ABSTRACT
Introduction: Taurine plays an important role in metabolism and can positively influence body composition, since it is believed that in appropriate concentrations this amino acid (AA) can reduce perceived exertion, thereby delaying the onset of fatigue; however, the effect of this AA combined with concurrent training in postmenopausal women is unknown.
Objective: To analyze the effects of concurrent training (aerobic+resistance) and taurine supplementation on the metabolic profile of postmenopausal women.
Methods: Forty-three postmenopausal women were randomly divided into the following groups: Control (C [N=13]), Taurine (T [N = 8]), Taurine+Exercise (TE [N=13]), and Placebo+Exercise (E [N=9]). The supplemented groups received capsules corresponding to a daily taurine intake of 1.5 g. Concurrent training (CT) took place three times a week and consisted of 50 minutes of resistance training and 30 minutes of aerobic training. Body composition was assessed using DXA, in addition to biochemical profile analysis: triglycerides, total cholesterol, low-density lipoprotein cholesterol and high-density lipoprotein cholesterol. The intervention period lasted for eight weeks. Statistical significance was set at 5%.
Results: The TE group presented a statistical reduction in terms of relative change in the percentage of total body fat (%) (−4.1±3.0) and trunk fat (%) (−4.4±3.9), with greater lean body mass (kg) gain (3.9±2.5) when compared to groups C (0.3±3.7, p=0.005; 0.8±4.3, p=0.024; −1.1±3.1, p<0.001; respectively) and T (1.2±3.4, p=0.004; 1.6±5.4, p=0.023; −1.2±2.9; p=0.002; respectively). The TE group presented a greater percentage reduction of total cholesterol (−5.8±7.1 mg/dl) when compared to group T (11.5±19.1 mg/dl). The TE group presented a significant decrease in LDL-c (−13.6±9.2 mg/dl) compared to groups C (3.5±13.9 mg/dl, p=0.014) and T (9.9±24.3 mg/dl, p=0.027).
Conclusion: The combination of concurrent training and taurine supplementation promoted a reduction in total cholesterol and LDL-c levels in postmenopausal women. Level of Evidence I; Study type: Randomized clinical study.
Keywords: Body composition; Resistance training; Metabolism
RESUMO
Introdução: A taurina desempenha um papel importante no metabolismo e pode influenciar positivamente a composição corporal, uma vez que, na concentração apropriada, este aminoácido pode diminuir a percepção de esforço e retardar o aparecimento da fadiga; entretanto, o efeito desse aminoácido combinado com o treinamento concorrente (TC) é desconhecido em mulheres pós-menopausa.
Objetivo: Analisar os efeitos do TC (aeróbico+resistência) e da suplementação com taurina nesse perfil metabólico de mulheres pós menopausa.
Métodos: Foram avaliadas 43 mulheres pós-menopausa que foram divididas randomicamente nos seguintes grupos: Controle (C [N = 13]), Taurina (T [N = 8]), Taurina+Exercício (TE [N = 13]) e Placebo+Exercício (E [N = 9]). Os grupos suplementados com taurina receberam cápsulas e consumiram 1,5 gramas/dia dessa substância. O TC aconteceu três vezes por semana (50 minutos de treinamento resistido e 30 minutos de treinamento aeróbico). A avaliação da composição corporal foi realizada por meio do DXA; além disso, foram analisados o perfil bioquímico com dosagem de triglicérides, colesterol total (CT), colesterol de lipoproteína de baixa densidade (LDL-c) e colesterol de lipoproteína de alta densidade (HDL-c). A intervenção teve duração de oito semanas.
