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Dietary intake, glucose metabolism and sex hormones in women with polycystic ovary syndrome (PCOS) compared with women with non-PCOS-related infertility

Published online by Cambridge University Press:  10 October 2012

Ya-Hui Tsai
Affiliation:
School of Nutrition and Health Sciences, Taipei Medical University, Taipei, Taiwan, ROC
Ting-Wen Wang
Affiliation:
School of Nutrition and Health Sciences, Taipei Medical University, Taipei, Taiwan, ROC
Hsiao-Jui Wei*
Affiliation:
Infertility Center, Taiwan Adventist Hospital, Taipei, Taiwan, ROC
Chien-Yeh Hsu
Affiliation:
Graduate Institute of Biomedical Informatics, Taipei Medical University, Taipei, Taiwan, ROC
Hsin-Jung Ho
Affiliation:
School of Nutrition and Health Sciences, Taipei Medical University, Taipei, Taiwan, ROC
Wen-Hua Chen
Affiliation:
Graduate Institute of Biomedical Informatics, Taipei Medical University, Taipei, Taiwan, ROC
Robert Young
Affiliation:
Infertility Center, Taiwan Adventist Hospital, Taipei, Taiwan, ROC
Chian-Mey Liaw
Affiliation:
Infertility Center, Taiwan Adventist Hospital, Taipei, Taiwan, ROC
Jane C.-J. Chao*
Affiliation:
School of Nutrition and Health Sciences, Taipei Medical University, Taipei, Taiwan, ROC Nutrition Research Center, Taipei Medical University Hospital, Taipei, Taiwan, ROC
*
*Corresponding authors: Dr Jane C.-J. Chao, fax +886 2 2737 3112, email [email protected]; Dr Hsiao-Jui Wei, email [email protected]
*Corresponding authors: Dr Jane C.-J. Chao, fax +886 2 2737 3112, email [email protected]; Dr Hsiao-Jui Wei, email [email protected]
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Abstract

The present study investigated dietary intake, glucose metabolism and sex hormones in women with polycystic ovary syndrome (PCOS). A total of forty-five women (aged 25–40 years) with PCOS and 161 control women (aged 25–43 years) with non-PCOS-related infertility were recruited. Anthropometry, glucose tolerance and sex hormones were determined and dietary intake was assessed. Women with PCOS had lower serum sex hormone-binding globulin and increased BMI, waist:hip ratio, luteinising hormone, ratio of luteinising hormone:follicle-stimulating hormone, testosterone and free androgen index (FAI). Postprandial glucose, fasting insulin and insulin resistance were elevated in women with PCOS. Women with PCOS had reduced energy and carbohydrate intake but higher fat intake. Serum sex hormone-binding globulin level was negatively associated with BMI in both groups and negatively correlated with macronutrient intake in the PCOS group with hyperandrogenism. However, FAI was positively correlated with BMI, waist circumference and glucose metabolic parameters in both groups. Therefore, women with PCOS consume lower energy and carbohydrate compared with those with non-PCOS-related infertility and macronutrient intake is only negatively associated with serum sex hormone-binding globulin level in the PCOS group with hyperandrogenism.

Type
Full Papers
Copyright
Copyright © The Authors 2012 

Polycystic ovary syndrome (PCOS), characterised by oligo- and/or anovulation, clinical and/or biochemical signs of hyperandrogenism and/or polycystic ovaries(1), is one of the most common causes of ovulation dysfunction in women of reproductive age. The prevalence of PCOS has been found to range from 2 to 20 % in the general population worldwide(Reference Knochenhauer, Key and Kahsar-Miller2), varying depending on the criteria used. According to the National Institutes of Health criteria (1990), Rotterdam consensus criteria (2003) and Androgen Excess Society criteria (2006), the estimated prevalence of PCOS was 8·7, 11·9–17·8 and 10·2–12·0 %, respectively, in Australia(Reference March, Moore and Willson3). PCOS can be suspected by clinical and laboratory findings including irregular menstruation or amenorrhea, hirsutism, acne and/or enlarged polycystic ovaries in women with infertility, but excludes other androgen excess or ovulatory disorders, such as congenital adrenal hyperplasia androgen-secreting neoplasms, Cushing's syndrome, thyroid dysfunction, severe insulin resistance, hyperprolactinaemia, or exogenous androgen excess(1, Reference Azziz, Woods and Reyna4). In addition to abnormal clinical and biochemical signs of hyperandrogenism, insulin resistance, compensatory hyperinsulinaemia and impaired glucose tolerance could increase the risk of type 2 diabetes mellitus and hyperlipidaemia in women with PCOS(Reference Legro, Kunselman and Dodson5, Reference Vrbikova and Hainer6).

Obesity is common in 30–70 % women with PCOS(Reference Vrbikova and Hainer6). Obesity, in particular of the abdominal type, is present in variable degrees in women with PCOS studied in Europid populations(Reference Remsberg, Talbott and Zborowski7, Reference Hahn, Tan and Elsenbruch8). However, there are a lower prevalence rate of glucose intolerance and lower BMI in Chinese women with PCOS(Reference Ni, Mo and Chen9). Obesity plays a crucial role in the pathogenesis of PCOS when accompanied with insulin resistance(Reference Dunaif10). About 50–70 % women with PCOS have insulin resistance and secondary hyperinsulinaemia(Reference Ovalle and Azziz11). Insulin resistance has been reported in non-obese Chinese women with PCOS(Reference Chang, Nakamura and Judd12), indicating that the presence of hyperinsulinaemia in women with PCOS is independent of obesity. Insulin resistance is associated with an increased risk of the metabolic syndrome, diabetes mellitus and CVD(Reference Galluzzo, Amato and Giordano13). It is hypothesised that controlled body weight and improved insulin resistance may delay or prevent the development of diabetes mellitus and CVD in women with PCOS(Reference Vrbikova and Hainer6).

