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Biometrics & Biostatistics International Journal

Research Article Volume 9 Issue 4

Effect of physical exercises on anthropometric parameters, blood pressure and heart rate of young people and adults in Matola city–Mozambique

José Luís Sousa Manjate,1 Félix Salvador Chavane,2 Leonardo Lúcio Nhantumbo2

1Department of School Nutrition and Health, Provincial Education Directorate, Mozambique
2Higher School of Sport Sciences, Eduardo Mondlane University, Mozambique

Correspondence: José Luís Sousa Manjate, Department of School Nutrition and Health, Provincial Education Directorate -Maputo Province, Mozambique

Received: June 28, 2020 | Published: August 14, 2020

Citation: Manjate JLS, Chavane FS, Nhantumbo LL. Effect of physical exercises on anthropometric parameters, blood pressure and heart rate of young people and adults in Matola city–Mozambique. Biom Biostat Int J. 2020;9(4):139-144. DOI: 10.15406/bbij.2020.09.00331

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Abstract

Introduction: physical inactivity is a risk factor for chronic non-communicable diseases, causing morbidity and mortality and weight gain in the economy of nations.

Objective: to analyze the effect of combined physical exercises on anthropometric and hemodynamic parameters in young and adults people in Cidade da Matola.

Methodology: 22 subjects from 23 to 60 years old (8 female and 14 male) were randomly selected in 2017. The anthropometric assessment consisted of weight, height, BMI and waist circumference. Hemodynamic variables were evaluated with an Omron M3-HEM-7131-E tensiometer. The sample performed combined physical exercises for three consecutive months. Using SPSS, 20.0, at 95% CI, the non-parametric WILCOXON test was applied to examine the effect of physical exercises on the variables of interest.

Results: globally, weight and BMI increased over the course of the intervention, however without statistical differences, on the other hand, height, WP, SBP, DBP and HR differed statistically: P=(0.019; 0.008; 0.048; 0.006; 0.000) respectively. After analyzing the sex, only male individuals registered statistically significant differences for WP, DBP and HR: P=(0.023; 0.006; 0.000) respectively. The age range of individuals aged ≥ 36 years revealed a significant effect of the intervention on the variables WP, DBP and HR: P=(0.022; 0.042; 0.001) respectively.

Conclusions: although the sample size was small, globally, the effect of the intervention on the variables of interest was notorious, especially in Blood Pressure, Heart Rate and Waist Perimeter.

Keywords: physical exercises; overweight, obesity, heart rate and blood pressure

Introduction

In developed countries as well as in developing countries, it has been reported that physical inactivity is one of the important risk factors for the increase of cardiovascular diseases and body weight beyond the ideal among people of different age groups, especially in adult population.1‒4

There is evidence that Mozambique, a nation in progressive construction of economic sustainability, therefore in the process of development, also faces the global effects resulting from the epidemiological transition, substantiated by the decline in physical activity, resulting from the reduction of existing spaces for its practice and the increasingly shorter lifestyle for motor skills.5,6

To mitigate the harmful effects of sedentary lifestyle, the scientific literature recommends the practice of diversified physical exercises, under the scrupulous observance of recommendations inherent to suitability and specificity for each case, as being the effective, low-cost and most accessible means for anyone.1,4,6,7

This finding is based on the fact that physical exercises combined with nutritional balance influence cardiovascular health indicators, especially blood pressure and heart rate as well as anthropometric indicators, particularly in the variables that determine body mass.8‒11

Anthropometric variables, namely weight and waist circumference for height and age, are essential predictors of health or disease. In this context, Grossl, Augustemak de Lima, and Karasiak12 report that the concentration of body fat, especially abdominal fat, is a determining factor in multiple cardiovascular and metabolic disorders and is, also associated with a high risk of death.

Machado, Rodrigues, Viana, and Sampaio13 report that central obesity represents the concentration of adipose tissue in the abdominal region and has been described as the type of obesity that offers the greatest risk to health, on the other hand, highlight that it is a risk factor for cardiovascular diseases, diabetes, dyslipidemia and metabolic syndrome.

