Systematic Review
Metformin Treatment for Obesity in Children and Adolescents: A Meta-analysis and Review of Literature
Department of Pharmaceutics, Qaasim University, P.O. Box 1627, Hail, 81441, Saudi Arabia
INTRODUCTION
Childhood obesity has become a major health problem worldwide (Morrison et al., 2008; Steinberger et al., 2009). Adverse health issues associated with the consequences of childhood obesity are observed in populations in all continents. These include type 2 Diabetes Mellitus and cardiovascular disease (Dixon, 2010). In addition, there is an increased incidence of elevated blood pressure, insulin resistance and dyslipidemia, all of these are the components constitute metabolic syndrome. Studies show that metabolic syndrome is an independent risk factor for the development of cardiovascular disease (Huang et al., 2009; Schubert et al., 2009).
Behavioral modification and lifestyle changes represent current approaches utilized to ameliorate the obesity and associated co-morbidities. Strategies focusing on low-caloric diets high in fruits and vegetables along with exercise have great potential to reduce fat mass but unfortunately these efforts have demonstrated limited efficacy (Savoye et al., 2007; Wilfley et al., 2007; McGovern et al., 2008; Kalarchian et al., 2009). This has led to a keen interest in the development of newer and more effective approaches. In this regard, chemotherapeutic regimens have always remained a priority in research. Metformin has received a good deal of attention due to its potential therapeutic role in pediatric obesity management (August et al., 2008).
Metformin suppresses hepatic glucose production at high concentrations (DeFronzo et al., 1991), improves peripheral insulin sensitivity (Cigolini et al., 1984) and reduces weight gain in adults with type 2 Diabetes Mellitus (UKPDS Group, 1998; Golay, 2008). Metformin has also demonstrated weight stabilization or a mild weight reduction characteristics in adults with (DeFronzo and Goodman, 1995; Stumvoll et al., 1995; Lee and Morley, 1998; DPPRG, 2012) and without diabetes (Munro et al., 1969; Fontbonne et al., 1996). A number of Randomized Controlled Trials (RCTs) have been carried out in obese, non-diabetic, insulin-resistant pediatric and adolescent populations (Lutjens and Smith, 1977; Freemark and Bursey, 2001; Srinivasan et al., 2006; Fu et al., 2007; Atabek and Pirgon, 2008; Love-Osborne et al., 2008; Wilson et al., 2010; Rezvanian et al., 2010; Yanovski et al., 2011). However, the variability of outcomes in these studies necessitates to conduct a meta-analysis of these results in order to improve the state of the evidence. The present systematic review and meta-analysis of pooled data from these randomized controlled trials has been conducted in order to examine the evidence of metformin efficacy in childhood/adolescence obesity. In addition, meta-regression analysis has also been carried out to explore independent predictors of metformin efficacy.
MATERIALS AND METHODS
Literature search and study selection: A systematic literature search for relevant double-blind studies published during 2001 and 2012 was conducted in PUBMED and EMBASE digital databases. Eleven search terms relating to overweight, obesity, diabetes and metformin were used to retrieve articles reporting RCTs evaluating the efficacy of metformin in obese children/adolescents (age = 19 years). Additional articles were manually searched by from the reference lists of identified papers. The search was restricted to articles published in English language. Studies that included diabetics or those with secondary causes of obesity were excluded from this analysis. Moreover, of the selected studies, only randomized phase trials of metformin treatment have been taken into consideration for this meta-analysis. Primary outcomes of interest were BMI (weight in kilograms divided by the height in squared meters; kg m-2), homeostasis model of assessment-insulin resistance (HOMA-IR; glucose X insulin/22.5) and fasting insulin levels. Secondary outcomes consisted of total triglyceride levels, total cholesterol levels, LDL-cholesterol levels, HDL-cholesterol and blood pressure, systolic as well as diastolic.
Statistical analysis: The analysis was conducted using STATA Version 9.1 (College Station, Texas) and Tableau (Seattle, Washington) software. Methods of analyses comprised meta-analysis (fixed effects model as well as random effect model) for the determination of statistical significance between metformin treatment and several variables of study outcomes and meta-regression analysis for the determination of impact of several independent variables on metformin treatment. Briefly, to calculate effect size, differences in means and standard errors were calculated for each study. Weights for each study were calculated as inverse variance. The synthesized data were subjected to the homogeneity test (random IV heterogeneity methods). The outcomes were compared by using Cohen, Hedges and the Glass statistics. For meta-regression analysis, random effect model was used. Between-study variance and coefficients were estimated by weighted least squares. This software uses residual (restricted) maximum likelihood (ReML) as a default algorithm component and is also powered by moments technique. Post-estimation tools utilized to strengthen the results also included empirical Bayes (EmBayes) estimates.