Several studies have revealed that weight loss by diet, exercise and/or behaviour intervention improves body composition, insulin resistance and hyperandrogenism as well as restores menstrual cyclicity and ovulation in overweight or obese women with PCOS(Reference Thomson, Buckley and Brinkworth14Reference Marsh, Steinbeck and Atkinson16). A low-glycaemic index diet has been reported to improve menstrual cyclicity in overweight and obese women with PCOS(Reference Marsh, Steinbeck and Atkinson16). However, central obesity and insulin resistance were not strictly correlated with dietary intake including energy and macronutrients in women with PCOS(Reference Thomson, Buckley and Brinkworth14). It is unclear whether dietary intake, glucose metabolism and sex hormones in women with PCOS differ from those with non-PCOS-related infertility and whether the changes in sex hormones are associated with anthropometric measurements, glucose metabolism and/or dietary intake in women with PCOS. Therefore, the present study investigated dietary intake, glucose metabolism and sex hormones in women with PCOS and the correlation between sex hormones and other variables, such as anthropometric measurements, glucose metabolism and dietary intake.

Methods

Subjects

A total of forty-five women with PCOS (aged 25–40 years) and 161 non-PCOS infertile women of a similar age (25–43 years) as controls were recruited from 287 patients who visited the Infertility Center of Taiwan Adventist Hospital for the first time between April 2008 and March 2009. Aetiologies of infertility in the subjects were: 37·7 % ovulation dysfunction (including women with PCOS), 9·5 % male factor, 8·6 % endometriosis, 1·4 % tubal factor, 1·1 % poor ovarian function, 15·0 % multiple factors and 26·7 % unexplained causes. The diagnosis of PCOS was based on revised 2003 Rotterdam criteria established by the European Society for Human Reproduction and Embryology and American Society for Reproductive Medicine(1). The subjects with non-classic adrenal hyperplasia, 21-hydroxylase deficiency, hyperprolactinaemia, hypothyroidism, androgen-secreting tumours and receiving hormonal therapy were excluded from the present study. The present study was conducted according to the guidelines laid down in the Declaration of Helsinki and all procedures involving human subjects were approved by the Taiwan Adventist Hospital Institutional Review Board. Written informed consent was obtained from all subjects before the study.

Protocols

The subjects completed the standard form for medical history including menstrual history and anthropometric measurements including height, body weight, BMI, waist circumference and waist:hip ratio (WHR). An overnight fasting blood sample was obtained from the subjects between 08.00 and 10.00 hours during the first 3 d of the menstrual cycle for hormone assays including follicle-stimulating hormone (FSH), luteinising hormone (LH), testosterone and sex hormone-binding globulin (SHBG). Blood samples were stored at − 80°C until analysis within 7 d. Blood glucose and insulin levels were measured before and 2 h after a 75 g oral glucose load in 300 ml water. Dietary intake was assessed by 3-d dietary record.

Laboratory assays

Serum FSH, LH, testosterone and SHBG were assessed by commercial RIA kits (Diagnosis System Laboratories, Inc.). Free androgen index (FAI), an indicator of an abnormal androgen status in women, was determined by:

$$\begin{eqnarray} FAI = total\ testosterone\ (nmol/l)/SHBG\ (nmol/l)\times 100. \end{eqnarray}$$

Blood glucose concentration was determined by the glucose oxidase method 30 min after blood was drawn. Serum insulin was analysed by a commercial RIA kit (Diagnosis Products Corp.). Homeostasis model assessment of insulin resistance (HOMA-IR)(Reference Matthews, Hosker and Rudenski17), an index of insulin resistance, was calculated as:

$$\begin{eqnarray} HOMA - IR = fasting\,glucose\ (mmol/l)\times fasting\ insulin\ (\mu U/ml)/22\cdot 5. \end{eqnarray}$$

Dietary assessment

The subjects were taught food portion sizes using food photographs and measuring containers and given instructions for the dietary record by a registered dietitian before recording dietary intake. A 3-d dietary record of their usual diets including two weekdays and one weekend was completed by the subjects in the week after blood was drawn. The registered dietitian re-checked mealtime, eating place, food items or ingredients, cooking methods and portion sizes by telephone interview after the dietary record sheet was returned. Energy and macronutrient intake was analysed using Food and Nutrition Data Analysis System for Research software (Ekitchen Business Co.). Dietary intake data were removed because of under-reporting of energy intake, which was defined as below 70 % of dietary reference intake in Taiwan.

Statistical analysis

All data are expressed as mean values and standard deviations. Statistical analysis was performed using SAS (version 9.1; SAS Institute Inc.). The normality of the data was tested by the Kolmogorov–Smirnov test. In order to determine the effect of BMI and hyperandrogenism on clinical measurements, the subjects in the PCOS and control groups were divided into two subgroups by BMI ( < 22 and ≥ 22 kg/m2) and those in the PCOS group were divided into two subgroups by serum testosterone level ( ≤ 1·7 and >1·7 nmol/l) for further analysis. The BMI cut-off point established in 1995 by the Department of Health in Taiwan for ideal weight was 22 kg/m2. According to current criteria of the Department of Health in Taiwan, the values of BMI for underweight, normal weight, overweight and obesity are < 18·5, 18·5–23·9, 24·0–26·9 and ≥ 27·0 kg/m2, respectively. The BMI cut-off point for the subgroups was set at 22 kg/m2, which is the same cut-off point for ideal weight in the present study. Hyperandrogenism was diagnosed biochemically by a serum testosterone level over 1·7 nmol/l(Reference Hatch, Rosenfield and Kim18), which was set for the cut-off point. The data among different subgroups in the control and PCOS groups were analysed by one-way ANOVA and Fisher's least significant difference test. The differences between the PCOS and control groups as well as between the two subgroups in women with PCOS were analysed by Student's t test. Correlations between two variables were analysed by simple linear regression and Pearson's correlation coefficient. Multiple linear regression analysis was used for predicting the association of clinical measurements and independent variables, such as characteristics, glucose metabolic parameters and dietary intake. The statistical significance level was set at P< 0·05.