This scenario makes overweight and obesity considered a public health problem and deserving of special attention from health entities.12

Additionally, blood pressure and heart rate indicators are positively influenced by physical exercise, that is, people with lifestyle habits associated with motor skills, regardless of whether they are obese or not are healthy in terms of cardiovascular forum pathologies, which suggests that physical exercises can be a protective factor against heart disease.14

However, although studies on the subject exist worldwide, little is known about the effect of combined physical exercises on anthropometric variables, blood pressure and heart rate in the young and adult population of Africa in general and of Mozambique in particular.

This scientific “adventure” is guided by the certainty of being able to contribute in the field of rigor of knowledge and in the perspective of closing the contextual cognitive gap on the subject under study.

The objective of this essay was to analyze the effect of combined physical exercises on anthropometric parameters, blood pressure and heart rate in young people and adults in Matola City, Mozambique.

Methodology

The sample of the present study, whose data collection took place in 2017 in a cohort of 68 participants in the Project of physical exercises for health called “Healthy Heart” carried out in the city of Matola, consisting of 22 people between young people and adults of both sexes (14 male and 8 female), aged between 23 and 60 years (X±SD=38.86±9.00). Of these, 6 were under 35 years old and 16 were 36 years old.

It should be noted that for inclusion in this study, the participants authorized their participation in writing, as well as presenting the restrictions recommended by the clinical entities to the research team if they had them and complied with a battery of tests at the beginning and during the process constituted by the anthropometric assessment, blood pressure and heart rate at rest and fasting blood glucose, in order to rule out impeding pathologies for participation in the project and/or adapt physical exercises according to individual limitations.

All individuals who did not adhere to the subsequent evaluations were excluded from the study, thus determining the substantial loss of the sample. It is noteworthy that they were all previously informed about the procedures followed in the program and the use of information for the production of scientific reports.

Within the scope of the study, anthropometric variables were measured, namely body mass, waist circumference and hemodynamic variables, namely systolic and diastolic blood pressure and heart rate. All tests were carried out by a team of professionals with higher education in Physical Education and Sports Sciences, under the leadership of the main researcher, who previously administered training for this purpose.

The anthropometric assessment consisted of body mass, height and waist circumference, measured according to the procedures described by Frisancho.15

Body mass was measured using a digital scale of the G-Tech brand, properly calibrated and with a capacity of 150 kg. Before measuring the measure, participants were asked to take off their shoes and remove all accessories and heavy clothing, having stayed only with light clothes.

Then they were asked to climb on the scale with both feet resting on the platform, looking at a line on the horizon, in such a way that the weight was evenly distributed. After recording the value that appeared on the digital monitor, participants were instructed to get off the scale.

Height was measured using a WCS branded biometer with a scale ranging from 20 to 220 cm. The measurement was performed after the participants were instructed to take off their shoes and wear only light clothes.

The measurement was taken in a standing position with legs and feet parallel, weight distributed on both feet, arms relaxed at the side of the body and palms facing the body. The back was facing the wall and the head obeyed the horizontal alignment of the lower edge of the orbital opening, with the upper margin of the external auditory conductor.

Based on these measures, the body mass index was calculated by the weight ratio and the square of the height expressed in meters, to indirectly determine the body composition of the participants in the study.

To assess waist circumference, participants were asked to slightly lower their pants and lift their torso clothes, always observing the need to never be completely naked, in order to directly touch the hip area, exactly the height of the crest iliac. The subjects were also asked to stand, with their feet together and their abdomen completely relaxed.

The appraiser positioned himself in front of the appraised and placed the Sunny® non-extensible tape measure around the waist, where he measured the navel height in centimeters.

Blood pressure and heart rate were assessed 10 minutes after rest, with an Omron M3-HEM-7131-E digital tensiometer. It should be noted that the armbands were selected according to the arm size of each participant.

For all variables, measurements were taken twice and, in case of differences, the average resulting from the two measurements was considered.

The group involved in the research was submitted to a combined physical exercise program that, for the purpose of the study, lasted for three consecutive months, with a volume of 180 minutes per week divided into three training sessions (Mondays, Tuesdays and Thursdays)), plus one on each Saturday at the end of the month.

The contents of the program consisted of training the functional condition, through exercises of speed, strength, endurance, flexibility and general mobility.

