Introduction

The population of elderly individuals has been increasing in the developing countries over the last few decades. Brazil is among those countries that will contribute a substantial portion to this increase. According to the statistics of the World Health Organization (WHO)¹ as well as the Brazilian Institute of Geography and Statistics,² estimates are that between 1950 and 2030, the population of the elderly will grow by approximately 7.5% to around 15%, the same as in European countries. By 2050, the estimate is that there will be more elderly than children under the age of 15 years, ranking Brazil sixth in the world.

Aging is associated with a nonlinear decline in the osseous and muscular system due to osteopenia and sarcopenia, which will probably lead to a decrease in functional autonomy.³ This will impact directly on the cardiovascular system, being one of the several factors that predispose to chronic no communicable diseases (CNCD) associated with smoking, excessive alcohol consumption, physical inactivity, unhealthy diet, and social determinants such as; schooling, income, food and employment.⁴

The WHO estimates indicate that CNCDs are one of the greatest public health problems today, accounting for 63% of the 36 million deaths worldwide in 2008.⁵ In Brazil also, CNCDs are prevalent, accounting for 72% of all deaths in 2007, mainly circulatory diseases (31.3% of deaths), neoplasias (16.3%), and diabetes (5.2%).⁶

The aging process causes a decrease and fractionation of sleeping hours, impacting the sleep quality of the elderly and generating chronic health sequel, thereby, becoming an endemic condition in the modern society. Research has indicated that poor quality and duration of sleep are associated with worsening of cardiovascular diseases (CVD), and are related to a number of independent risk factors such as systemic arterial hypertension, diabetes mellitus, and obesity.⁷ Insomnia exerts deleterious effects on sleep modulating function, impacting on glucose metabolism, molecular mechanisms, physiological stress, immunity, and the interaction between sleep and eating.⁸ The regular practice of physical activity of mild to moderate intensity has been shown to be an important regulator of the quantity and quality of sleep, mainly in the elderly.⁹

Thus, the objective of the present study was to analyze the effects of a physical exercise program on blood markers and sleep quality in the elderly attending the health service of an Elderly clinic.

Methods

Sample

The sample consisted of 112 elderly patients with hypercholesterolemia and diabetes mellitus diagnosed clinically and controlled by hypocholesterolemic and hypoglycemic medications. All the volunteers were enrolled into the program of physical activity called “Elderly in Movement”, an institutionalized project of the clinic of the elderly of the single health service, of the city of Lauro de Freitas, Bahia, Brazil. The exclusion criteria were: a) presence of severe congestive heart or respiratory insufficiency; b) those who would attend less than 75% of the program; c) those participating in another physical activity program; and d) those less than 55 years of age.

All the subjects were informed about the study, and they provided their signed written informed consent in accordance with the resolution 466/2012 of the National Commission of Ethics in Research of the National Health Council in agreement with the ethical principles expressed in the Declaration of Helsinki (1964, restated in 1975, 1983, 1989, 1996, 2000, 2008, and 2013) of the World Medical Association. Approved by ethics committee with number partnership 69319717.0.0000.5546.

Experimental design

After the steps mentioned (figure 1), the subjects were randomly divided (by lot) into two groups: 54 subjects in the exercise group (EG) and 58 in the control group (CG). Their characteristics are described in table 1.

A digital scale of the Toledo® brand (Toledo, Brazil) was used to determine the body mass measurements with a coupled stadiometer with a capacity of 0–150 kg and an accuracy of 0.05 kg. The body mass index (BMI) (Quételet, 1835, adopted by World Health Organization (WHO), was calculated by the mathematical relation body mass (Kg)/height (m²).¹⁰

The metabolic parameters were requested by the medical professional or nurse of the clinic for the elderly following 12 h of fasting to determine the levels of total cholesterol, triglycerides, high-density lipoprotein (HDL), low-density lipoprotein (LDL), very-low-density lipoprotein (VLDL), fasting glucose, and calcium. The blood samples were collected by a laboratory technician from Lauro de Freitas Central Laboratory, Bahia, Brazil, on the scheduled days in the clinic of the Elderly.