Results

Demographic and clinical characteristics

All participants completed anthropometric and clinical measurements and dietary records in the study. The number of women with normal ( ≤ 1·7 nmol/l), intermediate (1·8–3·1 nmol/l) and high (>3·1 nmol/l) serum testosterone level in the PCOS group was twenty-four (53 %), eighteen (40 %) and three (7 %), respectively. Of the women, eight controls (5 %) and six with PCOS (13 %) were obese, with BMI ≥ 27 kg/m2 defined as obesity in Taiwan, and five controls (3 %) and four with PCOS (9 %) had BMI >30 kg/m2. Body weight (P= 0·009), BMI (P= 0·033), waist circumference (P= 0·005) and WHR (P= 0·039) were significantly higher in the PCOS group than those in the control group (Table 1).

Table 1 Demographic and clinical characteristics of the control and polycystic ovary syndrome (PCOS) by BMI category (Mean values and standard deviations)

WHR, waist:hip ratio; FSH, follicle-stimulating hormone; LH, luteinising hormone; SHBG, sex hormone-binding globulin; FAI, free androgen index; HOMA-IR, homeostasis model assessment of insulin resistance.

* Mean value was significantly different from that of the BMI < 22 kg/m2 subgroup in the same group (P< 0·05; one-way ANOVA and Fisher's least significant different test).

Mean value was significantly different from that of the same BMI subgroup of the control group (P< 0·05; one-way ANOVA and Fisher's least significant different test).Mean value was significantly different from that of the control group (total): ‡ P< 0·05, ‡‡ P< 0·0001 (Student's t test).

The PCOS group had significantly increased serum LH (P< 0·0001), LH:FSH (P< 0·0001), testosterone (P= 0·036) and FAI (P< 0·0001), but lowered serum SHBG (P= 0·002) compared with the control group (Table 1). The control group with BMI ≥ 22 kg/m2 had significantly decreased serum FSH level (P= 0·033) compared with those with BMI < 22 kg/m2. Both control and PCOS groups with BMI ≥ 22 kg/m2 had significantly decreased serum SHBG levels (P< 0·0001 and P= 0·033 for the control and PCOS groups) compared with the corresponding groups with BMI < 22 kg/m2. The PCOS group with BMI ≥ 22 kg/m2 had elevated serum LH (P= 0·0005), LH:FSH (P= 0·009) and FAI (P< 0·0001) compared with the control group with BMI ≥ 22 kg/m2.

The PCOS group had significantly elevated 2-h serum glucose (P= 0·048), fasting insulin (P= 0·004) and HOMA-IR (P= 0·004) compared with the control group (Table 1). The control group with BMI ≥ 22 kg/m2 had increased fasting glucose (P= 0·004), 2-h serum glucose (P= 0·003), fasting insulin (P= 0·002), 2-h serum insulin (P= 0·001) and HOMA-IR (P= 0·001) compared with those with BMI < 22 kg/m2. The PCOS group with BMI ≥ 22 kg/m2 had significantly elevated 2-h serum glucose (P= 0·002), fasting insulin (P= 0·015), 2-h serum insulin (P= 0·009) and HOMA-IR (P= 0·007) compared with the corresponding group with BMI < 22 kg/m2.

Comparing the two subgroups with serum testosterone level ≤ 1·7 or >1·7 nmol/l, the PCOS group with the mean serum testosterone level of 2·4 nmol/l had significantly higher serum LH level (P= 0·012), LH:FSH (P= 0·008) and FAI (P= 0·003) than the group with the mean serum testosterone level of 1·3 nmol/l (Table 2). However, there were no significant differences in anthropometric measurements, FSH, SHBG, glucose metabolism and dietary intake between two subgroups with serum testosterone level ≤ 1·7 or >1·7 nmol/l in women with PCOS.

Table 2 Demographic and clinical characteristics of the polycystic ovary syndrome group (n 45) by serum testosterone level (Mean values and standard deviations)

WHR, waist:hip ratio; FSH, follicle-stimulating hormone; LH, luteinising hormone; SHBG, sex hormone-binding globulin; FAI, free androgen index; HOMA-IR, homeostasis model assessment of insulin resistance.

Mean value was significantly different from that of the testosterone ≤ 1·7 nmol/l subgroup: * P< 0·05, ** P< 0·0001 (Student's t test).

Dietary intake

The PCOS group had significantly lower daily intakes of energy (6311 (sd 1408) v. 6766 (sd 1080) kJ/d; P= 0·002) (Fig. 1(a)) and carbohydrate (191 (sd 50) v. 222 (sd 45) g/d, P< 0·0001; 51·5 (sd 8·9) v. 55·0 (sd 6·0) % of energy, P< 0·0001) (Fig. 1(b) and (c)), but a higher fat intake (30·8 (sd 7·9) v. 28·3 (sd 5·1) % of energy; P= 0·0003) (Fig. 1(c)) than the control group. However, fat intake in terms of g/d did not differ between the control and PCOS groups (51 (sd 11) v. 53 (sd 17) g/d). Protein intake in the control and PCOS groups (68 (sd 17) v. 67 (sd 19) g/d; 17·3 (sd 7·3) v. 17·6 (sd 4·2) % of energy) did not differ.

Fig. 1 Daily dietary intake for (a) total energy, (b) macronutrients (g/d) and (c) macronutrients (% of energy) in the control (n 161; □) and polycystic ovary syndrome (PCOS) (n 45; ) groups. Data are means, with standard deviations represented by vertical bars. Mean value was significantly different from that of the control group: ** P< 0·01, *** P< 0·0001 (Student's t test).

