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Inicio Endocrinología, Diabetes y Nutrición (English ed.) Supplementation with omega-3 fatty acids and plasma adiponectin in women with po...
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Vol. 65. Núm. 4.
Páginas 192-199 (abril 2018)
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Vol. 65. Núm. 4.
Páginas 192-199 (abril 2018)
Original article
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Supplementation with omega-3 fatty acids and plasma adiponectin in women with polycystic ovary syndrome
Suplementación de ácidos grasos omega-3 y adiponectina plasmática en mujeres con síndrome de ovarios poliquísticos
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4043
Jorly Mejia-Montillaa, Eduardo Reyna-Villasmilb,
Autor para correspondencia
sippenbauch@gmail.com

Corresponding author.
, Lorena Domínguez-Britoc, Carmen Naranjo-Rodríguezc, Delia Noriega-Verdugoc, María Padilla-Samaniegoc, Vanessa Vargas-Olallac
a Facultad de Medicina, La Universidad del Zulia, Maracaibo, Venezuela
b Hospital Central “Dr. Urquinaona”, Maracaibo, Venezuela
c Universidad Estatal de Milagro, Milagro, Ecuador
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Tablas (4)
Table 1. General characteristics of each study group.
Table 2. Food intake in the two groups at the start and end of the study.
Table 3. Clinical and laboratory test parameters in the two groups at the start and end of the study.
Table 4. Plasma adiponectin according to insulin resistance among women in group A at the start and end of treatment with omega-3 fatty acids.
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Abstract
Objective

To study plasma adiponectin levels in women diagnosed with polycystic ovary syndrome given omega-3 fatty acid supplements.

Patients and methods

A study was conducted in 195 women diagnosed with polycystic ovary syndrome treated with omega-3 fatty acids for 12 weeks (n=97; group A) and control women given placebo (n=98, group B). General characteristics, metabolism, lipid profile, and hormone and adiponectin levels were compared.

Results

There were no significant differences between the two groups in general characteristics. No significant differences were also found in hormone, blood glucose, and HOMA levels between the groups. Women in study groups A and B showed no statistically significant differences in total calorie, carbohydrate, protein, and total fat intake between the baseline and final values. Decreased total cholesterol, low-density lipoprotein, and triglyceride levels were found in group A women (p<0.0001). Mean of adiponectin levels also showed a statistically significant increase after treatment (p<0.0001). There were no statistically significant differences in the mean values of the different variables in group B women.

Conclusion

Omega-3 fatty acid supplementation for 12 weeks caused a significant increase in plasma adiponectin levels in women with polycystic ovary syndrome.

Keywords:
Omega-3
Adiponectin
Polycystic ovary syndrome
Supplementation
Resumen
Objetivo

Estudiar las concentraciones plasmáticas de adiponectina en mujeres con diagnóstico de síndrome de ovario poliquístico (SOPQ) tratadas con suplementación de ácidos grasos omega-3.

Material y métodos

Se realizó un estudio en 195 mujeres con diagnóstico de SOPQ que fueron tratadas con ácidos grasos omega-3 durante 12 semanas (n=97; grupo A) y controles tratados con placebo (n=98, grupo B). Se compararon las características generales, las concentraciones hormonales, el perfil lipídico y la adiponectina.

Resultados

No se encontraron diferencias significativas entre ambos grupos con relación a las características generales. Tampoco se encontraron diferencias significativas en las concentraciones hormonales, glucemia y HOMA entre los grupos. Las mujeres de los grupos A y B no mostraron diferencias estadísticamente significativas en la ingesta total, ingesta de hidratos de carbono, proteínas y grasas totales entre los valores al inicio y al final del estudio. Las mujeres del grupo A presentaron disminución en las concentraciones de colesterol total, de lipoproteínas de baja densidad y de triglicéridos (p<0,0001). Los valores promedio de adiponectina también mostraron aumento estadísticamente significativo luego del tratamiento (p<0,0001). No se encontraron diferencias estadísticamente significativas en los valores promedio de las diferentes variables en las mujeres del grupo B.

Conclusión

La suplementación de ácidos grasos omega-3 durante 12 semanas produce aumento significativo en las concentraciones plasmáticas de adiponectina en mujeres con SOPQ.

