physical activity, school sports and academic performance. Int J Behav Nutr Phys Acta 2008; 5: 10.
  27. Lindner KJ. Banding effects in physical activity participation extent and reasons therefor of Hong Kong secondaryschool pupils.   Hong Kong Journal of Sports Medicine and Sports Sciences 2001; 12:,21-33.
  28. Dwyer T, Sallis JF, Blizzard L, Lazarus R, Dean K. Relation of academic performance to physical activity and fitness in children. Pediatr Exerc Sci 2001; 13: 225–237.
  29. Strong WB, Malina RM, Blimkie CJ, Daniels SR, Dishman RK, Gutin B, Hergenroeder AC, Must A, Nixon PA, Pivarnik JM. Evidence based physical activity for school-age youth J Pediatr. 2005; 146: 732–737.
  30. Hillman CH, Erickson KI, Kramer AF. Be smart, exercise your heart: Exercise effects on brain and cognition. Nature Reviews Neuroscience 2008; 9(1): 58–65.
  31. Querid JS, Sheel AW. Regulation of cerebral blood flow during exercise. Sports Medicine 2007; 37(9): 765–782.
  32. Ploughman M. Exercise is brain food: The effects of physical activity on cognitive function. Developmental Neuro rehabilitation, 2008; 11(3): 236–240.
  33. Szuhany KL, Bugatti M, Otto MW. A meta-analytic review of the effects of exercise on brain-derived neurotrophic factor. Journal of Psychiatric Research 2015; 60: 56–64.
  34. Hassevoort KM, Khan NA, Hillman CH, Cohen NJ. Childhood markers of health behavior relate to hippocampal health, memory, and academic performance. Mind, Brain, and Education 2016; 10(3): 162–170.
  35. Diener E. Subjective well-being. The science of happiness and a proposal for a national index. Am Psychol 2000; 55:34–43.
  36. Cotman CW, Berchtold NC, Christie LA. Exercise builds brain health: Key roles of growth factor cascades and inflammation. Trends Neurosci 2007; 30:464–472.
  37. Tomporowski PD. Effects of acute bouts of exercise on cognition. Acta Psychol, 2003;112:297–324.
  38. Coles K, Tomporowski PD. Effects of acute exercise on executive processing, short-term and long-term memory. J Sports Sci 2008; 26:333–344.
  39. Andel R, et al. Physical exercise at midlife and risk of dementia three decades later: a population-based study of Swedish twins. J Gerontol Series A Biol Sci Med Sci 2008;63:62–66.
  40. Lautenschlager NT, et al. Effect of physical activity on cognitive function in older adults at risk for Alzheimer disease: A randomized trial. JAMA 2008; 300:1027–1037.                                                                                                                 
  41. Tremblay MS, Inman JW, Willms JD. The Relationship between Physical Activity, Self-Esteem, and Academic Achievement in 12-Year-Old Children. Pediatric Exercise Science 2000; 12: 312-324.

 

 

 

 

 

 

 

Table 1. Demographic data of the participants included in the study

 

Variable

LPA

(n= 33)

MPA

(n=34)

HPA

(n= 33)

P value

Age, y

20. 3 ±0.35

21. 1 ±0.37

20.9 ±0.65

0.998

Weight, kg

60.3 ±3.6

59.7 ±3.5

61.02 ±2.1

0.242

Height, cm

162.4 ±1.8

162.5 ±1.6

163.1 ± 1.5

0.176

BMI (kg/m2)

22.86 ±2.6

22.91 ±2.4

22.93 ±2.1

0.992

VO2max( mL.kg-1.min-1)

56.0± 13.6

61.0± 13.2

65.8 ±11.2

0.009

GPA

3.1±0.12

3.5±0.09

3.7±0.1

˂0.001

BMI: Body Mass Index, CRF:  Cardio Respiratory fitness evaluated by estimated VO2max, GPA:  Grade Point Average. LPA: low level physical activity, MPA: Moderate level physical activity, HPA: High level physical activity.

 

 

 

 

 

 

 

 

 

 

Table 2. Relationship between cardiorespiratory fitness, academic performance physical activity

 

LPA

MPA

HPA

P value

CRF

0.93

0.80

0.66

0.021

GPA

0.18

0.21

0.24

0.033

P value

0.09

˂0.001

˂0.001

 

CRF:  Cardio Respiratory Fitness, GPA:  Grade Point Average. LPA: low level physical activity, MPA: Moderate level physical activity, HPA: High level physical activity.

 

 

Table 3. The mediation analyses of cardio respiratory fitness between physical activity and academic performance in three different physical activity

 

Indirect effect

Bias Correction 95% CI

PM (%)

LPA

0.003 (0.049)

0.097–0.100

18.6

MPA

0.132(0.044)

0.073–0.210

47.4

HPA

0.140 (0.041)

0.074–0.231

49.2

CI: confidence interval. PM: percentage of mediation

 

Appendix 1

International Physical Activity Questionnaire Short form

  1. During the last 7 days, on how many days did you do vigorous physical activities like heavy lifting, digging, aerobics, running, fast bicycling, or fast swimming?
  2. How much time did you usually spend doing vigorous physical activities on one of those days?
  3. During the last 7 days, on how many days did you do moderate physical activities like bicycling at a regular pace; carrying light loads, and doubles tennis? Do not include walking.
  4. How much time did you usually spend doing moderate physical activities on one of those days?
  5. During the last 7 days, on how many days did you walk for at least 10 min at a time?
  6. How much time did you usually spend walking on one of those days?
  7. During the last 7 days, how much time did you usually spend sitting on a weekday?

 

 

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.