Correlations between clinical measurements and anthropometric parameters or dietary intake

Serum FSH level was negatively associated with body weight (r − 0·19; P= 0·016), BMI (r − 0·21; P= 0·006), fasting insulin (r − 0·19; P= 0·014), 2-h serum insulin (r − 0·21; P= 0·007) and HOMA-IR (r − 0·18; P= 0·022), but positively associated with protein intake (g/d) (r 0·19; P= 0·018) in the control group (Table 3). Serum LH level was negatively correlated with body weight (r − 0·16; P= 0·041), BMI (r − 0·20; P= 0·013), waist circumference (r − 0·21; P= 0·009) and WHR (r − 0·16; P= 0·048) in the control group. Serum testosterone level was significantly negatively associated with age (r − 0·25; P= 0·001), WHR (r − 0·18; P= 0·018), energy intake (r − 0·18; P= 0·024) and carbohydrate intake (g/d) (r − 0·20; P= 0·013), but positively associated with protein intake (% of energy) (r 0·20; P= 0·010) in the control group. Serum SHBG level was negatively correlated with body weight (r − 0·43, P= 0·0001 v. r − 0·59, P< 0·0001), BMI (r − 0·43 v. r − 0·59; P< 0·0001), waist circumference (r − 0·42, P< 0·0001 v. r − 0·55, P= 0·0002), WHR (r − 0·22, P= 0·031 v. r − 0·37, P= 0·006), 2-h serum glucose (r − 0·32, P< 0·0001 v. r − 0·33, P= 0·029), 2-h serum insulin (r − 0·34, P< 0·0001 v. r − 0·35, P= 0·019) and HOMA-IR (r − 0·36, P< 0·0001 v. r − 0·29, P= 0·049) in the control and PCOS groups. However, FAI was positively correlated with body weight (r 0·40 v. 0·55; P< 0·0001), BMI (r 0·38, P< 0·0001 v. r 0·52, P= 0·0002) and waist circumference (r 0·39, P< 0·0001 v. r 0·46, P= 0·001), 2-h serum glucose (r 0·21, P= 0·008 v. r 0·37, P= 0·013), fasting insulin (r 0·38, P< 0·0001 v. r 0·41, P< 0·05), 2-h serum insulin (r 0·30, P= 0·0001 v. 0·54, P= 0·0001) and HOMA-IR (r 0·39, P< 0·0001 v. r 0·38, P= 0·009) in the control and PCOS groups. FAI was negatively associated with fat intake (g/d) (r − 0·15; P= 0·048) in women with PCOS.

Table 3 Relationships between sex hormones and characteristics, glucose metabolic parameters, or dietary intake in the control (n 161) and polycystic ovary syndrome (PCOS; n 45) groups (Pearson's correlation coefficients (r))

FSH, follicle-stimulating hormone; LH, luteinising hormone; SHBG, sex hormone-binding globulin; FAI, free androgen index; WHR, waist:hip ratio; HOMA-IR, homeostasis model assessment of insulin resistance.

P< 0·05, ** P< 0·01, *** P< 0·001.

Fasting glucose level was positively correlated with body weight (r 0·19; P= 0·018) and BMI (r 0·15; P= 0·043) in the control group (Table 4). The levels of 2-h serum glucose, fasting insulin, 2-h serum insulin and HOMA-IR were positively associated with body weight (r 0·18–0·30, P= 0·001–0·020 v. r 0·37–0·61, P< 0·0001–0·012), BMI (r 0·19–0·33, P< 0·0001–0·01 v. r 0·45–0·64, P< 0·0001–0·002) and waist circumference (r 0·27–0·34, P< 0·0001–0·0006 v. r 0·37–0·55, P< 0·0001–0·012) in the control and PCOS groups. Fasting insulin level and HOMA-IR were positively correlated with WHR (r 0·18, P= 0·031–0·038 v. r 0·40–0·41, P= 0·005–0·006) in the control and PCOS groups.

Table 4 Relationships between blood glucose, insulin, or insulin resistance and characteristics or dietary intake in the control (n 161) and polycystic ovary syndrome (PCOS; n 45) groups (Pearson's correlation coefficients (r))

HOMA-IR, homeostasis model assessment of insulin resistance; WHR, waist:hip ratio.

P< 0·05, ** P< 0·01, *** P< 0·001.

Protein intake in terms of g/d and percentage of energy was negatively associated with fasting insulin (r − 0·19, P= 0·018 v. r − 0·16, P= 0·039) and HOMA-IR (r − 0·18, P= 0·025 v. r − 0·15, P= 0·052) in the control group (Table 4). However, energy and macronutrient intakes were not significantly correlated with glucose metabolic parameters in women with PCOS.

The multiple linear regression analysis showed that serum LH level tended to be negatively associated with WHR (β − 14·325; P= 0·052) in the control group (Table 5). Serum testosterone level was negatively correlated with age (β − 0·029; P= 0·010) and energy intake (β − 0·0001; P= 0·017) in the control group. Serum SHBG level was negatively associated with BMI (β − 2·764; P= 0·001) and fasting insulin level (β − 0·279; P= 0·022) in the control group. Serum testosterone level was negatively associated with age (β − 0·279; P= 0·008) and 2-h insulin level (β − 0·279; P= 0·025) in the PCOS group. Serum SHBG level was only negatively associated with BMI (β − 3·394; P= 0·007) in the PCOS group, and a correlation (β − 6·325; P= 0·009) also existed in the PCOS group with serum testosterone level ≤ 1·7 nmol/l (Table 6). Serum SHBG level was negatively correlated with macronutrient intake (carbohydrate: β − 4404·103, P= 0·043; protein: β − 4520·923, P= 0·047; fat: β − 4376·076, P= 0·044) in the PCOS group with serum testosterone level >1·7 nmol/l. Consistent with the findings using a simple linear regression model, the results indicated that BMI was a better predictive indicator for serum SHBG level in both the control and PCOS groups. Serum FSH level was negatively associated with WHR (β − 29·323; P= 0·043) in the PCOS group with serum testosterone level >1·7 nmol/l. However, serum LH level was not significantly associated with characteristics (age, BMI and WHR), glucose metabolic parameters (blood glucose and insulin levels) and dietary intake (energy and macronutrients) in the PCOS group with or without hyperandrogenism.