Figure 1. Experimental design - Weekly training schedule

Table 1. Physical characteristics of the sample

The Pittsburgh Sleep Quality Index Questionnaire (PSQI) evaluates sleep quality and disturbances during a period of one month and was developed by Buysse et al.¹¹ as a standardized questionnaire, simple and well accepted by patients. The instrument consists of 19 self-report questions and five questions directed to the spouse or room companion. The last five questions are only used for clinical practice, not contributing to the overall score of the index. The 19 questions are categorized into seven components, the scores graded from zero (no difficulty) to three (severe difficulty). The components of PSQI are C1, subjective sleep quality; C2, sleep latency; C3, sleep duration; C4, usual sleep efficiency; C5, sleep disturbances; C6, sleep medication; and C7, sleep diurnal dysfunction. The sum of the values assigned to the seven components ranges from 0 to 21, with higher the score, worse the quality of sleep. A total score greater than 5 indicates that the individual is experiencing major dysfunctions in at least two components or moderate dysfunction in at least three components.

The CG performed their normal daily duties throughout the study period. The participants in this study agreed not to make any systematic changes in physical combined activity or work combined activities during the 16 weeks of the experiment until the completion of the post-test. The EG underwent 16 weeks of exercise training consisting of walking, stretching exercises, and balance exercises. The classes were held three times per week on alternate days, always at the same time and lasting 60–70 min. Each session consisted of a 5-min “fun” warm-up with low-intensity activities. The warm-up was followed by a 15-min workout of static and passive stretching, with the stimulus 10–15s at each movement. The stretching consisted of three sets involving alternating half of the body for every movement with an interval of 30 s between movements. The stretching exercise was followed by five minutes of exercises and static balances on the ground. The 15 min of resistance exercise consisted of two sets of 12 repetitions at moderate intensity using dumbbells and resistance bands. The resistance exercise was followed by 25 min of aerobic exercise consisting of a moderate-intensity walk and recovery. To control the intensity of the exercise, the OMNI-RES was used, and all personnel were properly trained and familiar with the goal of 3–5 intensity level for this study. The OMNI-RES scale presents illustrations with weight-lifting for the individual to make associations with ratings of perceived exertion.¹²

Statistical analysis

Descriptive statistics were applied with measures of central tendency (mean ± standard deviation) and the normality of the variables verified through the Shapiro-Wilk test, considering the sample size. Sphericity was ensured by the Mauchly’s test. To verify the variations in the domains, ANOVA (two way) with Bonferroni post hoc test was performed. The significance level adopted was p ≤ 0.05. In order to verify the size of the effect, the values of eta (μp2) were used, adopting low effect values (0.1 and 0.24), mean effect (0.25 and 0.39), and high effect (greater than 0.40). The program used for data processing was SPSS version 20.0.

Results

The results of the exercise and control groups in the period before and after the 16 weeks of intervention are shown in table 2.

Blood glucose, total cholesterol, and triglyceride levels showed a mean reduction of 27.47, 18.13, and 23.48 mg/dl, respectively. On the other hand, there was an increase of 8.98 mg/dl in the HDL levels, representing beneficial changes in the health condition of the studied population. However, the result was not significant, enter groups and moments.

The variables LDL, VLDL, and calcium presented significant changes when comparing the data of the post-test EG and pre-test CG with a significance of p < 0.004, p < 0.016, and p < 0.001 and effect μp2=0.77, 0.49, and 0.35, respectively.

The mean PSQI scores showed a reduction of 3.15 (p < 0.001, μp2=0.78) on comparing the post-test EG with post-test CG. The EG reduced its score keeping the same classification, while the CG showed a worsening of the score in the post-test period, and according to the classification, showed the presence of sleep disorder.

The blood kinetics (glycemia, total cholesterol, HDL, LDL, VLDL, triglyceride, calcium and quality of sleep) are shown in figure 2.

Discussion

The objective of the present study was to analyze the effects of a physical exercise program on blood markers and sleep quality in the elderly. It was observed that the EG improved in all variables, glycemia, total cholesterol, triglycerides, HDL, LDL, VLDL, calcium, and sleep, compared with the CG. A significant difference was seen in the LDL, VLDL, and calcium levels and sleep quality pre- and post-intervention.

The blood glucose levels showed a decrease after four months of intervention, although not statistically significant, demonstrating a possible increase in the effect with a longer intervention time. These findings corroborate with¹³ in that we found a reduction in the blood glucose levels as reflected by the HbA1c values (p = 0.0001) for the elderly who performed mild intensity physical exercise.