The weekly physical exercise plan consisted of the following: on the first day of the week, the training was preceded by stretching and warming up guided by the instructor. Then they did 60 minutes of aerobic work, using musical cadence, with a low to moderate intensity, between 125 to 165 Bpm.

On the second day of the week, after stretching, the participants did 30 minutes of aerobic training with the intensity mentioned above, then did anaerobic training in order to tone specific muscle groups, namely the trunk, abdomen, upper and lower limbs.

The third workout of the week was covered by the first part of stretches and general warm-up, followed by 40 minutes of training of localized muscle groups and then the performance of aerobic work using rope and other means, lasting 20 minutes.

On Saturdays at the end of the month, participants were guided to a circuit of 15 kilometers of walking and slow running in the area reserved for the construction of the Citadel of Matola. Then they did stretching and playful games for relaxation.

This study follows a quasi-experimental design with a quantitative approach, as the participants were previously evaluated for anthropometric and hemodynamic parameters, subsequently submitted to a physical exercise program for 12 weeks (three months) and at the end of the process again evaluated.

Statistical analysis was performed in the Statistical Package for the Social Sciences (SPSS 20.0). After exploring the database in order to remove the outlines, descriptive statistics were expressed in average values and the respective standard deviation of the main variables under study.

To examine the effect of physical exercises on the variables of interest in the pre- and post-intervention moments, the non-parametric WILCOXON test was applied, at a 95% confidence interval.

Results

Table 1 presents the results of the comparison of the anthropometric and hemodynamic variables of the sample as a whole between the pre and post-intervention moments using the 12-week physical exercise program. As can be seen, Weight and Body Mass Index (BMI) increased throughout the intervention, however without statistical differences, on the other hand, Height, Waist Perimeter, Systolic Arterial Pressure, Diastolic Arterial Pressure and Frequency Cardiac reduced at the end of the intervention, with statistically significant differences: P=(0.019; 0.008; 0.048; 0.006; 0.000) respectively.

 

Variables

Pre-intervention (n=22)

Post-intervention (n=22)

Wilcoxon test

X±DP

Min

Max

X±DP

Min

Max

Z

P

Weight (Kg)

77.16±10.67

62.00

93.50

78.68±11.16

61.00

96.00

-0.960

0.337

Height (Cm)

1.67±0.08

1.55

1.91

1.66±0.08

1.55

1.90

-2.333

0.019

BMI (Kg / m2)

27.81±4.94

21.37

37.46

28.35±5.08

21.55

39.96

-1.001

0.316

WP (Cm)

92.74±10.97

76.00

115.50

89.69±13.73

44.50

110.40

-2.646

0.008

SBP (mmHg)

133.95±21.22

102.00

180.00

130.09±19.17

104.00

174.00

-1.974

0.048

DBP (mmHg)

83.72±13.94

63.00

116.00

81.40±13.54

62.00

110.00

-2.711

0.006

HR (Bpm)

70.68±10.29

54.00

94.00

66.59±7.60

51.00

85.00

-3.419

0.000

Table 1 Comparison of the results of the anthropometric assessment, blood pressure and heart rate in the pre and post intervention of the sample as a whole (p <0.05)

The comparison of the results between the pre and post-intervention moments using physical exercises according to sex is shown in table 2. As can be seen, for the female sex, even though the average values of Weight and BMI have shown increases when walking of the intervention and the other variables have registered a reduction in the average indicators, no change reveals differences with statistical significance.

 

Variables

Interventioned group (n=22)

Female (n=8)

Wilcoxon test

Male (n=14)

Wilcoxon test

Pre-Interv.
X±DP

Post-Interv.
X±DP

Z

P

Pré-Interv.
X±DP

Pós-Interv.
X±DP

Z

P

Weight (Kg)

75.91±9.32

77.93±11.29

-1.153

0.248

77.87±11.64

79.10±11.49

-0.235

0.813

BMI (Kg/m2)

24.57±3.14

25.19±3.48

-1.153

0.248

29.66±4.89

30.15±5.05

-0.235

0.813

WP (Cm)

86.65±8.82

81.81±16.60

-1.260

0.207

96.22±10.80

94.20±9.81

-2.261

0.023

SBP (mmHg)

128.87±11.16

127.12±12.11

-1.185

0.235

136.85±25.21

131.78±22.50

-1.610

0.107

DBP (mmHg)