Resultados: O grupo TE apresentou redução percentual significativa da gordura corporal total (−4,1 ± 3,0) e gordura de tronco (−4,4 ± 3,9) e maiores ganhos da massa corporal magra (3,9 ± 2,5) em comparação ao grupo C (0,3 ± 3,7, p = 0,005; 0,8 ± 4,3, p = 0,024; −1,1 ± 3,1, p <0,001; respectivamente) e ao grupo T (1,2 ± 3,4, p = 0,004; 1,6 ± 5,4, p = 0,023; −1,2 ± 2,9; p = 0,002; respectivamente). O grupo TE apresentou maiores reduções do CT (−5,8 ± 7,1 mg/dl) em comparação ao grupo T (11,5 ± 19,1 mg/dl). O grupo TE apresentou significativa redução do LDL-c (−13,6 ± 9,2 mg/dl) em comparação ao grupo C (3,5 ± 13,9 mg/dl, p = 0,014) e ao grupo T (9,9 ± 24,3 mg/dl, p = 0,027).
Conclusão: A associação TC e suplementação com taurina promoveu redução dos níveis de colesterol total e LDL-c em mulheres pós-menopausa. Nível de Evidência I; Tipo de Estudo: Estudo clínico randomizado.
Descritores: Composição corporal; Treinamento de resistência; Metabolismo
RESUMEN
Introducción: La taurina desempeña un papel importante en el metabolismo y puede influenciar positivamente la composición corporal, ya que en la concentración apropiada este aminoácido puede disminuir la percepción de esfuerzo y retrasar la aparición de la fatiga; sin embargo, el efecto de este aminoácido combinado con el entrenamiento concurrente (EC) es desconocido en mujeres posmenopáusicas.
Objetivo: Analizar los efectos del EC (aeróbico+resistencia) y de la suplementación con taurina en este perfil metabólico de mujeres posmenopáusicas.
Métodos: Se evaluaron 43 mujeres posmenopáusicas que se dividieron aleatoriamente en los siguientes grupos: Control (C [N = 13]), Taurina (T [N = 8]), Taurina+Ejercicio (TE [N = 13]), Placebo+Ejercicio (E [N = 9]). Los grupos suplementados con taurina recibieron 1,5 gramos/día de esta sustancia. El EC ocurrió tres veces por semana (50 minutos de entrenamiento resistido y 30 minutos de entrenamiento aeróbico). La composición corporal fue realizada por medio del DXA; además, se analizaron el perfil bioquímico con dosificaciones de triglicéridos, colesterol total (CT), colesterol de lipoproteína de baja densidad (LDL-c) y colesterol de lipoproteína de alta densidad (HDL-c). La intervención tuvo duración de ocho semanas.
Resultados: El grupo TE presentó reducción porcentual significativa de la grasa corporal total (−4,1 ± 3,0) y grasa del tronco (−4,4 ± 3,9) y mayores ganancias de masa corporal magra (3,9 ± 2,5) en comparación al Grupo C (0,3 ± 3,7, p = 0,005, 0,8 ± 4,3, p = 0,024, −1,1 ± 3,1, p <0,001, respectivamente) y al Grupo T (1,2 ± 3,4, p = 0,004; 1,6 ± 5,4, p = 0,023; −1,2 ± 2,9; p = 0,002; respectivamente). El Grupo TE presentó mayores reducciones del CT (−5,8 ± 7,1 mg/dl) en comparación con el Grupo T (11,5 ± 19,1 mg/dl). El Grupo TE presentó una significativa reducción del LDL-c (−13,6 ± 9,2 mg/dl) en comparación con el Grupo C (3,5 ± 13,9 mg / dl, p = 0,014) y el Grupo T (9,9 ± 24,3 mg / dl, p = 0,027).
Conclusión: La asociación de EC y suplementación con taurina promovió reducción de los niveles de colesterol total y LDL-c en mujeres posmenopáusicas. Nivel de evidencia I; Tipo de Estudio: Estudio clínico aleatorizado.