Table 5 Relationships between sex hormones and independent variables including characteristics, glucose metabolic parameters and dietary intake in the control and polycystic ovary syndrome (PCOS) groups using a multiple linear regression model (Regression coefficients (β))

FSH, follicle-stimulating hormone; LH, luteinising hormone; SHBG, sex hormone-binding globulin; WHR, waist:hip ratio.

P< 0·05, ** P< 0·01, *** P< 0·001.

Table 6 Relationships between sex hormones and independent variables including characteristics, metabolic parameters and dietary intake in the polycystic ovary syndrome group (n 45) by serum testosterone level using a multiple linear regression model (Regression coefficients (β))

FSH, follicle-stimulating hormone; LH, luteinising hormone; SHBG, sex hormone-binding globulin; WHR, waist:hip ratio.

P< 0·05, ** P< 0·01.

Discussion

Similar to the findings of previous studies(Reference Legro, Kunselman and Dodson5, Reference Lee, Oh and Sung19, Reference Cupisti, Kajaia and Dittrich20), women with PCOS had higher BMI than control women. Some of the studies have demonstrated that obesity commonly exists in 30–70 % women with PCOS(Reference Azziz, Woods and Reyna4, Reference Vrbikova and Hainer6, Reference Cupisti, Kajaia and Dittrich20Reference Kelestimur, Unluhizarci and Baybuga22). However, our data showed that only 13 % women with PCOS had BMI ≥ 27 kg/m2 and most women with PCOS were non-obese (BMI 23·0 (sd 4·4) kg/m2), which is consistent with the study of women with PCOS (BMI 22·7 (sd 4·1) kg/m2) in southern China(Reference Chen, Yang and Mo23). Therefore, the prevalence of obesity in women with PCOS is different between Chinese and Caucasian women. Overweight and obesity in women with PCOS exacerbated the severity of hyperandrogenism and impaired the metabolic profiles(Reference O'Connor, Gibney and Roche24). The present study showed that women with PCOS also had higher waist circumference and WHR than control women, indicating that women with PCOS could have more abdominal fat. In addition, FAI was positively correlated with BMI, waist circumference and HOMA-IR in women with PCOS. Regardless of overweight or obesity, the development of PCOS was strongly associated with weight gain and abdominal fat was correlated with hyperandrogenism and insulin resistance in women with PCOS(Reference Barber, McCarthy and Wass25, Reference Diamanti-Kandarakis26).

The clinical measurements varied due to different ethnic groups, BMI and hormone levels. The PCOS group with the mean age of 32·7 years and the mean BMI of 23·0 kg/m2 in the present study had higher mean serum FSH (6·8 v. 5·0 IU/l), LH (7·3 v. 6·2 IU/l), testosterone (1·8 v. 1·4 nmol/l) and SHBG (49·4 v. 20·4 nmol/l) levels, but lower FAI (4·68 v. 7·38) and HOMA-IR (1·8 v. 3·3) compared with PCOS patients with a mean age of 27·7 years and a mean BMI of 34·1 kg/m2 in Bahrain(Reference Golbahar, Al-Ayadhi and Das27). The PCOS group in the present study had a higher mean FSH level (6·8 v. 5·0 IU/l), but lower LH level (7·3 v. 13·0 IU/l), LH:FSH (1·1 v. 2·6), testosterone (1·8 v. 3·2 nmol/l) and FAI (4·68 v. 11·3) compared with PCOS patients with a mean age of 32·2 years and a mean BMI of 29·9 kg/m2 in the UK(Reference Nardo, Buckett and White28). The PCOS group in the present study had lower BMI and FAI compared with the previous studies(Reference Golbahar, Al-Ayadhi and Das27, Reference Nardo, Buckett and White28), which is consistent with our findings that FAI was reduced with decreased BMI in women with PCOS.

The present study demonstrated that women with PCOS had higher serum LH, LH:FSH, serum testosterone and FAI and lower serum SHBG levels, which is consistent with hormonal changes for the diagnosis of PCOS. A previous study found that obese women with PCOS had significantly higher serum total testosterone levels than non-obese women with PCOS(Reference Liou, Tang and Hsieh29). However, the present study showed that in the PCOS group serum testosterone level was not significantly different in the group with BMI ≥ 22 kg/m2 compared with the group with BMI < 22 kg/m2, which is consistent with our findings that serum testosterone level was associated with neither BMI nor waist circumference in women with PCOS. The different findings could be attributed to different proportions of overweight and obese women with PCOS and degree of hyperandrogenism.

The changes in hormones including serum SHBG and FAI were greater in women with PCOS with BMI ≥ 22 kg/m2 compared with those with BMI < 22 kg/m2, suggesting that hormonal changes are strongly associated with BMI. In agreement with a previous study(Reference Ducluzeau, Cousin and Malvoisin30), serum SHBG level was negatively associated with body weight, BMI and waist circumference, while FAI was positively associated with these parameters mentioned above, in women with PCOS. In addition, as compared with women with PCOS who had BMI < 22 kg/m2, those with BMI ≥ 22 kg/m2 had significantly increased 2-h serum glucose, fasting insulin, 2-h serum insulin and HOMA-IR which were positively correlated with body weight, BMI and waist circumference. Women with PCOS and impaired glucose metabolism had higher incidences of glucose intolerance and type 2 diabetes mellitus(Reference Legro, Kunselman and Dodson5, Reference Wei, Young and Kuo31). Therefore, it is reasonable to suspect that increased BMI in women with PCOS impairs insulin sensitivity which can further influence hyperandrogenism. Insulin insensitivity was found to possibly contribute to hyperandrogenism(Reference Legro, Castracane and Kauffman32). Elevated insulin level and HOMA-IR in women with PCOS who had higher BMI values in the present study could contribute to the increases in serum testosterone and FAI. Increased insulin level also possibly leads to lower serum SHBG. There was a strong negative correlation between fasting insulin level and serum SHBG in obese hyperandrogenic women(Reference Pugeat, Crave and Elmidani33) and women with PCOS(Reference Jayagopal, Kilpatrick and Jennings34). Martens et al. (Reference Martens, Geller and Arlt35) hypothesised that serine hyperphosphorylation of cytochrome P450c17 increasing 17,20-lyase activity and androgen production may cause hyperandrogenism and serine hyperphosphorylation of insulin receptor-β inhibiting its tyrosine phosphorylation may cause insulin resistance in women with PCOS.