79.87±7.16

78.62±9.44

-1.078

0.280

85.92±16.49

83.00±15.51

-2.746

0.006

HR (Bpm)

64.50±11.23

61.62±7.02

-1.021

0.307

74.21±8.14

69.42±6.54

-3.315

0.000

Table 2 Comparison of the results of the anthropometric assessment, blood pressure and heart rate in the moments before and after the intervention according to sex (p <0.05)

On the other hand, among male participants, the mean values of Waist Perimeter, Diastolic Blood Pressure and Heart Rate decreased after three months of intervention, with statistical significance: P=(0.023; 0.006; 0.000) respectively.

The comparison of the effect of the physical exercise program according to the age group, in the two moments is shown in table 3. As can be seen, among young people, although there were no statistically significant differences, the trend of the mean values of all variables was to reduce over the 12 weeks of intervention.

 

Variables

Interventioned group (n=22)

≤35 years (n=6)

Wilcoxon test

≥36 years (n=16)

Wilcoxon teste

Pre-Interv.
X±DP

Post-Interv.
X±DP

Z

P

Pre-Interv.
X±DP

Post-Interv.
X±DP

Z

P

Weight (Kg)

70.33±10.43

70.00±9.44

-0.677

0.498

79.72±9.87

81.93±10.16

-1.364

0.172

BMI (Kg/m2)

24.50±3.82

24.38±3.48

-0.677

0.498

29.05±4.82

29.83±4.84

-1.362

0.172

WP (Cm)

84.21±11.14

77.31±18.12

-1.572

0.115

95.93±9.34

94.33±8.39

-2.275

0.022

SBP (mmHg)

131.00±11.83

125.00±15.09

-1.095

0.273

136.68±27.88

132.00±20.60

-1.876

0.060

DBP (mmHg)

79.50±9.64

75.83±10.22

-1.897

0.057

86.31±17.68

83.50±14.31

-2.029

0.042

HR (Bpm)

65.00±9.25

62.50±6.62

-1.510

0.130

72.81±10.10

68.12±7.55

-3.144

0.001

Table 3 Comparison of the results of the anthropometric assessment, blood pressure and heart rate in the moments before and after the intervention according to the age group (p <0.05)

However, the age group of individuals aged ≥ 36 years, therefore of adults, revealed a significant effect of the intervention on the variables Waist Perimeter, Diastolic Blood Pressure and Heart Rate: P=(0.022; 0.042; 0.001) respectively.

Discussion

Although the sample of the present study was reduced, the results revealed a marginal increase in weight and body mass index for the entire sample over the three months of intervention, however without statistical significance. Additionally, height, waist circumference and hemodynamic indicators pointed to a reduction in mean values, with statistical significance.

This scenario corroborates, in part, with the results found in the study by Lopes et al.,16 in which they evaluated the effect of a physical exercise program with and without nutritional guidance on anthropometric and metabolic variables of young people. In this study, after the intervention, both groups did not register statistically significant differences for weight, body mass index and waist circumference, except for height, coinciding in this aspect with the present study.

It is important to highlight that the behavior of the waist circumference recorded in the study by Lopes et al.,16 differs with the finding in this trial.

The average values found in this investigation reveal that, for the sample as a whole, there were statistically significant differences.

This scenario is also illustrated in a study carried out with a group of people with an average age of 33 years, who after a period of nutritional guidance and physical exercise revealed a reduction in blood pressure and heart rate indicators, with greater emphasis on the values of diastolic blood pressure.17

Another study carried out with the aim of verifying the effect of aerobic physical exercises on people at cardiovascular risk revealed that anthropometric parameters, namely weight, body mass index and waist circumference, as well as hemodynamics, especially blood pressure of the sample reduced marginally, but without statistically significant differences.3

The marginal effect of physical exercises on anthropometric and hemodynamic indicators revealed in the study by Viana et al.3 can be explained by the fact that only an aerobic exercise program was applied.

Still in this context, studies have recommended the use of a combined physical exercise plan, namely aerobic and anaerobic ones with a focus on localized exercises so that chronic physiological adaptations in anthropometric and hemodynamic parameters can be established.18,19

Indeed, the outcomes found here can be justified, in part, by the use of an intervention program that combined a protocol of aerobic and anaerobic activities, with predominance of exercises located in the abdominal fat mass.

