Berberine and Metformin in the Treatment of Type 2 Diabetes Mellitus: A Systemic Review and Meta-Analysis of Randomized Clinical Trials ()
1. Introduction
The incidence of type 2 diabetes mellitus (T2DM) is increasing rapidly worldwide. Thirty years ago, T2DM was a fairly rare occurrence in adults and was almost undocumented in children [1]. In 2010, 285 million people with T2DM comprised approximately 90% of diabetes worldwide [2]. The results of Chronic Disease and the risk factors in China in 2013 showed that the prevalence rate of diabetes in adult group was 10.4% and increased to 11.2% in 2017 [3]. The global prevalence of diabetes is estimated to rise to 592 million by the year 2035, and there will be more than 500 million patients with T2DM [2].
Metformin, a derivative of biguanide, is one of the most commonly used drugs to treat T2DM, and it has been used for nearly one century [4]. Guanidine was found to have anti-diabetic properties in animals in 1918. But unfortunately, it was toxic in clinical trials [5]. This prompted scientists to find safer substitutions. In the 1920, metformin (1, 1-dimethyl biguanide hydrochloride) was synthesized. Since then, metformin became the first choice to treat T2DM due to its remarkable ability to decrease plasma glucose levels [6]. In recent years, many additional unexpected but effective roles of metformin were found. Studies showed that metformin exerts a strong effect on numerous cancer [7], cardiavascular disease (CVD) [8], liver disease [9], obesity [10] and renal disease [11]. Sole medication or combination therapy with other drugs has shown to be effective to treat different diseases.
Berberine (BBR, molecular formula: C20H19NO5, molecular weight: 353.36), an isoquinoline alkaloid originally isolated from the Chinese herb Coptis chinensis (Huanglian), is one of the main components of R. coptidis [12]. Berberine has been used in traditional Chinese, Indian, and middle-eastern folk medicine for more than 400 years. Its chemical structure as a quaternary base is quite different from other commonly used hypoglycemic agents, such as sulfonylureas, biguanides, thiazolidinediones, or acarbose. Recent studies have demonstrated that berberine has remarkable effects as an anti-hyperglycemic and anti-hyperlipidemic and it reduces weight gain in T2DM [13] [14] [15]. In addition, the beneficial effects of berberine on cardiovascular, liver, and renal disease have been demonstrated in both pre-clinical and clinical research [16] [17] [18].
Berberine and metformin share many features in actions despite different structure and both could be excellent drugs in treating T2DM. Meanwhile, berberine can improve the intestinal intolerance of metformin [19]. The combination of the two drugs may bring better hypoglycemic effect. This research used the Cochrane systematic evaluation method and evaluated the efficacy and safety of berberine and metformin in treating T2DM in RCTs. It is important clinical significance for the development of diabetes therapy.
2. Materials and Methods
2.1. Inclusion Criteria
Studies were included if they fulfilled the following criteria: Randomized controlled trials (RCTs), irrespective of blinding; People with T2DM, preexisting or newly diagnosed; for the types of interventions, treatments with berberine alone or combined with metformin compared with metformin. Literature is either Chinese or English litersture. Some studies contained multiple groups and each group was considered as a separate study in the analysis. Studies were only included if the intervention was given for at least 8 weeks. To be consistent with changes in diagnostic criteria of T2DM through the years, the diagnosis should has been established using the diagnostic criteria valid at the time of the beginning of the trial [20]. The diagnosis criteria include WHO 1999 [21] and CDS 2013 [22].
The primary outcomes consisted of fasting plasma glucose levels (FPG), 2-hour postprandial plasma glucose (2hPG), glycosylated hemoglobin levels A1c (HbA1c). The secondary outcomes consisted of homeostasis model assessment of insulin resistance (HOMA-IR) and adverse effects.
2.2. Exclusion Criteria
The exclusion criteria were non-randominzed controlled trials and quasi-randomized controlled trials; abstracts or comments from conference papers; animal studies and obvious duplicate studies.
2.3. Search Strategy
We searched the following electronic databases for the identification of trials: PubMed, Excerpta Medica Database (EMBase), Cochrane Library, Chinese National Knowledge Infrastructure database (CNKI), WanFang, the Chinese Scientific and Technical Journals database (VIP), China Doctor Dissertation Full-text Database (CDFD) and China Master Dissertation Full-text Database (CMFD) from the inception to April 2021 in Chinese or English language. The following search terms were used: [“Berberine” or “Huangliansu” or “Xiaopojian”] and [“metformin” or “dimethyldiguanide”] and [“type 2 diabetes mellitus” or “T2DM” or “non-insulin-dependent diabetes mellitus”]. In addition, the reference lists from the articles were manually searched for further studies.