A previous study in the UK reported that women with PCOS who had a mean BMI of 27·4 kg/m2 consumed 38 % of energy intake from fat(Reference Barr, Hart and Reeves36), which was higher than that (31 %) in those with the mean BMI of 23·0 kg/m2 in the present study. Similar to the present results for macronutrient intake (18, 31 and 51 % of energy intake from protein, fat and carbohydrate, respectively) in women with PCOS, a previous study in Italy showed that habitual intake for protein, fat and carbohydrate was 16, 33 and 52 % of energy intake, which was a similar distribution between women with PCOS and hypothalamic amenorrhea(Reference Colombo, Pinelli and Comelli37). The consumption of energy and macronutrients was not significantly different between women with PCOS and age-, race- and BMI-matched healthy women in the study by Douglas et al. (Reference Douglas, Norris and Oster38). However, women with PCOS consumed more high-glycaemic index foods, such as white bread (7·9 (sd 4·4) v. 5·5 (sd 2·9) servings over 4 d; P< 0·05) and fried potatoes (1·0 (sd 1·5) v. 0·4 (sd 0·7) servings over 4 d; P= 0·07) than did the healthy control group(Reference Douglas, Norris and Oster38). The present study found that women with PCOS had lower energy and carbohydrate intake but higher fat intake than infertile women without PCOS. The different findings between the study by Douglas et al. (Reference Douglas, Norris and Oster38) and the present study could be due to different anthropometric characteristics (race: mostly white Americans v. Chinese, age: 28·9 v. 32·7–34·7 years and BMI: 29·1–29·7 v. 21·3–23·0 kg/m2), dietary habits (different cuisines), biochemical data (fasting glucose and insulin levels, HOMA-IR: 2·9–4·6 v. 1·37–1·81) and comparing subjects (healthy v. non-PCOS-related infertile women). However, the present study only used 3-d dietary record to assess dietary intake, but did not use a FFQ, particularly for sweets and high-glycaemic index foods, which could be further studied.

Compared with the results of the Nutrition and Health Survey in Taiwan 2005–2008, the average energy intake (1617 kcal/d; 6766 kJ/d) in the control group with the mean age of 34·7 years was very similar to that (1671 kcal/d; 6991 kJ/d) in healthy women aged 31–64 years(Reference Wu, Pan and Yeh39). The average energy intake in both the control and PCOS groups (1617 v. 1508 kcal/d; 6766 v. 6311 kJ/d) fell within the current dietary reference intake in Taiwan for energy (1450–2100 kcal/d; 6070–8790 kJ/d) in women aged 31–50 years(Reference Wang40). The average intake (g/d) for carbohydrate, fat and protein was 102, 88 and 96 % in the control group (222, 51 and 68 g/d) compared with those (218, 58 and 71 g/d) in healthy women aged 31 to 64 years in Taiwan(Reference Wu, Pan and Yeh39), while the PCOS group had 88, 91 and 94 % of the average intake for carbohydrate, fat and protein (191, 53 and 67 g/d). However, energy intake from carbohydrate, fat and protein in women with PCOS (51·5, 30·8 and 17·6 %) was close to those (51·8, 31·2 and 17·0 %) in healthy women aged 31–64 years in Taiwan.

Weight loss through energy restriction has been demonstrated to positively affect metabolic and hormonal profiles in women with PCOS(Reference O'Connor, Gibney and Roche24). The present study revealed that women with PCOS had lower intakes of energy, carbohydrate and percentage of energy from carbohydrate but a higher percentage of energy from fat. However, women with PCOS had higher BMI and waist circumference. This is probably due to decreased energy intake for weight loss in non-obese women with PCOS and higher BMI. However, the measurement error of using dietary records for dietary assessment cannot be ruled out, although the 3-d dietary record reflects current dietary intake more accurately and specifically than dietary recall and FFQ. Dietary composition and energy distribution from macronutrients could also contribute to higher BMI in women with PCOS. However, in agreement with the present study, daily intake of energy and macronutrients has not been found to be associated with insulin resistance(Reference Douglas, Norris and Oster38, Reference Toscani, Mario and Radavelli-Bagatini41). Other nutrients or food components, such as dietary fibre and antioxidants, could cause metabolic and hormonal changes in women with PCOS. Protein intake was negatively correlated with fasting insulin level and HOMA-IR in the control group but not in women with PCOS, indicating that there could be various relationships between dietary intake and glucose metabolic parameters in the control and PCOS groups due to different anthropometric, metabolic and nutritional status.

Due to the different proportions of overweight and obese women with PCOS and degree of hyperandrogenism between the present study and others carried out in Europid populations, generalisation of the present results is considered to be limited for those non-obese women with PCOS. In conclusion, women with PCOS have lower serum SHBG levels negatively correlated with HOMA-IR and higher FAI positively correlated with HOMA-IR compared with those with non-PCOS-related infertility. Women with PCOS have lower energy and carbohydrate intakes but higher fat intakes, and macronutrient intake is only negatively associated with serum SHBG level in the PCOS group with hyperandrogenism. To minimise the influence of BMI and hyperandrogenism, the comparisons between non-obese and obese women with PCOS and between those with and without hyperandrogenism should be studied further to investigate whether dietary intake or habit is associated with the morbidity of PCOS. In addition, only 3-d dietary records were used for dietary intake evaluation in the present study; 7-d weighed food diaries could be considered for the assessment of dietary habit and under-reporting in women with PCOS in a future study.