In another analysis, the fact that the individuals in the present study superficially gained body weight after three months, but with a significant reduction in the average values of waist circumference may be justified by the reason that the muscle toning exercises have promoted an increase in bone and muscle density on the one hand, but it can also be considered that the lack of control and / or monitoring of the participants’ diet was at the origin of the weight gain of the weight.20,21

When comparing the intervention using combined physical exercises according to sex, the female participants did not register any effect; however the male gender showed statistically significant differences for waist circumference, diastolic blood pressure and heart rate.

These results, especially those related to anthropometric indicators, differ from those found in a study carried out with a group of postmenopausal women, who after two months of intervention using physical exercises registered a significant decrease in body mass.22

Following the same pattern, the study by Rocca et al.,23 carried out with women between the ages of 25 and 50, with the aim of evaluating the effect of a physical exercise program for weight loss found results equally different, from the point of view of anthropometric parameters, from those described in this research. It should be noted that the similarities in these indicators were only recorded for the waist circumference.

On the other hand, Gomes24 reveals in his dissertation that both men and women showed significant differences in hemodynamic parameters, after the intervention using aquatic physical exercises. These results are similar to those found in this research, only for males, in diastolic blood pressure and heart rate.

The comparison of the effect of the combined physical exercise program according to the age groups, between young people and adults revealed significant differences between the pre and post-intervention moments in individuals aged 36 years or over, with greater emphasis on the perimeter waist, heart rate and diastolic blood pressure.

However, even though there were differences between the two groups in the present study, the reference literature has highlighted that the use of combined physical exercises results in changes in the chronic adaptation of body composition and hemodynamic indicators, both for young people, adults and elderly.22,25,26

Conclusions

The sample of the present study consisted of 22 people, therefore relatively small, however it was possible to reach the following conclusions:

The combined physical exercise program promoted chronic adaptations among research participants, with greater emphasis on hemodynamic indicators;

Although sex and age were decisive, overall the effect of the intervention on the variables studied was notorious, especially in the indicators of diastolic blood pressure, heart rate and waist circumference, which are curiously predictors of cardiovascular forum pathologies;

The results of this research suggest the importance of using combined physical exercises for therapeutic purposes, especially against cardiovascular forum pathologies.

Acknowledgments

We thank all participants in the healthy heart program, which takes place in the city of Matola, Escola Maria Ana Mogas and the School Board for authorizing the use of its facilities.

Conflicts of interest

We declare that there is no conflict of interest.