The evaluation time of the elderly (16 weeks) was an important factor in this intervention in the reduction of glycemia, corroborating with an intervention study which showed a monthly decline in HbA1c of 0.7 mmol/mol during the first six months of the intervention.¹⁴ Patients with diabetes were divided into groups that underwent gymnastics and walking for six months. A reduction in the fasting blood glucose was seen in both the groups, gymnastics (p = 0.01) and walking (p = 0.008). Also, a decrease in the insulin resistance was seen in the gymnastics (p = 0.01) and walking group (p = 0.001).¹³

Those with mean total cholesterol, triglyceride, and HDL levels of 195.59, 121.41, and 64.72 mg/dl, respectively, had the same glycemia behavior, showing a slight decrease after four months of intervention, as has been seen in other similar studies. A six month study involving moderate physical activity showed a significant reduction in the HDL (p = 0.0001), triglycerides (p = 0.49), and total cholesterol levels (p = 0.009).¹³ Patients with metabolic syndrome and deranged lipid profile who were divided into groups that performed gymnastics and walking for six months obtained a reduction in the total cholesterol (p = 0.001) and triglycerides (p = 0.001) in the former and only in the total cholesterol levels (p = 0.04) in the latter group.¹⁵ A significant reduction was also seen in the LDL (p < 0.004, μp2=0.77) and VLDL levels (p < 0.016, μp2=0.49) during the intervention period.

Other study with longer intervention time have showed the efficacy of exercise on total cholesterol (−31.86 ± 4.2 mg/dl, p = 0.012), HDL-c (−11.14 ± 0.9 mg/dl, p = 0.008), HDL (8 ± 0.9 mg/dL), triglycerides (−12.3 ± 1.0 mg/dL), and glucose (−6.9 ± 2.9 mg/dL).¹⁶ In the present study, the total and LDL cholesterol levels decreased significantly with physical training (p < 0.01). HDL, an important marker of cardiovascular disease incidence, also significantly reduced (from 3.91 ± 0.91–3.60 ± 0.74, p < 0.01) after the physical exercise program. In menopausal women who performed physical activity for 15 weeks, the triglycerides decreased (7.4%, p < 0.05) and HDL-C increased (4.6%, p < 0.05) significantly in the EG compared with that in the CG.¹⁷

A reduction was seen in the calcium levels (p < 0.004, μp2=0.35), but this remained within the acceptable values which may be associated with a calcium absorption, important for the population that has a mean age of 62 years, representing a protective effect against osteoporosis. A study in elderly women with low bone mass who performed strength exercise for four months showed a correlation between the manual muscle strength and femoral neck bone mineral density (r = 0.582, p = 0.003) and total femur BMD (r = 0.485, p = 0.01).¹⁸ Resistance training or jumping exercise is also an effective way to increase bone mineral density in men with low bone mass as shown by a randomized 12-month clinical trial.¹⁹

Regarding sleep quality, the present study showed that the regular practice of exercise by the EG was able to reduce the average PSQI score of the participants by 3.15 compared with the control. The results of the present study corroborate with that of another study²⁰ which showed that the practice of walking managed to change the classification from bad to good in the EG and observed that increased physical activity time during leisure in the EG produced positive results in relation to subjective quality of sleep (p < 0.001, μp2=0.78), complementing with the findings that the regular practice of physical activity contributes to the improvement of sleep quality.

In view of the results obtained in this study, it can be concluded that the physical exercise program, consisting of supervised walking and gymnastics with localized quadriceps muscle strengthening exercises, performed for 16 weeks at a frequency of three times a week lasting 60 min, was effective in improving the LDL and VLDL levels, and sleep quality. Also, a reduction in the glycemia, total cholesterol, and HDL values in the elderly with dyslipidemias and metabolic diseases who participated in the training was seen.

Authotship. All the authors have intellectually contributed to the development of the study, assume responsibility for its content and also agree with the definitive version of the article. Conflicts of interest. The author have no conflicts of interest to declare. Provenance and peer review. Not commissioned; externally peer reviewed. Ethical Responsabilities. Protection of individuals and animals: The authors declare that the conducted procedures met the ethical standards of the responsible committee on human experimentation of the World Medical Association and the Declaration of Helsinki. Confidentiality: The authors are responsible for following the protocols established by their respective healthcare centers for accessing data from medical records for performing this type of publication in order to conduct research/dissemination for the community. Privacy: The authors declare no patient data appear in this article.