2.4. Data Extraction
Literature selecting: read the article title and abstract, eliminated the studies not meeting the inclusion/exclusion criteria. Two reviewers independently assessed trials for inclusion in the review. They extracted data concerning details of the sample size, interventions, duration of treatment, age and outcomes by using a standard Microsoft Excel (Microsoft Corporation, office 2016) file. Any disagreements were resolved by consensus, or if required by a third reviewer.
2.5. Quality Assessment
Bias is a systematic error other than random error that can lead to differences between research results and the real situation. There are many sources of bias, including selection bias, performance bias, detection bias, attrition bias and reporting bias. The quality of the included trials was assessed using the Cochrane risk bias tools (Review Mamager 5.4 provided by the Cochrane Collaboration) [23]. The criterias include random sequence generation (selection bias), allocation concealment (selection bias), blinding of participants and personnel (performance bias), blinding of outcome assessment (detection bias), incomplete outcome data (attrition bias), selective reporting (reporting bias) and other bias. We made judgement on each of these criterias relating to the risk of bias: low, high, or unclear (indicating unclear or unknown risk of bias).
2.6. Statistical Methods
We used the RevMan 5.4 meta-analysis sofeware to summarize the effects of berberine. Categorical variables used the odds ratio (OR) and continuous variables used the mean differences (MD) as analysis statistics. 95% confidence interval (95% CI) was used as effective size for the combined analysis. The clinical and methodological heterogeneity of the included studies was evaluated with Χ2 test and I2 test. The different berberine and/or metformin intervention metheods were used for sensitivity subgroup analysis. Reporting bias was explored through funnel plot analysis when the number of included trials exceeded ten. A fixed-effect model was used when the studies in the subgroup were sufficiently similar (I2 < 50%, P > 0.10). Otherwise, a random-effect model was used. When P < 0.05, it indicated that there was a significant difference between the two groups. Interval estimation and hypothesis test results were shown in the forest plot.
3. Results
3.1. Literature Search Results
The primary searches identified a total of 552 references. 137 articles were screened after 415 duplicates of the same articles were removed. According to the inclusion criteria, 124 records were excluded because they were not RCTs, animal studies, not set control group reasonable, reviews or comments. Finally, thirteen studies met the eligibility criteria and were included in the systematic review and meta-analysis. The flowchart of study search results was displayed in Figure 1.
3.2. Characteristics of the Included Studies
The thirteen studies, including eleven in Chinese and two in English, were published in 2008-2020. One study [27] was performed as multicenter and the other studies as single center. All studies were originated from the mainland of China. Tow studies adopted three-armed group design including berberine, berberine combined with metformin, and metformin [25] [29]. The other studies adopted two-armed paralled group design. According to the inclusion criteria, the two studies were analyzed as four trials [25] [29]. A total of 1173 T2DM patients were enrolled. Among them, 599 were in the experimental group and 574 in the control. All articles describled medication on the basis of diet and exercise. See Table 1.
Figure 1. Flow chart of the strategy used for the selection of studies used in the meta-analysis.
Table 1. Characteristics of the included trials.
Note: -, no record; BBR, berberine; Met, metformin; W, week; M, month; ① FPG; ② 2hPG; ③ HbA1c; ④ HOMA-IR; ⑤ adverse effects.
3.3. Risk of Bias in Included Studies
We used RevMan 5.4 to assess the risk of bias in the included thirteen studies according to the Cochrane Manual [23]. Most of the included trials were of poor quality. All the studies mentioned random assignment of participants. But only one study [35] described random sequence generation methods, such as random number tables. There was insufficient information to determine whether the randomizations were carried out correctly in the rest of the studies. All the trials were not describle the allocation concealment and blinding. Three studies [24] [27] [28] reported the number of withdrawals and drop-outs in each group. Four studies [24] [33] [34] [36] were not reported selectively. Two studies [27] [29] mentioned other biases. None of them reported the reseach plan and sample size estimation method. The risk of bias in included studies was shown in Figure 2.