Descriptores: Composición corporal; Entrenamiento de resistencia; Metabolismo
INTRODUCTION
Menopause is characterized by reduced estrogen production and the interruption of the menstrual cycle, resulting in the end of ovarian function, and is recognized retrospectively after a year of amenorrhea.1 In addition to the impact on the reproductive system, menopause may also be responsible for significant changes in body composition, since, after this event, many women experience weight gain and adiposity, particularly in their core 2 and, thus, are more likely to develop an atherogenic lipid profile and heart disease.3
Concurrent training (aerobic + resistance) can minimize the effects of aging on body composition and the metabolism. This stems from an increase in lean mass and a reduction in body fat,4 in addition to increasing insulin sensitivity and energy expenditure, both during and after exercise,5 improving lipid metabolism. 6
Some supplements such as amino acids (AA), have been used as additional strategies to enhance the results in health and quality of life from exercise programs. Among these AAs, is taurine (2-aminoethanesulfonic acid) which, in humans, is synthesized in the liver and considered a semi-essential AA. The quantity produced by the organism is low and it is therefore recommended that this be supplemented through diet, such as meat and seafood.7
Studies have suggested that taurine plays an important role in metabolism 8 and can positively influence body composition, since it is believed that in appropriate concentrations this AA can decrease perceived exertion, and thus, delay the onset of fatigue, 9 presumably causing an individual to tolerate higher exercise intensity and volume, resulting in higher gains. However, no studies were found in the literature which investigated the effects of the combination of taurine supplementation and concurrent training on the body composition and lipid profile of postmenopausal women.
The hypothesis of this study was that supplementation with taurine, associated with concurrent training, would promote gains in lean body mass, reduce overall body and trunk fat, and improve the lipid profile of postmenopausal women. Thus, the aim of the present study was to analyze the effects of concurrent training and supplementation with taurine on the body composition and lipid profile of postmenopausal women.
METHODS
Study Design
This double-blinded controlled study was carried out from January of 2012 to August of 2014 at the Science and Technology Department of the Paulista State University, Brazil. Evaluations were performed at baseline and again after eight weeks of training and involved: screening for inclusion in the study; anthropometric, body composition and lipid profile measurements and three nonconsecutive 24-hour dietary recalls which were conducted at two periods: one week before the beginning of the intervention and in the first week after the intervention.
Subjects
For the sample size calculation the average of the triacylglycerol variable obtained from the study of Balducci, Zanuso10 was considered, together with the standard deviation from that study (23.9mg/dL). Adopting a power of 80% for a two-tailed test and a maximum desired error of 5%, the equation indicating the need for at least six individuals per group. Predicting possible sample losses, each group started the protocol with 12 participants.
The invitation to participate in the study was made through dissemination on the radio, television and in local newspapers. To participate in this study, the following inclusion criteria were adopted: 1) to be in menopause [no menstrual cycle for at least a year and serum levels of the follicle stimulating hormone (FSH) ≥ 30 UI/l;11 2) to be between the ages of 50 and 79 on the date of the evaluation; 3) not to present any physical limitations or health problems which would hinder the performance of the evaluations; 4) to possess a medical certificate to participate in the training program; 5) to perform all evaluations; 6) to sign the informed consent form for participation in the study (protocol 64/2011). The study was approved by the Ethics Research Group of the Sao Paulo State University Campus Presidente Prudente (Protocol 64/2011).
The following exclusion criteria were adopted: accumulating three consecutive absences or four non-consecutive absences during one month.
After the dissemination, 141 postmenopausal women signed up to participate in the study, of which 64 met the inclusion/exclusion criteria and agreed to participate in the intervention. The participants were divided randomly into the following groups: Control (C [n = 16]); Taurine (T [n = 16]), Taurine + Exercise (TE [n = 16]) Placebo + Exercise (E [n = 16]). The final sample consisted of 43 women, the reasons for dropping out were: lack of time, difficulties related to locomotion to the university, and personal problems. The flow, drop-out and final sample of the study was presented in the Figure 1.
Procedures
Anthropometry and Body Composition
Body weight was measured using an electronic Filizola-brand scale. Height was measured using a Sanny-brand fixed stadiometer. The values of height and weight were used to calculate body mass index (BMI) [weight (kg)/height (m)2].