RESULTS
The literature search finally led to the identification of nine studies, eight of which met the criteria for inclusion in this meta-analysis (Table 1). Results of these studies were published between 2001 and 2011. Five of the eight studies were conducted in the United States (Freemark and Bursey, 2001; Srinivasan et al., 2006; Love-Osborne et al., 2008; Wilson et al., 2010; Yanovski et al., 2011), one in China (Fu et al., 2007), one in Iran, (Rezvanian et al., 2010) and one in Turkey (Atabek and Pirgon, 2008). Six of these trials utilized a treatment design that was complemented with behavioral modifications and lifestyle changes. Study intervention duration ranged from 12-52 weeks. Study population size ranged from 28 to 348 participants. Participants ranged in age from 6 to 19 years. Six of the studies stratified patients by gender. The highest proportion of female participants was 72% (Love-Osborne et al., 2008) and the lowest 40% (Fu et al., 2007). Four studies stratified patients by their ethnic backgrounds. The highest proportion of minority participants was 90% (Love-Osborne et al., 2008) while the lowest 45% (Freemark and Bursey, 2001). Minority participants were defined as those with the following racial backgrounds: Hispanic, African-American, Native American, Asian, Pacific Islander and Indian Subcontinent.
Almost all of the studies revealed a good deal of tolerability of metformin treatment as the side effects were lesser as well as well-manageable. A synthesis of the prevalence of most important side effects reported in all these studies has been presented in Table 2.
Meta-analysis
Effects of metformin treatment on BMI, HOMA-IR and fasting insulin levels: Overall, both the models of the meta-analysis comprising of eight RCTs of 12-52 weeks duration identified a significant effect of metformin treatment in reducing BMI with effect size ranged in magnitude from -3.17 kg m-2 (Fu et al., 2007) to -0.16 kg m-2 (Love-Osborne et al., 2008). The fixed effects pooled results demonstrated a drop in BMI of 1.08 kg m-2 with a 95% confidence interval of -1.14 and -0.03 kg m-2 (p<0.01). The Random effect model demonstrated a larger effect size with a value of -1.46 kg m-2 and confidence interval of -1.91 to -1.01 kg m-2 (p<0.01). Only one study (Love-Osborne et al., 2008) failed to demonstrate a statistically significant association) between the metformin treatment and BMI reduction (Table 3).
In a fixed effects model, the analysis showed a decrease of 1.06 (p<0.002) HOMA-IR while the random effects model did not reveal any statistically significant relation between metformin treatment and HOMA-IR though it resulted in an effect size of -2.57 (p = 0.07)(Table 4). As far as the effect of metformin on fasting insulin levels is concerned, the meta-analysis revealed fixed effect value of -4.47 (p<0.002) and random effects value of -7.13 (p<0.005) (Table 4).
Effect of metformin on cholesterol, triglycerides and blood pressure: Not all studies mentioned data regarding the effect of metformin on lipid profile; cholesterol (4 studies), HDL/LDL (4 studies) and two studies reported pre- and post-treatment blood pressure data. The effect of metformin treatment was found to be significant in reducing total cholesterol levels (ES -0.87; CI -12.53 to 3.46; P<0.003) and increasing HDL cholesterol levels (ES 1.5; CI 0.28 to 2.71; p = 0.02). However, no statistically significant correlation was observed in the meta-analysis of the metformin treatment effect on triglycerides (ES -0.38; CI -1.11 to 0.35; p = 0.31), LDL cholesterol (ES -0.79; CI -4.14 to 2.57; p = 0.65), systolic blood pressure (ES -0.19; CI -1.09 to 0.72; p = 0.69) and diastolic blood pressure (ES 0.32; CI -0.32 to 0.76; p = 0.42).
Meta-regression: Meta-regression analysis was carried out in order to explore independent variables that might have exerted impacts on the efficacy of metformin treatment in selected eight RCTs. Of the nine variable (weight, mean age, initial BMI, sample size, percentage of females, attrition rate, behavioral interventions, length of study, percent minority participants), at 95% confidence level, only sample size (coefficient = -0.01; t = -2.53; p = 0.05) and female gender (coefficient = 10.68; t = 6.23; p<0.001) were recognized as independent variables to regress metformin efficacy. Other variables that had no effect on the magnitude of the metformin induced change in BMI included initial weight (p = 0.11), initial BMI (p = 0.12), mean age (p = 0.18), racial composition of the total sample (p = 0.51), study attrition rate (p = 0.47), behavioral intervention (p = 0.40) and study length (p = 0.46). Meta-regression analysis also failed to demonstrate any statistically significant association between higher metformin dosage and attrition rate (p = 0.34; Fig. 1a), higher metformin dosage and gastrointestinal side effect incidence trend (p = 0.75; Fig. 1b) and attrition rate of the participants because of the side effects prevalence (p = 0.82; Fig. 1c).
DISCUSSION
Obesity is no more rarely associated with the development of metabolic syndrome, a problem that predisposes individuals to the development of cardiovascular disease in later years (Huang et al., 2009; Schubert et al., 2009). Moreover, the risk of the development of Type 2 diabetes in an overweight individual is directly proportional to the severity of the obese state (Zimmet et al., 1992; Srinivasan et al., 1999). Treatment of childhood obesity along with its associated comorbid illnesses is therefore of paramount importance. In this regard, the present systematic review and meta-analysis of the published RCTs serve to shed light on metformin treatment as a potential therapeutic intervention in this hyperinsulinemic, obese patient population.