Palabras clave:
Omega-3
Adiponectina
Síndrome de ovario poliquístico
Suplementación
Texto completo
Introduction

Polycystic ovary syndrome (POS) is a common endocrine-metabolic disorder in women of reproductive age, and is characterized by chronic anovulation and hyperandrogenism. The syndrome affects 5–10% of all women and is the cause of 50–70% of all cases of anovulatory infertility. Patients with POS suffer oligomenorrhea or amenorrhea and hyperandrogenism (with hirsutism, acne, increased plasma androgen levels, or a combination of such findings).1 Obesity and insulin resistance are known to be frequent in women with POS, and both conditions are related to hormone changes.2,3

Adipose tissue is active from the endocrine perspective and produces a number of peptides (including adipokines and growth factors), lipids and steroids. Adipokines exert autocrine and paracrine action upon the adipose tissue itself, as well as endocrine actions upon other organs and tissues such as skeletal muscle, adrenal glands and the central nervous system, modulating different functions, including insulin action.4 Hypoadiponectinemia has been associated with the physiopathology and metabolic complications of the syndrome.5 A number of studies have demonstrated a decrease in plasma adiponectin concentration in women with POS.4,5

In women with POS, many nutritional studies have focused on the effects of energy restriction and weight loss upon different metabolic and hormone parameters.6 Omega-3 fatty acids exert effects against obesity, inflammation and insulin resistance.7 Experimental studies have revealed an association between the consumption of these fatty acids and increments in adiponectin concentration.8 However, in humans the findings of clinical trials involving different doses and supplementation periods remain controversial.9

A number of studies have evaluated the effect of omega-3 fatty acids upon the metabolic balance and condition of different diseases,10,11 though few have involved women diagnosed with POS. Understanding the effects of omega-3 fatty acids upon the syndrome and certain adipokines, particularly adiponectin, may be important for women. The present study investigates plasma adiponectin concentrations in women diagnosed with POS and treated with omega-3 fatty acid supplements.

Material and methods

The present prospective clinical study was carried out in women with POS who attended our hospital in the period between January 2011 and May 2017. All the participants were subjected to clinical evaluation (general and gynecological exploration, including transvaginal ultrasound).

The diagnosis of POS was established according to the criteria of the consensus group12: oligomenorrhea (an interval of ≥35 days) or amenorrhea (an absence of vaginal bleeding for 6 months), hirsutism, an increased LH/FSH ratio, elevated serum testosterone, and the presence of multiple ovarian cysts (over 10 small cysts measuring 2–8mm in diameter) with a peripheral and dispersed distribution throughout the dense stromal nucleus (the presence of a ring of follicular cysts), revealed by transvaginal ultrasound performed by two physicians of the Imaging Diagnosis Department of the hospital and unrelated to the investigation. In addition to the above findings, other similar syndromes were excluded, such as adrenal gland dysfunction, Cushing's syndrome, congenital adrenal hyperplasia, androgen-producing tumors, hyperprolactinemia and untreated hypothyroidism or thyroid gland disease.

Women using oral contraceptives were excluded from the study, as were those receiving antiandrogen medication, insulin sensitizing drugs or any other medication or supplement with effects upon body weight, insulin sensitivity or the normal function of the hypothalamic-hypophyseal-gonadal axis during the three months before the study. We also excluded women with a history of diabetes mellitus, kidney disease, liver and/or gastrointestinal disorders, smoking or the consumption of more than two alcoholic drinks per week, as well as those that failed to comply with the study protocol or could take more than 80% of the administered treatment.

Written informed consent to participation was obtained from all the patients. The study protocol abided with the ethical standards of “Dr. Urquinaona” Central Hospital–University of Zulia, and with the Declaration of Helsinki (1975, revised in 2004). The local Research Ethics Committee approved the study.

The sample size was calculated on the basis of a review of previous investigations that showed a decrease of approximately 20% in adiponectin concentration after supplementing with omega-3 fatty acids. In reaching this objective with an alpha error of 0.05 and a statistical power of 90%, the inclusion of 125 women in each group was considered necessary in order to obtain similar results.

A computer-generated random numbers table was used for patient randomization. The sealed and numbered envelopes were kept by a person unconnected to the study and blinded to the objectives of the trial. Each envelope contained an assignment to a group: group A (cases: supplementing with omega-3 fatty acids) or group B (controls: supplementing with placebo). Each capsule of omega-3 fatty acids contained 180mg of eicosapentaenoic acid and 120mg of docosahexaenoic acid, while each capsule of placebo contained 1g of paraffin. The capsules and containers were all similar. The written records with the codes and respective intervention groups were only opened once all the analyses had been made.