Acknowledgements

This research received no specific grant from any funding agency in the public, commercial or not-for-profit sectors. Y.-H. T. and T.-W. W. participated in data collection, biochemical and statistical analysis of data and preparation of the manuscript. H.-J. W. participated in the concept and design of the study, recruitment and screening of the subjects, interpretation of data and revision of the manuscript. C.-Y. H., H.-J. H. and W.-H. C. participated in statistical analysis and interpretation of data. R. Y. and C.-M. L. participated in data collection and subject screening. J. C.-J. C. participated in the concept and design of the study, interpretation of data and critical revision of the manuscript. None of the authors has declared a conflict of interest.

References

1Rotterdam ESHRE/ASRM-Sponsored PCOS Consensus Workshop Group (2004) Revised 2003 consensus on diagnostic criteria and long-term health risks related to polycystic ovary syndrome. Fertil Steril 81, 1925.CrossRefGoogle Scholar
2Knochenhauer, ES, Key, TJ, Kahsar-Miller, M, et al. (1998) Prevalence of the polycystic ovary syndrome in unselected black and white women of the southeastern United States: a prospective study. J Clin Endocrinol Metab 83, 30783082.Google Scholar
3March, WA, Moore, VM, Willson, KJ, et al. (2010) The prevalence of polycystic ovary syndrome in a community sample assessed under contrasting diagnostic criteria. Hum Reprod 25, 544551.Google Scholar
4Azziz, R, Woods, KS, Reyna, R, et al. (2004) The prevalence and features of the polycystic ovary syndrome in an unselected population. J Clin Endocrinol Metab 89, 27452749.Google Scholar
5Legro, RS, Kunselman, AR, Dodson, WC, et al. (1999) Prevalence and predictors of risk for type 2 diabetes mellitus and impaired glucose tolerance in polycystic ovary syndrome: a prospective, controlled study in 254 affected women. J Clin Endocrinol Metab 84, 165169.Google ScholarPubMed
6Vrbikova, J & Hainer, V (2009) Obesity and polycystic ovary syndrome. Obes Facts 2, 2635.Google Scholar
7Remsberg, KE, Talbott, EO, Zborowski, JV, et al. (2002) Evidence for competing effects of body mass, hyperinsulinemia, insulin resistance, and androgens on leptin levels among lean, overweight, and obese women with polycystic ovary syndrome. Fertil Steril 78, 479486.Google Scholar
8Hahn, S, Tan, S, Elsenbruch, S, et al. (2005) Clinical and biochemical characterization of women with polycystic ovary syndrome in North Rhine-Westphalia. Horm Metab Res 37, 438444.Google Scholar
9Ni, RM, Mo, Y, Chen, X, et al. (2009) Low prevalence of the metabolic syndrome but high occurrence of various metabolic disorders in Chinese women with polycystic ovary syndrome. Eur J Endocrinol 161, 411418.Google Scholar
10Dunaif, A (1997) Insulin resistance and the polycystic ovary syndrome: mechanism and implications for pathogenesis. Endocr Rev 18, 774800.Google Scholar
11Ovalle, F & Azziz, R (2002) Insulin resistance, polycystic ovary syndrome, and type 2 diabetes mellitus. Fertil Steril 77, 10951105.Google Scholar
12Chang, RJ, Nakamura, RM, Judd, HL, et al. (1983) Insulin resistance in nonobese patients with polycystic ovarian disease. J Clin Endocrinol Metab 57, 356359.CrossRefGoogle ScholarPubMed
13Galluzzo, A, Amato, MC & Giordano, C (2008) Insulin resistance and polycystic ovary syndrome. Nutr Metab Cardio Dis 18, 511518.Google Scholar
14Thomson, RL, Buckley, JD & Brinkworth, GD (2011) Exercise for the treatment and management of overweight women with polycystic ovary syndrome: a review of the literature. Obes Rev 12, e202e210.Google Scholar
15Moran, LJ, Noakes, M, Clifton, PM, et al. (2006) Short-term meal replacements followed by dietary macronutrient restriction enhance weight loss in polycystic ovary syndrome. Am J Clin Nutr 84, 7787.Google Scholar
16Marsh, KA, Steinbeck, KS, Atkinson, FS, et al. (2010) Effect of a low glycemic index compared with a conventional healthy diet on polycystic ovary syndrome. Am J Clin Nutr 92, 8392.Google Scholar
17Matthews, DR, Hosker, JP, Rudenski, AS, et al. (1985) Homeostasis model assessment: insulin resistance and β-cell function from fasting plasma glucose and insulin concentrations in man. Diabetologia 28, 412419.CrossRefGoogle ScholarPubMed
18Hatch, R, Rosenfield, RL, Kim, MH, et al. (1981) Hirsutism: implications, etiology, and management. Am J Obstet Gynecol 140, 815830.CrossRefGoogle ScholarPubMed
19Lee, H, Oh, JY, Sung, YA, et al. (2009) The prevalence and risk factors for glucose intolerance in young Korean women with polycystic ovary syndrome. Endocrine 36, 326332.Google Scholar
20Cupisti, S, Kajaia, N, Dittrich, R, et al. (2008) Body mass index and ovarian function are associated with endocrine and metabolic abnormalities in women with hyperandrogenic syndrome. Eur J Endocrinol 158, 711719.Google Scholar
21Carmina, E, Legro, RS, Stamets, K, et al. (2003) Difference in body weight between American and Italian women with polycystic ovary syndrome: influence of the diet. Hum Reprod 18, 22892293.CrossRefGoogle ScholarPubMed
22Kelestimur, F, Unluhizarci, K, Baybuga, H, et al. (2006) Prevalence of polycystic ovarian changes and polycystic ovary syndrome in premenopausal women with treated type 2 diabetes mellitus. Fertil Steril 86, 405410.Google Scholar
23Chen, X, Yang, D, Mo, Y, et al. (2008) Prevalence of polycystic ovary syndrome in unselected women from southern China. Eur J Obstet Gynecol Reprod Biol 139, 5964.Google Scholar
24O'Connor, A, Gibney, J & Roche, HM (2010) Metabolic and hormonal aspects of polycystic ovary syndrome: the impact of diet. Proc Nutr Soc 69, 628635.Google Scholar
25Barber, TM, McCarthy, MI, Wass, JAH, et al. (2006) Obesity and polycystic ovary syndrome. Clin Endocrinol 65, 137145.Google Scholar
26Diamanti-Kandarakis, E (2007) Role of obesity and adiposity in polycystic ovary syndrome. Int J Obes (Lond) 31, S8S13.CrossRefGoogle ScholarPubMed
27Golbahar, J, Al-Ayadhi, M, Das, NM, et al. (2012) Sensitive and specific markers for insulin resistance, hyperandrogenemia, and inappropriate gonadotrophin secretion in women with polycystic ovary syndrome: a case–control study from Bahrain. Int J Women's Health 4, 201206.Google Scholar
28Nardo, LG, Buckett, WM, White, D, et al. (2002) Three-dimensional assessment of ultrasound features in women with clomiphene citrate-resistant polycystic ovarian syndrome (PCOS): ovarian stromal volume does not correlate with biochemical indices. Hum Reprod 17, 10521055.Google Scholar
29Liou, TH, Tang, JH, Hsieh, CH, et al. (2009) Clinical and biochemical presentation of polycystic ovary syndrome among obese and nonobese women. Fertil Steril 92, 19601965.Google Scholar
30Ducluzeau, PH, Cousin, P, Malvoisin, E, et al. (2003) Glucose-to-insulin ratio rather than sex hormone-binding globulin and adiponectin levels is the best predictor of insulin resistance in nonobese women with polycystic ovary syndrome. J Clin Endocrinol Metab 88, 36263631.Google Scholar
31Wei, HJ, Young, R, Kuo, IL, et al. (2009) Prevalence of insulin resistance and determination of risk factors for glucose intolerance in polycystic ovary syndrome: a cross-sectional study of Chinese infertility patients. Fertil Steril 91, 18641868.Google Scholar
32Legro, RS, Castracane, VD & Kauffman, RP (2004) Detecting insulin resistance in polycystic ovary syndrome: purposes and pitfalls. Obstet Gynecol Surv 59, 141154.Google Scholar
33Pugeat, M, Crave, JC, Elmidani, M, et al. (1991) Pathophysiology of sex hormone binding globulin (SHBG): relation to insulin. J Steroid Biochem Mol Biol 40, 841849.Google Scholar
34Jayagopal, V, Kilpatrick, ES, Jennings, PE, et al. (2003) The biological variation of testosterone and sex hormone-binding globulin (SHBG) in polycystic ovarian syndrome: implications for SHBG as a surrogate marker of insulin resistance. J Clin Endocrinol Metab 88, 15281533.CrossRefGoogle ScholarPubMed
35Martens, JW, Geller, DH, Arlt, W, et al. (2000) Enzymatic activities of P450c17 stably expressed in fibroblasts from patients with the polycystic ovary syndrome. J Clin Endocrinol Metab 85, 43384346.Google Scholar
36Barr, S, Hart, K, Reeves, S, et al. (2011) Habitual dietary intake, eating pattern and physical activity of women with polycystic ovary syndrome. Eur J Clin Nutr 65, 11261132.Google Scholar
37Colombo, O, Pinelli, G, Comelli, M, et al. (2009) Dietary intakes in infertile women a pilot study. Nutr J 8, 53.Google Scholar
38Douglas, CC, Norris, LE, Oster, RA, et al. (2006) Difference in dietary intake between women with polycystic ovary syndrome and healthy controls. Fertil Steril 86, 411417.Google Scholar
39Wu, SJ, Pan, WH, Yeh, NH, et al. (2011) Trends in nutrient and dietary intake among adults and the elderly: from NAHSIT 1993–1996 to 2005–2008. Asia Pac J Clin Nutr 20, 251265.Google Scholar
40Wang, GS (editor) (2012) Dietary Reference Intakes. 7th ed.Taipei, Taiwan: Food and Drug Administration, Department of Health, Taiwan, R.O.C.Google Scholar
41Toscani, MK, Mario, FM, Radavelli-Bagatini, S, et al. (2011) Insulin resistance is not strictly associated with energy intake or dietary macronutrient composition in women with polycystic ovary syndrome. Nutr Res 31, 97103.Google Scholar
Figure 0