For analysis of body composition a Dual Energy X-ray absorptiometry (DXA [General Electric Medical Systems, Lunar DPX MD, Madison, WI, USA]) device brand was used with software version 4.7. The following body composition variables were evaluated: total mass; lean body mass; total body and trunk fat, expressed in absolute and relative values.
To calculate the technical error of measurement of the DXA, two whole body evaluations were performed, by the same evaluator, on two consecutive days with 12 female subjects. From the results obtained the error was estimated as follows: 1.48% for total body fat; 1.38% for trunk fat; 2.06% for total lean body mass. The test re-test intraclass correlation coefficient of these procedure has been shown reliable (ICC between 0.91 to 0.99 for the variables used in this study).
Blood Samples
After an overnight fast (12 h), venous blood samples were collected to measure FSH, triglycerides (TG), fasting total cholesterol (TC), high-density lipoprotein cholesterol (HDL-c) and low-density lipoprotein cholesterol (LDL-c), using the colorimetric technique in dry chemical and Johnson and Johnson equipment, model Vitros 250.
Aerobic Training Procedures
The determination of the intensity of the aerobic training was performed using the critical velocity protocol proposed by Wakayoshi, Yoshida.12 The studied group traveled three distances (400, 800 and 1200 m) on a running track on separate, nonconsecutive days. The participants were instructed to cover the distance in the shortest possible time, which was recorded using a digital stopwatch (Polar®). After four weeks the procedures were repeated to adjust the intensities.
Resistance training procedures
The exercises used in the program were: 45° leg press, leg extension, leg curl, bench press, seated row, arm curl, triceps extension, side elevation with dumbbells and abdominal exercises. The training load was adjusted every four training weeks in order to maintain the prescribed number of repetitions: phases [phase 1 (1st to 4th week, 15 repetitions at ~65% of maximum, three sets per exercise, 60–90 sec between sets); phase 2 (5th to 8th week, 12 repetitions at ~70% of maximum, three sets per exercise, 60-90 sec between sets); phase 3 (9th to 12th week, 10 repetitions at ~75% of maximum, three to four sets per exercise, 60-90 sec between sets) and phase 4 (13th to 16th week, eight repetitions at ~80% of maximum, three to four sets per exercise, 60-90 sec between sets)].
The intensity of the resistance training was controlled through the zone of maximum repetitions. The series were executed until momentary exhaustion, if the participants performed more than the maximum predicted, the load was increased in order to respect the training zone.13 The test of one maximum repetition (1RM) was performed only for the Leg press and bench press, and consisted of a warm-up, followed by the performance of one series of ten repetitions of each exercise without overload. The load was gradually increased during the test until the participants were no longer able to perform the entire movement, and three attempts were allowed to meet the corresponding 1RM load. For recovery, an interval of three to five minutes between attempts was given. After four weeks the procedures were repeated to adjust the intensities.
Concurrent Training Protocol
The women who underwent the concurrent training performed the protocol three times a week on nonconsecutive days for eight weeks. Initially, the participants had a period of two weeks of familiarization. Only after familiarization, were the tests for determining training load performed. The concurrent training program lasted for 80 minutes per session, with 50 minutes of resistance training and 30 minutes of aerobic training.
To ensure that the intensities as well as the training routine were appropriate, all activities were accompanied by both previously trained monitors and the researchers responsible for the project. At the beginning of each training session blood pressure was monitored and at the end 10 minutes of stretching were conducted to cool down.
Supplementation Protocol
Twenty-four hour dietary recalls were conducted on three nonconsecutive days (one weekend and two weekdays).14 The participants were oriented by a nutritionist. Data was analyzed by the same nutritionist using the software NutWin, version 1.5 (Programa de Apoio à Nutrição, Universidade Federal de São Paulo, Brazil, 2002).
The T and TE groups consumed orally 1.5 g of taurine/day, the E and C group received capsules containing potato starch. The participants received three daily doses of taurine, 500 mg on waking, 500 mg at lunchtime and 500 mg in the evening.