The participants in both groups were consulted weekly by telephone and visited the clinic every four weeks. The women were asked to continue their usual diet and lifestyle. Data regarding the food consumed during a 7 day period were obtained at the start and end of the study, and were analyzed by two nutritionists participating in the study but unaware of the group to which each patient belonged, using Food Processor Nutrition Analysis Software (Esha Research, USA).

Body weight (kg) was recorded twice to the nearest 0.1kg, with the patient barefoot. Body height (m) was recorded twice to the nearest 0.5cm, with the patient barefoot. The body mass index (BMI) was calculated as weight divided by height,2 or kg/square meter. The waist circumference was measured with the patient in the standing position, at the midpoint between the upper margin of the iliac crest and the lower margin of the last rib, using a metric tape (cm). The hip circumference in turn was determined with the patient in the standing position as the greatest distance between the major trochanters. The waist/hip ratio was calculated by dividing the waist circumference (in cm) by the hip circumference (in cm).

The venous blood samples at the start and after 12 weeks of treatment were collected between 8:00–11:00a.m., under fasting conditions. Standard oral glucose tolerance testing (75g) was performed, together with evaluation of the insulin response to glucose loading, after 10–12h of fasting, between 8:30 and 10:30a.m. The results of the glucose tolerance tests were evaluated based on the criteria of the American Diabetes Association (ADA).13 All the samples were stored at −70°C until the time of analysis.

The plasma adiponectin concentrations were measured using a commercial ELISA kit (B-Bridge International, USA). The intra- and inter-assay coefficients of variation were 4.9% and 6.3%, respectively. All hormones were determined based on electrochemiluminescence immunoassays using the Elecsys 2010 autoanalyzer (Boehringer Mannheim, Germany), with specific reagents. The intra- and inter-assay coefficients of variation for each hormone were: FSH (1.7% and 4.7%), LH (1.1% and 3.1%), prolactin (2.9% and 4.1%), TSH (4.2% and 5.2%), estradiol (2.1% and 4.5%), testosterone (2.4% and 3.8%), insulin (3.0% and 4.7%), androstenedione (4.1% and 5.2%), respectively. The concentrations of dehydroepiandrosterone sulfate (intra- and inter-assay coefficients of variation: 7.5% and 5.5%, respectively) and androstenedione (intra- and inter-assay coefficients of variation: 6.8% and 7.2%, respectively) were measured using enzymoimmunoassay tests (Diagnostic Systems Laboratories, USA). In turn, 17-hydroxyprogesterone was measured using a double antibody test (ICN Pharmaceuticals, USA) (intra- and inter-assay coefficients of variation: 5.1% and 7.6%, respectively).

The glucose concentrations were determined using an enzyme method. An autoanalyzer (Hitachi 912, Boehringer Mannheim, Germany), with specific reagents was used. Insulin resistance under fasting conditions was evaluated using the Homeostatic Model Assessment (HOMA-IR), calculated using the following equation: (insulin×glucose)/22.5. Insulin was measured in μU/ml, and glucose in mmol/l.14 A HOMA-IR score of over 3.5 was interpreted as representing insulin resistance. The areas under the insulin and glucose curves were calculated according to the formula applicable to each geometrical figure, representing an increase in postprandial plasma concentrations above basal levels.15

The serum concentrations of total cholesterol (TC), high density lipoprotein cholesterol (HDLc), low density lipoprotein cholesterol (LDLc) and triglycerides (TGs) were recorded using the Abbott Aeroset automatic analyzer (Abbott Diagnostics, USA). The values corresponding to apolipoprotein A (Apo-A) and apolipoprotein B (Apo-B) were recorded by nephelometric assay using an Array 360 system (Beckman Coulter, USA). The intra- and inter-assay coefficients of variation were under 10% for all the tests.

The variables were reported as the mean±standard deviation (SD). After confirming normal data distribution with the Kolmogorov–Smirnov test, the Student t-test for related samples was used to compare values before and after treatment in both groups of patients. The Pearson test was used to correlate the adiponectin values to the values of the different laboratory parameters in each study period. The percentage change in variables after the intervention was determined from the following formula: [(final valuesinitial values)/initial values]×100. All statistical analyses were made using the SPSS version 19.0 statistical package (SPSS Inc., USA). Statistical significance was considered for p<0.05.