Table 1 Demographic and clinical characteristics of the control and polycystic ovary syndrome (PCOS) by BMI category (Mean values and standard deviations)

Figure 1

Table 2 Demographic and clinical characteristics of the polycystic ovary syndrome group (n 45) by serum testosterone level (Mean values and standard deviations)

Figure 2

Fig. 1 Daily dietary intake for (a) total energy, (b) macronutrients (g/d) and (c) macronutrients (% of energy) in the control (n 161; □) and polycystic ovary syndrome (PCOS) (n 45; ) groups. Data are means, with standard deviations represented by vertical bars. Mean value was significantly different from that of the control group: ** P< 0·01, *** P< 0·0001 (Student's t test).

Figure 3

Table 3 Relationships between sex hormones and characteristics, glucose metabolic parameters, or dietary intake in the control (n 161) and polycystic ovary syndrome (PCOS; n 45) groups (Pearson's correlation coefficients (r))

Figure 4

Table 4 Relationships between blood glucose, insulin, or insulin resistance and characteristics or dietary intake in the control (n 161) and polycystic ovary syndrome (PCOS; n 45) groups (Pearson's correlation coefficients (r))

Figure 5

Table 5 Relationships between sex hormones and independent variables including characteristics, glucose metabolic parameters and dietary intake in the control and polycystic ovary syndrome (PCOS) groups using a multiple linear regression model (Regression coefficients (β))

Figure 6

Table 6 Relationships between sex hormones and independent variables including characteristics, metabolic parameters and dietary intake in the polycystic ovary syndrome group (n 45) by serum testosterone level using a multiple linear regression model (Regression coefficients (β))