Meta-analysis using both pooled fixed and random effects models demonstrated that metformin therapy produced a statistically significant decline in BMI in the treated participants of study population. The fixed effects results demonstrated that metformin treatment was associated with BMI decline of 1.08 kg m-2 with a 95% confidence interval of -1.14 to -1.03 kg m-2 (p<0.01). The random effects model revealed a larger effect; -1.46 kg m-2 BMI decline with confidence interval of -1.91 kg m-2 to -1.01 kg m-2 (p<0.01). Previously, in a meta-analysis conducted by Park et al. (2009) a significant metformin therapeutic effect (1.42 kg m-2) has been reported which is similar in magnitude to that of achieved in our study.
Dietary modifications, lifestyle changes and exercise comprise an integral component of the overall long term management of obesity and metabolic syndrome. The findings of this review serve to reiterate that metformin may substantiate other strategic interventions such as behavioral modifications and dietary changes. Though meta-regression analysis fails to provide any significant association between metformin induced change in BMI seen herein with behavioral interventions (p = 0.86), yet several lines of evidence suggest that there could be multi-mechanisms of metformin mode of action. Love-Osborne et al. (2008) have reported non-significant effect of metformin on BMI overall but they found a significant effect in individuals who observed lifestyle changes such as those who reduced portion size. In the study of Fu et al. (2007), 23.3% participants under metformin treatment reported reduced appetite. There is some evidence that metformin may also act to reduce food intake in obese subjects (Paolisso et al., 1998).
A meta-analysis of 64 RCTs performed by Oude Luttikhuis et al. (2009) encompassing over five thousand participants showed that medication alone may not be as effective as behavioral interventions in reducing BMI. They noted effects sizes of Orlistat and sibutramine as -0.76 kg m-2 (-1.07 to -0.44) and -1.66 kg m-2 (-1.89 to -1.43), respectively following 6 months treatments. McGovern et al. (2008) examined the data from three studies and failed to find any notable metformin effect after 6 months of treatment; -0.17 kg m-2 (95% CI -0.62 to -0.28). Sukkari et al. (2010) have also reported a greater benefit for lifestyle intervention when compared with metformin treatment. Behavioral interventions have shown effect up to -3.04 kg m-2 (95% CI -3.14 to -2.94) at 6 months and at 12 months of follow-up.
In this meta-analysis, the HOMA-IR data taken from four studies (Srinivasan et al., 2006; Fu et al., 2007; ERFC, 2010; Yanovski et al., 2011) revealed no statistically significant metformin effect while two (Freemark and Bursey, 2001; Atabek and Pirgon, 2008) reported a strong metformin effect. Though, in a fixed effects model, based on these six studies, a statistically significant metformin effect has been noted, the random effects model did not reveal significant effect. Keeping in view a great deal of disparity in participant characteristics, it is reasonable to give more credence to the random effects result (Riley et al., 2011).
All four studies (Freemark and Bursey, 2001; Srinivasan et al., 2006; Fu et al., 2007; Atabek and Pirgon, 2008) that reported baseline and end of metformin treatment fasting insulin levels yielded a statistically significant association. In aggregate, a strong metformin effect on this parameter has been noticed. In addition, a metformin induced significant effect was also seen in total cholesterol (p<0.003) and HDL cholesterol (p = 0.02) levels.
The meta-regression outcomes indicated that the percentage of female participants was directly associated with increased metformin efficacy (p = 0.003). This observation owes its major weight from the study of Love-Osborne et al. (2008) who found that females were twice as likely as males to decrease their BMI by 5% and were less likely to gain weight as compared to males. This gender-biased metformin effect has also been reported in another study (Freemark and Bursey, 2001). The reason for these differences is not as clear. This may be attributed to the effects on leptin levels in metformin treated girls as is observed by Fu et al. (2007). It is well-established that leptin levels in the young adolescents remain higher in females as compared to males (Carlsson et al., 1997; Kiess et al., 1998).
The incidence of serious side effects was found to be extremely rare. Minor gastrointestinal side effects were common in study patients and present a statistically significantly greater number taking metformin when compared with those taking placebo. The higher prevalence rates of side effects are generally implicated for higher attrition rates in many clinical trials. In the present study, however, meta-regression analysis did not reveal a significant association between the incidence of gastrointestinal side effects and attrition rate. There was also no significant correlation between the dosage of metformin and the frequency of gastrointestinal side effects as well.
CONCLUSION
The present study revealed that sample size served as an independent variable in the assessment of metformin efficacy. The relatively small number of patients in the pooled analysis may have served to obscure the true potency of this medication. In addition, there may not have been sufficient statistical power to detect other relevant treatment effects. Nonetheless, these results are encouraging; metformin demonstrated significant efficacy with only minor associated side effects. In future, larger studies are recommended to evaluate the significance; not only on metformin but also on second generation sulfonylureas such as glipizide, to definitively determine their role in the treatment of obesity in this patient population.