Results

A total of 250 women diagnosed with POS were selected. Fifty-five participants were excluded from the final analysis (28 in group A and 27 in group B) because they failed to complete the follow-up period, stopped taking the capsules and/or could not provide all the measurements of the different study variables. A total of 195 women were therefore included in the final analysis: 97 treated with omega-3 fatty acids during 12 weeks (group A) and 98 controls (group B). The mean patient age was 23.5±3.6, with a BMI of 26.2±2.9kg/m2 and a waist/hip ratio of 0.80±0.06.

Table 1 shows the general characteristics of each study group. There were no statistically significant differences between the two groups of women in terms of age, the BMI or the waist/hip ratio. Likewise, no significant differences were observed in the concentrations of sex hormones, thyroid hormones or prolactin between groups A and B. In turn, no significant differences were observed between the two groups in relation to fasting insulin concentration, HOMA-IR, or the areas under the insulin and glucose curves.

Table 1.

General characteristics of each study group.

X±SD  Group A  Group B  p 
  Omega-3  Controls   
  n=97  n=98   
Age, years  23.6±3.4  23.3±3.9  0.5678 
Body mass index, kg/m2  26.4±3.0  26.0±2.7  0.3289 
Waist/hip ratio  0.80±0.06  0.81±0.05  0.2075 
FSH mIU/l  5.4±1.3  5.6±1.2  0.2656 
LH mIU/l  10.7±4.2  10.0±4.0  0.2348 
LH/FSH ratio  2.1±0.9  1.9±0.9  0.2540 
Estradiol, pg/ml  56.9±30.1  54.5±28.9  0.5707 
Progesterone, ng/ml  0.83±0.21  0.78±0.22  0.1062 
Total testosterone, ng/ml  0.89±0.11  0.91±0.12  0.2267 
Free testosterone, pg/ml  3.3±0.9  3.3±0.9  0.2775 
Androstenedione, ng/ml  3.1±0.8  3.3±0.8  0.0825 
Dehydroepiandrosterone sulfate, pg/dl  314.9±74.5  313.2±65.1  0.8654 
Prolactin, ng/ml  15.6±4.6  16.7±5.0  0.1116 
TSH mIU/l  2.9±0.4  2.8±0.5  0.1249 
Fasting insulin, pIU/ml  18.7±4.2  19.4±3.9  0.2292 
HOMA-IR  3.5±0.9  3.6±0.9  0.4388 
Area under the insulin curve, pIU/ml/min  9.894±575  9.975±577  0.3247 
Area under the glucose curve, mg/dl/min  16.489±1.189  16.438±1.290  0.1081 

Table 2 shows the food intake values of the two groups at the start and end of the study. There were no statistically significant differences between the two groups in terms of the total intake or the intake of carbohydrates, proteins and fats between the start and end of the study. Likewise, no statistically significant differences were recorded in any of the study variables between the two food intake groups at the end of the study.

Table 2.

Food intake in the two groups at the start and end of the study.

X±SD  Group Apa  Group Bpa 
  Omega-3  Controls 
  n=97  n=98 
  Initial  Final    Initial  Final   
Total intake, kcal/day  1.979±207  2.010±216  0.3088  1.951±231  2.045±236  0.0745 
Carbohydrates, g/day  223±35  222±39  0.8511  217±34  228±38  0.0822 
Proteins, g/day  63±13  60±12  0.0965  63±13  61±12  0.2645 
Total fats, g/day  64±12  63±11  0.5459  63±12  62±11  0.5438 
a

Comparison of initial and final values.

With regard to insulin resistance, lipid profile and adiponectin (Table 3), the women treated with omega-3 fatty acids for 12 weeks showed a decrease in fasting insulin (approximately 12%), HOMA-IR (over 8%), the area under the insulin curve (approximately 10%) and the area under the glucose curve (over 10%). All of these differences were considered statistically significant (p<0.05). The patients in group A also showed a decrease of about 15% in total cholesterol (p<0.0001). This was accompanied by a 23% decrease in LDLc (p<0.0001) and a 25% decrease in triglyceride levels (p<0.0001). We also recorded a significant 4% increase in HDLc concentration (p<0.0097) and a 7% increase in Apo-B concentration (p<0.0001). By contrast, Apo-A levels showed no significant variations (p=0.2353). The mean final adiponectin values showed a statistically significant increase of about 35% versus the initial levels (5.3±1.4ng/ml versus 3.9±1.1ng/ml; p<0.0001). There were no statistically significant differences in the mean values of the different variables in the control group.

Table 3.

Clinical and laboratory test parameters in the two groups at the start and end of the study.

