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Revista de la Facultad de Medicina Humana
Print version ISSN 1814-5469On-line version ISSN 2308-0531
Rev. Fac. Med. Hum. vol.22 no.4 Lima Oct./Dec. 2022 Epub Oct 12, 2022
http://dx.doi.org/10.25176/rfmh.v22i4.4892
Original article
Effects of high intensity-interval training on cardiovascular risk, body mass index and metabolic markers in healthcare workers
1Universidad de Montemorelos, México.
2Escuela mexicana de medicina de estilo de vida
Objectives:
The obesity epidemic in Mexico has caused a health crisis. This places great importance in the identification of useful methods to manage it across all populations. In this present study we evaluate the effect of high intensity interval training in healthcare workers.
Methods:
An intervention was carried out that consisted in 60 sessions of high intensity interval training during a 12 week period aimed at health care workers working at the General Hospital in Montemorelos, Mexico. Variables regarding body composition, cholesterol and arterial blood pressure were evaluated for each individual both before and after the intervention. Pearson coefficients were estimated between the initial and final values.
Results:
8 participants were included, 55.6% men aged 32.8 ± 10.9 years with a BMI of 31.69 ± 2.9. A statistically significant difference was found between the initial and final values of weight, BMI, total cholesterol, mean arterial blood pressure, and cardiovascular risk at 10 years.
Conclusions:
These results reveal a significant decrease in our variables related to obesity in healthcare workers after a HIIT intervention in an uncontrolled setting. We recommend the further implementation of similar studies with greater sample size, intensity and duration to target obesity which is the root cause of chronic non-communicable diseases. Further studies are required to confirm the effect of this intervention in the prevention, treatment of obesity in health care workers and to describe its long term effects.
Keywords: WPhysical Exercise; Overweight; Obesity. (Source: MeSH NLM).
INTRODUCTION
The World Health Organization (WHO) defines obesity as an excessive accumulation of fat that is detrimental to health. In addition, it recognizes this as a health problem that constitutes a global epidemic1. Worldwide, the prevalence of obesity has tripled between 1975 and 2016, reaching figures of more than 1.9 billion adults2. Mexico is one of the two countries with the highest prevalence of obesity in the world. In 2016, the combined prevalence of overweight and obesity was an alarming 72.5%3. Obesity is responsible for more than 200,000 deaths annually in this country, of which more than 80,000 are due to diabetes, and more than 100,000 to cardiovascular diseases4,5. These figures represent a constant and significant burden for the health sector and Mexicans since their effects negatively impact morbidity, mortality, and the economy.
Health workers, in particular, are exposed to a high risk of being overweight and obese due to their demanding job responsibilities, and therefore, in general, they practice an unhealthy lifestyle6. For this reason, the prevalence of obesity in this particular population is higher than in the general population in Mexico7. The World Obesity Federation has rightly identified and emphasized the need for immediate action for the prevention and control of obesity8. For this reason, the identification of useful tools in the fight against obesity becomes critically important.
In 2013 Donnelly demonstrated through his midwestern exercise test that integrating aerobic exercise exclusively into his participants' habits resulted in a significant decrease in body mass index (BMI)9. Later, in 2017, Weiss and his collaborators found that the benefits of aerobic physical activity, in addition to lowering BMI, included the preservation of fat-free mass and a significant improvement in the efficiency of maximum oxygen consumption10.
Although recent studies have shown that high-intensity interval training (HIIT) offers a beneficial effect superior to that of aerobic exercise to be effective in losing body fat11)(12, this phenomenon has not been studied in health workers. For this reason, the objective of this work is to identify the effect of a HIIT regimen on health workers.
METHODS
Population and sample
Using a non-probabilistic convenience sampling, all health workers between 20 and 50 years of age with morning, evening, or night work shifts were invited to participate. Health workers with a history of high-risk cardiovascular disease, symptoms of infection at the time of the study, pregnancy or lactation, and those using lipid-lowering or antihypertensive drugs were excluded.
Variables, procedures, and instruments
The intervention consisted of 60 sessions of 30 minutes of HIIT for 12 weeks aimed at health workers of the General Hospital of Montemorelos, with the aim of promoting increased physical activity. Each session was presented by a certified trainer and consisted of a warm-up and circuits of 5 muscular strengthening and HIIT-type cardiovascular resistance exercises repeated for 5 cycles. Each participant sent audiovisual evidence of each training to the research team as a requirement for the final evaluation. The content and methodology of this intervention are described in Annex A.
Data collection, laboratory taking, and processing of each participant were carried out on 2 occasions, before starting the intervention and after it. An initial clinical interview was obtained to capture data including medication use, history of cardiovascular disease, and measurement of vital signs.