Statistical Analysis
Initially, Levene's test identified that there was a homogeneity of variance for all numerical variables, except relative changes for HDL-C. Thus, HDL-C values were log-transformed. The descriptive statistic was composed of mean and standard-deviation.
The comparisons of the initial and final values of the dietary recalls of the groups were performed using the Wilcoxon test due to non-parametric distribution even after log-transformation (therefore, presented as median and inter-quartile range). Relative variations were calculated, taking into account the values obtained at the initial and final moments of the study ([Final Moment – Baseline moment] / Baseline moment * 100). Comparisons of relative values among the experimental groups were performed by analysis of variance and Tukey's post hoc test was applied when necessary. All analyses were performed using the SPSS program, version 17.0 (SP.SS Inc, Chicago, IL) and statistical significance was set at <5%.
RESULTS
The study consisted of 43 postmenopausal women (FSH = 69.4 ± 26.2), aged between 50.7 and 77 years (60.5 ± 6.5) years. The values in Table 1 and 2 refer to the initial values and comparisons between the groups of body composition and biochemical profile, of the study participants. When comparing the values obtained in the dietary recalls no significant differences were found in any of the groups studied (Table 3).
General characteristics of body composition and comparison between the groups at the beginning of the intervention, expressed as mean and standard deviation.
Biochemical profile and comparison between the groups at the beginning of the intervention, expressed as mean and standard deviation.
Figure 2 refers to the percentage changes in body composition which showed a significant difference between the pre- and post-intervention periods.
Mean percentage changes in total body composition after eight weeks of intervention, expressed as mean and standard deviation.
It was observed that the TE group presented significant reductions in the percentage of total body fat (p = 0.005, p = 0.004) and trunk fat (p = 0.024, p = 0.023), and higher improvement in the lean mass (p <0.000, p = 0.002), when compared to C and T groups, respectively. The E group showed significant increase in the lean mass (p = 0.001, p = 0.004) and reduction in the percentage of trunk fat (p = 0.042, p = 0.035), when compared to C and T groups, respectively. The E group also presented higher total body mass (p = 0.011), when compared to C group.
Figure 3 shows the percentage values of the changes in the TC and LDL-c.
After the analysis of relative changes in TC, higher reductions in the TE group, when compared to the T (p=0.020) group were observed. In relation to LDL-c, the group which trained and took taurine presented higher reductions, when compared to the C (p=0.014) and T (p=0.027) groups.
DISCUSSION
Among the principal findings of this study, it is worth highlighting that, after eight weeks of supplementation with taurine alone and associated with concurrent training, there was a reduction in total and core body fat and an increase in lean mass in both the groups which received training. Regarding the lipid profile, there was a statistically significant reduction in total cholesterol and LDL-c only in the TE group.
Rutherford, Spriet,15 verified the acute effect of supplementation of 1.66 grams of taurine in cyclists, and found increased fat oxidation after supplementation, suggesting that taurine may act on body composition, helping to reduce body fat. It has been suggested that taurine increases skeletal and cardiac muscle contraction, as it participates in the regulation of intracellular calcium and enhances the availability of calcium for contraction.16
Beyranvand, Khalafi,17 observed that individuals with heart failure who took 0.5 grams of taurine, three times a day for two weeks, showed improved performance in the treadmill test, with increased exercise time and distance traveled when compared to the placebo group. These findings corroborate the study of Alford, Cox,18 in which they used an energy drink containing taurine on trained individuals and observed a 9% increase in aerobic resistance.
The groups that underwent concurrent training (TE and E) presented a statistically significant reduction in body fat percentage, percentage of upper-body fat and an increase in lean body mass (Figure 2), when compared to the groups which did not train. Therefore, the results of this study indicate that isolated supplementation of 1.5 grams/day of taurine for eight weeks does not appear to influence body composition, even when associated with concurrent training, in postmenopausal women.
These findings corroborate with the results obtained by Lixandrão, Bonganha,19 who found that concurrent training for 16 weeks of intervention, performed by postmenopausal women, promoted increased muscle mass and strength. In a study conducted by Rossato, Binotto20 with perimenopausal women, it was found that after 20 weeks of concurrent training there was no reduction in body fat or increase in lean mass, unlike our findings. It is worth mentioning that the changes in body composition in the present study were obtained in just eight weeks.