X±SD  Group Apa  Group Bpc 
  Omega-3  Controls 
  n=97  n=98 
  Initial  Final    Initial  Final   
Body mass index, kg/m2  26.4±3.0  25.7±3.1  0.1117  26.0±2.7  26.2±2.8  0.6113 
Waist/hip ratio  0.80±0.06  0.81±0.07  0.2867  0.81±0.05  0.80±0.06  0.2065 
Fasting insulin, pIU/ml  18.7±4.2  16.5±3.4  0.0001  19.4±4.2  19.6±4.3  0.7435 
HOMA-IR  3.6±0.8  3.3±0.9  0.0213  3.6±0.9  3.7±0.7  0.3888 
Area under the insulin curve, pIU/ml/min  9.894±575  8.822±531  0.0001  9.975±577  9.838±554  0.0933 
Area under the glucose curve, mg/dl/min  16.489±1.189  14.882±1.049  0.0001  16.489±1.189  16.438±1.166  0.7633 
TC, mg/dl  180.1±22.1  154.6±17.6  0.0001  180.5±21.0  176.1±20.8  0.1334 
LDLc, mg/dl  109.3±12.1  84.7±11.2  0.0001  111.7±12.9  110.4±15.4  0.5225 
HDLc, mg/dl  50.4±5.5  52.7±6.7  0.0097  48.5±6.0  47.8±5.6  0.3995 
TG, mg/dl  106.7±24.7  86.3±18.9  0.0001  104.1±22.4  102.6±22.9  0.6435 
Apo-A, mg/dl  121.1±19.2  118.0±17.0  0.2353  121.9±17.4  119.1±15.6  0.2370 
Apo-B, mg/dl  87.7±13.1  94.5±12.6  0.0003  88.6±12.8  86.2±12.9  0.1926 
Adiponectin, ng/ml  3.9±1.1  5.3±1.4  0.0001  4.0±1.2  3.8±1.2  0.2448 

Apo-A: apolipoprotein A; Apo-B: apolipoprotein B; HDLc: high density lipoprotein cholesterol; LDLc: low density lipoprotein cholesterol; TC: total cholesterol; TG: triglycerides.

a

Comparison of initial and final values.

In group A, the adiponectin concentrations before treatment were seen to correlate significantly (p<0.05) with the area under the insulin curve (r=−0.245), while the concentrations after treatment only correlated with the triglyceride levels (r=−0.340).

Table 4 shows the adiponectin levels before and after treatment among the patients in group A, stratified according to the presence of insulin resistance (HOMA-IR >3.5). The women with insulin resistance showed a significant increase (34%) in the final adiponectin levels versus the initial values (5.1±1.5ng/ml versus 3.8±1.1ng/ml; p<0.0001). The women without insulin resistance also showed a significant increase (36%) in the final adiponectin levels versus the initial values (5.6±1.3ng/ml versus 4.1±1.1ng/ml; p=0.005). No statistically significant differences were observed on comparing the initial and final concentrations in the two groups.

Table 4.

Plasma adiponectin according to insulin resistance among women in group A at the start and end of treatment with omega-3 fatty acids.

  Women with POS and insulin resistancepa  Women with POS and insulin resistancepa 
  (HOMA-IR <3.5)  (HOMA-IR >3.5) 
  n=51  n=46 
  Before treatment  After treatment    Before treatment  After treatment   
Adiponectin, ng/ml  3.8±1.1  5.1±1.5  0.0001  4.1±1.1  5.6±1.3  0.005 
a

Comparison of initial and final values.

Discussion

The evidence indicates that POS contributes to the development of a proinflammatory state that in turn correlates with variations in the plasma concentrations of different adipokines.16 Adiponectin exerts important antiinflammatory, vascular protective, antidiabetic and cardioprotective effects.4 The present study investigated the plasma adiponectin concentrations in women diagnosed with POS and treated with omega-3 fatty acid supplements. A significant increase in these concentrations was observed in the women with POS after 12 weeks of supplementing with omega-3 fatty acids.

Different clinical and experimental studies in healthy individuals and subjects with different disease conditions have explored the potential effects of omega-3 fatty acid supplements upon adiponectin concentrations. One such study showed that the consumption of fish oil for 8 weeks increased adiponectin concentrations in non-obese young individuals.17 Likewise, two studies, one involving obese subjects8 and another in women with hyperinsulinemia and overweight,18 found that supplementing with polyunsaturated fatty acids raised adiponectin concentrations. Studies in animals have shown a diet containing fish oil to be associated with increased adiponectin levels.19 However, other earlier studies were unable to demonstrate changes in adiponectin concentration after supplementing with omega-3 fatty acids20; this was possibly attributable to the metabolic state of the selected individuals or to differences in design between the studies.