The anthropometric data of each participant was measured using a calibrated OMRON HBF-214 scale and height with a stadiometer. The Body Mass Index13was calculated using formula 1:
BMI= Weight in (Kg)/Height in (cm²)1
Blood samples was obtained from each participant after 8-12 hours of fasting and processed in the certified laboratory of the Hospital General de Montemorelos. Total and HDL cholesterol concentrations were measured with colorimetric assays. The Cholesterol/HDL ratio was calculated using formula 214:
HDL Cholesterol Ratio=Total Cholesterol (mg/dl)/HDL Cholesterol (mg/dl)2
Blood pressure was measured with a calibrated Welch Allyn DS4411 aneroid sphygmomanometer. Systolic blood pressure was identified by the first phase of the Korotkoff sounds, while diastolic pressure was identified by its 5th phase. The mean arterial pressure was calculated using formula 315:
MAP =DBP - 1/3 (SBP-DBP)3
Donde:
MAP = Mean arterial pressure in mmHg
SBP =Systolic Blood Pressure in mmHg
DPB =Diastolic Blood Pressure in mmHg
The cardiovascular risk - cholesterol based on the framingham heart study16was obtained using the calculator of the Instituto Mexicano de Seguro Social17.
Statistic analysis
The data was collected and organized in a database using the Microsoft Office Excel® 2019 program to later process them with the SPSS® Statistics 25 statistical package for descriptive and analytical statistical analysis. The distribution of the variables was determined using the Shapiro-Wilk test (Table 2). Subsequently, correlations were made between the pre and post results of each variable using the Student's t statistical tests for paired samples and the Wilcoxon test to estimate Pearson's correlation coefficients.
RESULTS
A participation of 8 participants with an average age of 32.8 years was obtained. The general characteristics of the study population are shown in Table 1. The cardiovascular risk results were 2.3 ± 2. The initial and final values with standard deviation and the Pearson correlation coefficients between the initial values and the values are presented. results of each variable in Table 3. A statistically significant difference was found between the initial and final values of weight, BMI, systolic blood pressure, diastolic blood pressure, mean blood pressure, total cholesterol and cardiovascular risk at 10 years.
Characteristic | Result |
Age(in years) | 32,8 ± 10,9 |
Smoking | Negative 100%(8) |
Diabetes Mellitus | Negative 100%(8) |
Workshift | Morning 100%(8) |
Size(Centimeters) | 163 ± 10,2 |
Weight(Kilograms) | 84,1 ± 9,9 |
Body Mass Index | 31,69 ± 2,9 |
Variable | P-value |
Weight1 | 0,403 |
Weight2 | 0,325 |
BMI 1 | 0,647 |
BMI2 | 0,744 |
SBP 1 | 0,555 |
SBP 2 | 0,037 |
DBP 1 | 0,357 |
DBP 2 | 0,142 |
MAP 1 | 0,420 |
MAP 2 | 0,150 |
Col 1 | 0,334 |
Col 2 | 0,690 |
HDL 1 | 0,994 |
HDL 2 | 0,552 |
C/HDL 1 | 0,240 |
C/HDL 2 | 0,473 |
R10 1 | 0,001 |
R10 2 | 0,003 |
1; Initial value, 2; Final Value, Weight; Body weight in Kg, BMI; Body mass index, Col; mg/dl of blood cholesterol, HDL; High-density lipoprotein, SBP; Systolic blood pressure, DBP; Diastolic blood pressure, MAP; Mean arterial pressure, C/HDL; HDL Cholesterol Ratio, R10; Cardiovascular risk at 10 years.
Variable | Mean and Standard Deviation | P-value |
Weight 1 | 84,14 ± 9.9 | 0.027 |
Weight 2 | 82,45 ± 9.8 | |
BMI 1 | 31,69 ± 2.92 | 0.033 |
BMI 2 | 31,07 ± 3 | |
SBP 1 | 121,2 ± 12,5 | 0,006 |
SBP 2 | 111,3 ± 6,4 | |
DBP 1 | 81,750 ± 6,7 | 0,033 |
DBP 2 | 75,8 ± 8,3 | |
MAP 1 | 94,9 ± 8,5 | 0,008 |
MAP 2 | 87,6 ± 6,9 | |
Col1 | 163,4 ± 33,2 | 0,010 |
Col2 | 148,8 ± 30,6 | |
HDL1 | 42,5 ± 9,4 | 0,740 |
HDL2 | 43,1 ± 12,3 | |
C/HDL1 | 3,99 ± 1,12 | 0,017 |
C/HDL2 | 3,62 ± 1,03 | |
R101 | 2,3 ± 2 | 0,059 |
R102 | 1,7 ± 2,4 |
1; Initial value, 2; Final Value, Weight; Body weight in Kg, BMI; Body mass index, Col; mg/dl of blood cholesterol, HDL; High-density lipoprotein, SBP; Systolic blood pressure, DBP; Diastolic blood pressure, MAP; Mean arterial pressure, C/HDL; HDL Cholesterol Ratio, R10; Cardiovascular risk at 10 years.