References

1. World Health Organization (WHO). Non-communicable diseases country profiles 2011. Geneva: WHO, 2011.
2. Brazilian Institute of Statistical Geography (IBGE). Projection of population of Brazil by sex and age for the period 1980-20050. Research Directorate. Coordination of Population and Social Indicators. Rio de Janeiro: IBGE 2004.
3. Nóbrega ACL, Freitas EV, Oliveira MAB, Leitão MB, Lazzoli JK, Nahas RM. Official positioning of the Brazilian Society of Sports Medicine and the Brazilian Society of Geriatrics and Gerontology: physical activity and health in the elderly. Rev Bras Med Esp
4. Brazil. Ministry of Health. Secretariat of Health Surveillance. Vigitel Brasil 2013: Surveillance of Risk Factors and Protection for Chronic Diseases by Telephone Inquiry. Brasília: Ministry of Health 2014.
5. Zheng G, Xiong Z, Zheng X, Li J, Duan T, Qi D, et al. Subjective perceived subjective impact of Tai Chi training on physical and mental health among community older adults at risk of ischemic stroke: a qualitative study. BMC Complement Altern Med. 2017;17
6. Oliveira PF, Gadelha AB, Gauche R, Paiva FM, Bottaro M, Vianna LC, et al. Resistance training improves isokinetic strength and metabolic syndrome-related phenotypes in postmenopausal women. Clin Interv Aging. 2015;10:1299-304.
7. Araujo PAB, Sties SW, Wittkopf PG, Neto AS, Gonzáles AI, Lima DP, et al. Pittsburgh sleep quality index for use in cardiopulmonary and metabolic rehabilitation. Res Bras Med Esporte. 2015;21(6):472-5.
8. Steffens RAK, Liz CM, Viana MS, Brandt R, Oliveira LGA, Andrade A. Walking improves sleep quality and mood status in women with fibromyalgia syndrome. Rev Dor. 2011,12(4):327-31.
9. Araújo PAB. Sleep quality of participants in cardiopulmonary and metabolic rehabilitation program. Cinergis. 2015;16(2):42-7.
10. World Health Organization. Obesity: preventing and managing the global epidemic. Report of a WHO consultation, Geneva, Geneva: World Health Organization, 1998.
11. Buysse DJ, Hall ML, Strollo PJ, Kamarck TW, Owens J, Lee L, et al. Relationships between the Pittsburg Sleep Quality Index (PSQI), Epworth Sleepiness Scale (ESS), and Clinical/Polysomnographic measures in a community sample. J Clin Sleep Med. 2008;4(6):56
12. Lagally KM, Robertson RJ. Construct validity of the OMNI resistance exercise scale. J Strength Cond Res. 2006;20(2):252-6.
13. Balducci S, D’Errico V, Haxhi J, Sacchetti M, Orlando G, Cardelli P, et al. Level and correlates of physical activity and sedentary behavior in patients with type 2 diabetes: A cross-sectional analysis of the Italian Diabetes and Exercise Study_2. PLoS On
14. Moncrieft AE, Llabre MM, McCalla JR, Gutt M, Mendez AJ, Gellman MD, et al. Effects of a multicomponent life-stile intervention on weight, glycemic control, depressive symptoms, and renal function in low-income, minority patients with Type 2 Diabetes: resu
15. Verrusio W, Andreozzi P, Renzi A, Martinez A, Longo G, Musumeci M, et al. Efficacy and safety of spinning exercise in middle-aged and older adults with metabolic syndrome: randomized control trial. Ann Ist Super Sanita. 2016;52(2):295-300.
16. Engelke K, Kemmler W, Lauber D, Beeskow C, Pintag R, Kalender WA. Exercise maintains bone density at spine and hip EFOPS: a 3-year longitudinal study in early postmenopausal women. Osteoporos Int. 2006;17(1):133-42.
17. Nuri R, Kordi MR, Moghaddasi M, Rahnama N, Damirchi A, Rahmani-Nia F, et al. Effect of combination exercise training on metabolic syndrome parameters in postmenopausal women with breast cancer. J Cancer Res Ther. 2012;8(2):238-42.
18. Costa EL, Bastos Filho PS, Moura Mde S, Sousa TS, Lemos A, Pedrosa MA. Effects of a group exercise program on handgrip strength of elderly women with low bone mass. Arq Bras Endocrinol Metabol. 2012;56(5):313-8.
19. Hinton PS, Nigh P, Thyfault J. Effectiveness of resistance training or jumping-exercise to increase boné mineral density in men with low bone mass: A 12-month randomized, clinical trial. Bone. 2015;79:203-12.
20. Silverman NE, Nicklas BJ, Ryan AS. Addition of aerobic exercise to a weight loss program increases BMD, with an associated reduction in inflammation in overweight postmenopausal women. Calcif Tissue Int. 2009;84(4):257-65.

∗ Corresponding author.

E-mail-address: fjaidar@gmail.com(F. J. Aidar).

https://doi.org/10.33155/j.ramd.2019.05.009

Consejerı́a de Educación y Deporte de la Junta de Andalucı́a. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/)