The increase in adiponectin observed in our study among women with POS after 12 weeks of supplementing with omega-3 fatty acids was similar to that reported by Mohammadi et al.,21 who recorded an increase in adiponectin levels after treatment with omega-3 fatty acids for 8 weeks. This increase was accompanied by benefits in terms of insulin resistance, suggesting a contribution to metabolic control among the women. However, a previous investigation found no significant changes in plasma adiponectin concentrations in women diagnosed with POS after 6 weeks of supplementing with fish oil.22

In the present study, treatment with omega-3 fatty acids resulted in significant reductions in total cholesterol, triglycerides, LDLc and Apo-B, together with an increase in HDLc. These results are consistent with those of previous studies indicating significant reductions in triglyceride levels in women with POS treated with fish oil, although in these cases no significant changes in serum total cholesterol, LDLc or HDLc were noted.23 A decrease in the plasma concentrations of triglycerides has also been reported by other authors.24 A previous study showed that treatment with omega-3 fatty acids resulted in significant reductions in triglyceride levels, together with an increase in HDLc.25 The effect of supplementing with omega-3 fatty acids upon triglyceride levels depends upon the dose administered.24 In this regard, the dosage and duration of treatment with omega-3 fatty acids may have sufficed to produce the significant improvements observed after the intervention in this group of women.

The women with POS subjected to omega-3 fatty acid supplementing showed no significant differences in the BMI versus the initial or baseline values. This observation is consistent with the findings of a previous study in which supplements of this kind exerted scant effects upon the patient anthropometric profile.26 This is an important finding, since no differences in diet were noted during the study, and agrees with the previous observations of Mohammadi et al.,21 who recorded no changes in patient body weight after supplementing for 8 weeks. On the other hand, a number of studies demonstrated a decrease in the BMI after 8 weeks of supplementing with omega-3 fatty acids in women with non-insulin dependent diabetes,22 as well as a decrease in weight among mice.27 Other studies suggest that supplementing exerts this effect, especially when complemented with other weight-losing treatments, though these findings are contradictory.28 Obesity and its comorbidities (diabetes, cancer and heart diseases) are related to inflammation, and omega-3 fatty acids have antiinflammatory properties.

The possible explanation for the findings of this study is that omega-3 fatty acids are natural ligands for four metabolic nuclear receptors: the peroxisome proliferator activated receptor (PPAR) γ, the liver X receptor, the hepatocyte nuclear factor-4α and the farnesol X receptor. The activation of these receptors down-regulates genes encoding for proteins that stimulate lipid synthesis, and regulates genes that improve fatty acid oxidation in liver and muscle.29 Furthermore, certain positive effects upon the lipid profile are mediated by an improvement in AMP-activated protein kinase, an important sensor of cell energy status that regulates the division between lipid oxidation and lipogenesis.27 One of the main reported effects of supplementing with omega-3 fatty acids is the stimulation of the activation of the adiponectin gene in adipose cells, probably acting through ligands of peroxisome proliferator γ, a transcription regulator that interacts with the gene promoter.30

This study has several limitations. The investigation was carried out in women diagnosed with POS and of normal body weight. This can result in under- or overestimation of the changes in plasma adiponectin concentration; since the effects of omega-3 fatty acids are dose dependent, the findings may not be applicable to obese or overweight women, to other types of supplements or to different supplementing periods. In our study, we only measured total adiponectin concentrations, not those corresponding to high molecular weight adiponectin (which is more active and is related to insulin sensitivity). Lastly, although caloric intake was evaluated among the patients, no assessment of the changes in physical activity of the participants during the study period was made.

On the basis of the findings of our study, it can be concluded that supplementing with omega-3 fatty acids for 12 weeks results in a significant increase in plasma adiponectin levels in women with POS. This modulation of adiponectin secretion, directly related to the regulation of metabolism and insulin resistance, could have beneficial effects.

Conflicts of interest

The authors state that they have no conflicts of interest.