DISCUSSION
To our knowledge, this study is among the first to assess the effect of an exclusive HIIT intervention in healthcare workers. Our results show a significant improvement in anthropometric values, metabolic indicators and blood pressure figures. HIIT interventions with a duration of more than 10 weeks have been shown to be effective for weight loss and improvement of body composition data18, for this reason multiple studies19-21 have postulated it as a useful tool to decrease body fat percentage and BMI in overweight and obese populations. Our results are in line with this position given that after a 12-week HIIT intervention, our participants reported a statistically significant decrease in obesity measurements, with BMI -0.62 (P Value 0.033) and total body weight -1.69kg. (P-value 0.027). Causal mechanisms of HIIT-induced fat loss include the generation of catecholamines that increase the rate of fat oxidation and fat release from visceral fat stores, decrease post-exercise appetite, and increase body oxygen consumption. excess after exercise resulting in increased fat loss20,22.
Added to these results, a significant decrease in MAP(-7.3mmHg) SBP(-9.9mmHg) and DBP(-5.95mmHg) was found. These results are very similar to the meta-analysis carried out by Cornelissen23where an average decrease in SBP(-10.9mm Hg) and DBP(-6.4mm Hg) was recorded. The improvement in blood pressure induced by exercise is explained by a decrease in total resistance to both peripheral and central blood flow24. Physiological mechanisms implicated in this improvement include improved endothelial and homeostatic function in resistance vessels, decreased oxidative stress, and adequate autonomic regulation25. It is feasible to attribute these positive endothelial adaptations to the higher vascular shear stress on endothelial cells induced by HIIT intensity. This improvement is clinically relevant given that arterial hypertension is one of the modifiable risk factors for cardiovascular diseases26.
In this context, another important result to highlight was a significant improvement in blood lipids. Total cholesterol had an average decrease of -14.6 mg/dl (P value 0.010) while an average increase of +0.6 mg/dl of HDL-cholesterol was recorded, accompanied by a consequent decrease in the cholesterol/HDL ratio of -0.37(P-value 0.017). These results agree with the meta-analysis carried out by Kelley27demonstrating the lipid-lowering efficacy of HIIT in the obese population. The decrease in total cholesterol and increase in HDL levels after HIIT sessions has been related to its modulating effect on the activity of cholesterol ester transfer protein and lecithin cholesterol acyl transferase28,29.
Futhermore to being an indicator of metabolic health, the cholesterol/HDL ratio is considered an indicator of cardiovascular risk30. The clear improvement in the initial and final values of this index suggests a trend of improvement and its possible usefulness in the prevention of these cardiovascular diseases. .
Finally, although our population was within the range of low cardiovascular risk, a 0.6% decrease in cardiovascular risk was recorded at 10 years in Framingham. This method of estimating cardiovascular risk has proven to be a reliable indicator of mortality in multiple populations31,32. Since the calculation of this considers non-modifiable variables and only 2 modifiable (blood pressure and smoking)33, it is likely that the generalized decrease in blood pressure is responsible for these results. Future studies will be necessary to confirm these findings and study the effect of HIIT on cardiovascular health.
A particular strength of this study is the duration of the intervention, which made it possible to record medium-term changes in the participants. In addition, the evaluation of the lipid profile allowed to describe the changes in cardiovascular and metabolic risk of each participant. We acknowledge that our limitations include a small sample size and the absence of a quantifiable measure of habits related to body weight change. However, our method is helpful in documenting significant effects even in an uncontrolled setting.
CONCLUSION
In this particular manuscript, we aim to describe the effect of HIIT on metabolic and anthropological indicators and blood pressure figures in health workers. Our HIIT intervention significantly improved the lipid profile anthropometric values, and systolic and diastolic pressure figures. The results of this study could be of important contribution in the formulation of interventions aimed at the prevention and treatment of obesity in health workers and, as a consequence, reduce the diseases related to it. Furthermore, these results lay the groundwork for future research that should include a large population, controlled intervention and focus on describing the long-term effects of HIIT on healthcare workers.
Thanks
To Carlos Alberto Gracida, Dr. Cesar Sandoval Leal and Dr. Victor Torres for their selfless help in the implementation process of this study.
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8Article published by the Journal of the faculty of Human Medicine of the Ricardo Palma University. It is an open access article, distributed under the terms of the Creatvie Commons license: Creative Commons Attribution 4.0 International, CC BY 4.0(https://creativecommons.org/licenses/by/1.0/), that allows non-commercial use, distribution and reproduction in any medium, provided that the original work is duly cited. For commercial use, please contact revista.medicina@urp.edu.pe.
Received: April 12, 2022; Accepted: July 05, 2022