References

  1. Brand C, Gabrieler LC, Roth MA, et al. Effect of a Regular Physical Exercise Program on C‒Reactive Protein in Individuals at Risk for Cardiovascular Diseases. Rev Bras Cardiol. 2013;26(6):435‒441.
  2. Lee YH, Song YW, Kim HS, et al. The Effects of an Exercise Program on Anthropometric, Metabolic, and Cardiovascular Parameters in Obese Children. Korean Circ J. 2010;40(4):179‒184.
  3. Viana PADdC, Petto J, Santos ACNd, et al. Effect of Resistance Training on Cardiovascular Parameters of Normotensive and Hypertensive Adults. Rev Bras Cardiol. 2014;27(3):172‒179.
  4. Zaros PR, Pires CE, Bacci M, et al. Effect of 6‒months of physical exercise on the nitrate/nitrite levels in hypertensive postmenopausal women. BMC Womens Health. 2009;9:17.
  5. Nhantumbo L, Leandro C, Tchamo M. Physical fitness and health of children and young mozambicans: systematic review in the time horizon from 1994 to 2015. Rev cient UEM: Ser biomedical public health. 2016;1(2):33‒53.
  6. Prista A. Sedentary lifestyle, urbanization and epidemiological transition. Rev Cient UEM Ser: Biomedical Sciences and Public Health. 2012;1(0):28‒38.
  7. Costa PRdF, Assis AMO, Silva MdCMd, et al. Change in anthropometric parameters: the influence of a nutritional intervention program and physical exercise in adult women. Cad Saúde Pública. 2009;25(8):1763‒1773.
  8. Matsudo SM, Keihan V, Matsudo R, et al. Impact of aging on anthropometric, neuromotor and metabolic variables of physical fitness. Rev Bras Ciêne Mov. 2000;8(4).
  9. Monego ET, Jardim PCBV. Risk Determinants for Cardiovascular Diseases in Schoolchildren. Brazilian Archives of Cardiology. 2006;87(1).
  10. Sembulingam PKS, Ilango S. Rate Pressure Product as a Determinant of Physical Fitness in Normal Young Adults. IOSR Journal of Dental and Medical Sciences. 2015;14(4):8‒12.
  11. Stewart KJC, Turner BA, Lim K, et al. Exercise and risk factors associated with metabolic syndrome in older adults. American Journal of Preventive Medicine. 2005;28(1):9‒18.
  12. Grossl T, Augustemak de Lima LR, Karasiak FC. Relationship between body fat and anthropometric indicators in adults attending gym. Motricidade. 2010;6(2):35‒45.
  13. Machado SP, Rodrigues DGC, Viana KDAL, et al. Correlation  between  body  mass  index  and  anthropometric  indexes  of  abdominal  obesity  in  patients  with  type  2  diabetes  mellitus. Revista Brasileira em Promoção da Saúde. 2012;24(4):512‒520.
  14. Pitanga CPS, Oliveira RJ, Lessa I, et al. Physical activity as a protective factor for cardiovascular comorbidities in obese women. Brazilian Journal of Cineanthropometry and Human Performance. 2010;324‒330.
  15. Frisancho AR. Anthropometric Standards An Interactive Nutritional Reference of Body Size and Body Composition for Children and Adults by (Volume 1). United States of America: University of Michigan Press. 2008.
  16. Lopes Md FA, Bento PCB, Lazzaroto L, et al. Effects of water walking on anthropometric and metabolic aspects in obese youth. Revista Brasileira de Cineantropometria e Desempenho Humano. 2015;17(2):145.
  17. Barbato KBG, Martins Rd CV, Rodrigues Md LG, et al. Effects of Weight Loss of More than 5% on Hemodynamic, Metabolic and Neuroendocrine Profiles of Obese Grade I. Arquivos Brasileiros de Cardiologia. 2006;87(1).
  18. Nogueira IC, Santos ZMd SA, Mont´Alverne DGB, et al. Effects of physical exercise on the control of arterial hypertension in the elderly: a systematic review. Rev Bras de Geriatria Gerontol. 2012;15(3):587‒601.
  19. Sabia RV, dos Santos JE, Ribeiro RPP. Effect of physical activity associated with dietary orientation in obese adolescents: comparison between aerobic and anaerobic exercise. Rev Bras Med Esporte. 2004;10(5).
  20. Ferreira S, Tinoco ALA, Panato E, et al. Ethiological aspects and the role of physical exercise in the prevention and control of obesity. Revista de Educação Física. 2006;133:15‒24.
  21. Silva LA, Pereira DAdA, Priore SE. Effect of combined physical exercise on anthropometric and biochemical indicators of cardio metabolic risk in university students. Revista Brasileira de Nutriçao Esportiva. 2019;13(77):43‒53.
  22. Silva LA, Pereira DAdA, Priore SE. Effect of combined physical exercise on anthropometric and biochemical indicators of cardio metabolic risk in university students. Revista Brasileira de Nutriçao Esportiva. 2019;13(77):43‒53.
  23. Rocca SVdS, Tirapegui J, Melo CMd, et al. Effect of physical exercise on risk factors for chronic diseases in obese women. Brazilian Journal of Pharmaceutical Sciences. 2008;44(2):185‒192.
  24. Gomes SG. Water‒based exercise enhances the post‒exercise hypotension response for up to 24 hours. (Mestrado Dissertação), Istituto de Ciências Exactas e Biológicas, Ouro Preto, MG. 2016.  
  25. Matias LAdS. Acute and chronic effects of combined exercise on ambulatory blood pressure in postmenopausal hypertensive women. (Master in Health Sciences), Federal University of Uberlândia. 2018. 
  26. Rocha MC, Stabenow WR, Jacobino AG, et al. Combined physical training improved the lipid profile and reduced blood pressure in elderly women with chronic non‒communicable diseases. Revista Corpoconsciência. 2016;20(1):38‒45.
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