References
[1]
W.L. Chiu, J. Boyle, A. Vincent, H. Teede, L.J. Moran.
Cardiometabolic risks in polycystic ovary syndrome: non-traditional risk factors and the impact of obesity.
Neuroendocrinology, 104 (2017), pp. 412-424
[2]
J. Faubert, M.C. Battista, J.P. Baillargeon.
Physiology and endocrinology symposium: insulin action and lipotoxicity in the development of polycystic ovary syndrome: a review.
J Anim Sci, 94 (2016), pp. 1803-1811
[3]
D. Glintborg, M. Andersen.
Management of endocrine disease: morbidity in polycystic ovary syndrome.
Eur J Endocrinol, 176 (2017), pp. R53-R65
[4]
J.K. Ko, H.W. Li, K.S. Lam, S. Tam, V.C. Lee, T.W. Yeung, et al.
Serum adiponectin is independently associated with the metabolic syndrome in Hong Kong Chinese women with polycystic ovary syndrome.
Gynecol Endocrinol, 32 (2016), pp. 390-394
[5]
H. Demirci, M. Yilmaz, M.A. Ergun, E. Yurtcu, N. Bukan, G. Ayvaz.
Frequency of adiponectin gene polymorphisms in polycystic ovary syndrome and the association with serum adiponectin, androgen levels, insulin resistance and clinical parameters.
Gynecol Endocrinol, 26 (2010), pp. 348-355
[6]
J.G. Love, J.S. McKenzie, E.A. Nikokavoura, J. Broom, C. Rolland, K.L. Johnston.
The experiences of women with polycystic ovary syndrome on a very low-calorie diet.
Int J Womens Health, 8 (2016), pp. 299-310
[7]
A. Sener, Y. Zhang, N. Bulur, K. Louchami, W.J. Malaisse, Y.A. Carpentier.
The metabolic syndrome of omega-3-depleted rats II. Body weight, adipose tissue mass and glycemic homeostasis.
Int J Mol Med, 24 (2009), pp. 125-129
[8]
M. Itoh, T. Suganami, N. Satoh, K. Tanimoto-Koyama, X. Yuan, M. Tanaka, et al.
Increased adiponectin secretion by highly purified eicosapentaenoic acid in rodent models of obesity and human obese subjects.
Arterioscler Thromb Vasc Biol, 27 (2007), pp. 1918-1925
[9]
E. Lopez-Huertas.
The effect of EPA and DHA on metabolic syndrome patients: a systematic review of randomised controlled trials.
Br J Nutr, 107 (2012), pp. S185-S194
[10]
M. Guichardant, C. Calzada, N. Bernoud-Hubac, M. Lagarde, E. Véricel.
Omega-3 polyunsaturated fatty acids and oxygenated metabolism in atherothrombosis.
Biochim Biophys Acta, 1851 (2015), pp. 485-495
[11]
A.M. Minihane.
Impact of genotype on EPA and DHA status and responsiveness to increased intakes.
Nutrients, 8 (2016), pp. 123
[12]
D. Dewailly.
Diagnostic criteria for PCOS: is there a need for a rethink?.
Best Pract Res Clin Obstet Gynaecol, 37 (2016), pp. 5-11
[13]
E.R. Seaquist, J. Anderson, B. Childs, P. Cryer, S. Dagogo-Jack, L. Fish, et al.
Hypoglycemia and diabetes: a report of a workgroup of the American Diabetes Association and the Endocrine Society.
J Clin Endocrinol Metab, 98 (2013), pp. 1845-1859
[14]
D.R. Matthews, J.P. Hosker, A.S. Rudenski, B.A. Naylor, D.F. Treacher, R.C. Turner.
Homeostasis model assessment: insulin resistance and beta-cell function from fasting plasma glucose and insulin concentrations in man.
Diabetologia, 28 (1985), pp. 412-419
[15]
A. Aziz.
The glycemic index: methodological aspects related to the interpretation of health effects and to regulatory labeling.
J AOAC Int, 92 (2009), pp. 879-887
[16]
T. Sathyapalan, Z. Javed, E.S. Kilpatrick, A.M. Coady, S.L. Atkin.
Endocannabinoid receptor blockade increases vascular endothelial growth factor and inflammatory markers in obese women with polycystic ovary syndrome.
Clin Endocrinol (Oxf), 86 (2017), pp. 384-387
[17]
K. Kondo, K. Morino, Y. Nishio, M. Kondo, T. Fuke, S. Ugi, et al.
Effects of a fish-based diet on the serum adiponectin concentration in young, non-obese, healthy Japanese subjects.
J Atheroscler Thromb, 17 (2010), pp. 628-637
[18]