After menopause there is an increase in the concentration of plasma lipids, a fact which contributes to an increased incidence of cardiovascular events in women.21 Changes in the lipid metabolism appear to be related to decreased amounts of the hormone estradiol, and this condition is accompanied by increased levels of triglycerides, total cholesterol, LDL-c and reduced levels of HDL-c.22 Given that abnormal values of TC; especially increased LDL-c and decreased HDL-c are important risk factors for the occurrence of circulatory and cardiac system diseases.
Research regarding taurine has been widely performed in animal models, aimed at better understanding the effect of this AA on the lipid metabolism. From these studies it is evident that supplementation with taurine can reduce plasma and liver cholesterol concentrations, especially the very low density lipoprotein and LDL-c in situations of diet-induced hypercholesterolemia, as well as increasing levels of HDL-c.23
It is believed that taurine increases the activity of CYP7A1,23 the enzyme which stimulates the synthesis of bile acids, considered the main regulatory pathway for cholesterol homeostasis in the body.24 Therefore, if there is an increase in the quantity of bile acids, consequently, a greater amount of cholesterol is withdrawn from circulation. Additionally, it is believed that taurine acts on the LDLR protein responsible for clearance of about two thirds of LDL-c from circulation,25 therefore, it is extremely important to maintain the balance of this lipoprotein in the body.
Based on the literature, supplementation with taurine seems to be interesting in aiding the treatment of individuals diagnosed with some type of metabolic disorders such as diabetes or arterial hypertension. This AA, besides acting directly on the lipid metabolism, also displays a potential antioxidant and anti-inflammatory role, and promotes improvement of the endothelial function by stimulating the increase of nitric oxide, contributing to the metabolic profile of individuals with heart disease.26
The results here suggest that the association of concurrent training with taurine supplementation appears to be beneficial for reducing TC and LDL-c. In a study performed by Shaw, Shaw,27 sedentary adults were submitted to 16 weeks of concurrent training and aerobic training in isolation where it was observed that both interventions reduced TC and increased HDL-c. Seo, So28 analyzed the effects of 12 weeks of concurrent training on middle aged women and found a significant increase in HDL-c and a reduction in TG and body fat percentage.
It is known that diet is an important source for obtaining exogenous taurine, which is principally found in seafood, dark avian meat 7 and in beef. 29 The Brazilian diet was analyzed in a population-level study by Souza et al. 30 About half of Brazilian women (51.6%) consumed beef and 27.4% consumed poultry. Although fish contains the greatest source of taurine, it is not a commonly consumed product in this population, particularly by women who live in this region. Therefore, even though Brazilian women obtain taurine from their diet, they most likely do not consume adequate amounts of this AA suggesting that supplementation may be suggested, particularly among dyslipidemic individuals.
Data from this study is important for clarifying the effects of both concurrent training in isolation and in association with taurine supplementation as it relates to the body composition and metabolic profiles of women after menopause. However, it is necessary to mention, as a limitation, such as small sample size, the lack of control for time since menopause and the amount of taurine ingested from the diet indicating that caution is needed when generalizing the conclusions found here. However, the results from this study are promising and indicate that taurine and exercise are effective at lowering lipids. Furthermore, due to the limited number of large clinical trials examining taurine as a preventive agent for dyslipidemia, more studies need to be developed before recommendations for supplementation with Taurine should be made.
CONCLUSION
In summary, there is no additional effect of taurine supplementation with concurrent training on the body composition of postmenopausal women after eight weeks of intervention. However, the combination of this AA with concurrent training helped to reduce TC and LDL-c in this population.
ACKNOWLEDGEMENTS
Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES).
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Publication Dates
-
Publication in this collection
Mar-Apr 2019
History
-
Received
29 Apr 2018 -
Accepted
28 Nov 2018