J.D. Krebs, L.M. Browning, N.K. McLean, J.L. Rothwell, G.D. Mishra, C.S. Moore, et al.
Additive benefits of long-chain n-3 polyunsaturated fatty acids and weight-loss in the management of cardiovascular disease risk in overweight hyperinsulinaemic women.
Int J Obes (Lond), 30 (2006), pp. 1535-1544
[19]
T. Higuchi, N. Shirai, M. Saito, H. Suzuki, Y. Kagawa.
Levels of plasma insulin, leptin and adiponectin, and activities of key enzymes in carbohydrate metabolism in skeletal muscle and liver in fasted ICR mice fed dietary n-3 polyunsaturated fatty acids.
J Nutr Biochem, 19 (2008), pp. 577-586
[20]
M. Kratz, M.M. Swarbrick, H.S. Callahan, C.C. Matthys, P.J. Havel, D.S. Weigle.
Effect of dietary n-3 polyunsaturated fatty acids on plasma total and high-molecular-weight adiponectin concentrations in overweight to moderately obese men and women.
Am J Clin Nutr, 87 (2008), pp. 347-353
[21]
E. Mohammadi, M. Rafraf, L. Farzadi, M. Asghari-Jafarabadi, S. Sabour.
Effects of omega-3 fatty acids supplementation on serum adiponectin levels and some metabolic risk factors in women with polycystic ovary syndrome.
Asia Pac J Clin Nutr, 21 (2012), pp. 511-518
[22]
M. Poreba, M. Mostowik, A. Siniarski, R. Golebiowska-Wiatrak, K.P. Malinowski, M. Haberka, et al.
Treatment with high-dose n-3 PUFAs has no effect on platelet function, coagulation, metabolic status or inflammation in patients with atherosclerosis and type 2 diabetes.
Cardiovasc Diabetol, 16 (2017), pp. 50
[23]
M.L. Vargas, R.U. Almario, W. Buchan, K. Kim, S.E. Karakas.
Metabolic and endocrine effects of long-chain versus essential omega-3 polyunsaturated fatty acids in polycystic ovary syndrome.
Metabolism, 60 (2011), pp. 1711-1718
[24]
P. Nestel, P. Clifton, D. Colquhoun, M. Noakes, T.A. Mori, D. Sullivan, et al.
Indications for omega-3 long chain polyunsaturated fatty acid in the prevention and treatment of cardiovascular disease.
Heart Lung Circ, 24 (2015), pp. 769-779
[25]
H. Grundt, D.W. Nilsen, Ø. Hetland, M.A. Mansoor.
Clinical outcome and atherothrombogenic risk profile after prolonged wash-out following long-term treatment with high doses of n-3 PUFAs in patients with an acute myocardial infarction.
Clin Nutr, 23 (2004), pp. 491-500
[26]
N. Spanos, K. Tziomalos, D. Macut, E. Koiou, E.A. Kandaraki, D. Delkos, et al.
Adipokines, insulin resistance and hyperandrogenemia in obese patients with polycystic ovary syndrome: cross-sectional correlations and the effects of weight loss.
Obes Facts, 5 (2012), pp. 495-504
[27]
S.A. Khatib, E.L. Rossi, L.W. Bowers, S.D. Hursting.
Reducing the burden of obesity-associated cancers with anti-inflammatory long-chain omega-3 polyunsaturated fatty acids.
Prostaglandins Other Lipid Mediat, 125 (2016), pp. 100-107
[28]
X.W. Dai, Y.M. Chen, F.F. Zeng, L.L. Sun, C.G. Chen, Y.X. Su.
Association between n-3 polyunsaturated fatty acids in erythrocytes and metabolic syndrome in Chinese men and women.
Eur J Nutr, 55 (2016), pp. 981-989
[29]
A. Georgiadi, S. Kersten.
Mechanisms of gene regulation by fatty acids.
Adv Nutr, 3 (2012), pp. 127-134
[30]
P. Flachs, V. Mohamed-Ali, O. Horakova, M. Rossmeisl, M.J. Hosseinzadeh-Attar, M. Hensler, et al.
Polyunsaturated fatty acids of marine origin induce adiponectin in mice fed a high-fat diet.
Diabetologia, 49 (2006), pp. 394-397

Please cite this article as: Mejia-Montilla J, Reyna-Villasmil E, Domínguez-Brito L, Naranjo-Rodríguez C, Noriega-Verdugo D, Padilla-Samaniego M, et al. Suplementación de ácidos grasos omega-3 y adiponectina plasmática en mujeres con síndrome de ovarios poliquísticos. Endocrinol Diabetes Nutr. 2018;65:192–199.

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