3.4. Outcome Indicators
Thirteen studies (fifteen trials) were included in the study. The control groups were all metformin treatment. Considering that the intervention measures of berberine treatment were different, the influencing factors such as drug dosage and course of treatment could not be combined and analyzed. Therefore, the intervention types of experimental and control group were analyzed in subgroups, which were divided into berberine vs. metformin and berberine combined with metformin (berberine plus metformin) vs. metformin.
3.4.1. Efficacy of Berberine and Metformin Treatment on FPG
There were six trials compared the effect of berberine vs. metformin on FPG and nine trials for berberine combined with metformin vs. metformin. Due to high heterogenerty, I2 > 50%, random-effect (RE) model was used for the analysis. Subgroup analysis showed that berberine combined with metformin significantly reduced FPG leval compared with metformin group, [MD = −1.49, 95% CI (−2.22, −0.76), P < 0.0001]. There was no significant difference between berberine and metformin, [MD = 0.13, 95% CI (−0.27, 0.54), P = 0.53]. See Figure 3.
3.4.2. Efficacy of Berberine and Metformin Treatment on 2hPG
There were five trials compared the effect of berberine vs. metformin on 2hPG and nine trials for berberine combined with metformin vs. metformin. Due to high heterogenerty, I2 > 50%, random-effect (RE) model was used for the analysis. Subgroup analysis showed that berberine combined with metformin significantly reduced 2hPG leval compared with metformin group, [MD = −1.89, 95% CI (−2.94, −0.84), P = 0.0004]. There was no significant difference between berberine and metformin, [MD = 0.11, 95% CI (−1.38, 1.60), P = 0.88]. See Figure 4.
Figure 2. Risk of bias accessed using RevMan 5.4 according to the guidance in the Cochrane Handbook. Green represents low risk of bias, yellow represents unclear risk of bias, and red represents high risk of bias.
Figure 3. Forest plot of outcome measure FPG.
Figure 4. Forest plot of outcome measure 2hPG.
3.4.3. Efficacy of Berberine and Metformin Treatment on HbA1c
There were five trials compared the effect of berberine vs. metformin on HbA1c and seven trials for berberine combined with metformin vs. metformin. Due to high heterogenerty, I2 > 50%, random-effect (RE) model was used for the analysis. Subgroup analysis showed that berberine combined with metformin significantly reduced HbA1c leval compared with metformin group, [MD = −0.65, 95% CI (−0.91, −0.40), P < 0.00001]. There was no significant difference between berberine and metformin, [MD = −0.17, 95% CI (−0.49, 0.16), P = 0.31]. See Figure 5.
3.4.4. Efficacy of Berberine and Metformin Treatment on HOMA-IR
Only one trial compared the effect of berberine and metformin vs. metformin on HOMA-IR. There was sigificant difference between the two groups, [MD = −0.53, 95% CI (−1.03, −0.03), P = 0.04]. No trial compared the effect of berberine vs. metformin on HOMA-IR. See Figure 6.
Figure 5. Forest plot of outcome measure HbA1c.
Figure 6. Forest plot of outcome measure HOMA-IR.
3.4.5. Efficacy of Berberine and Metformin Treatment on Adverse Effects
Six trials reported the number of adverse effects and the other trials only stated a slight adverse effects of berberine without clear data. Due to high heterogenerty, I2 > 50%, random-effect (RE) model was used for the analysis. Subgroup analysis showed that there was no significant difference between berberine and metformin, [MD = 0.27, 95% CI (0.04, 1.84), P = 0.18]. The other subgroup, the adverse effects rate of berberine combined with metformin was significantly decreased, [MD = 0.41, 95% CI (0.18, 0.95), P = 0.04], compared with metformin group. All reported events were mild, including constipation, diarrhea, nausea and abdominal distension. No serious adverse effects were reported. See Figure 7.
3.5. Sensitivity Analysis
Sensitivity analysis was carried out by eliminating literature one by one. FPG and HbA1c for the subgroup of berberine vs. metformin, were significantly affected by the article, Cao Y [28]. The results changed from [P = 0.53, I2 = 71%, MD = −0.13, 95% CI (−0.27, 0.54)] and [P = 0.31, I2 = 70%, MD = −0.17, 95% CI (−0.49, 0.16)] to [P = 0.89, I2 = 50%, MD = −0.02, 95% CI (−0.33, 0.29)] and [P = 0.02, I2 = 52%, MD = −0.29, 95% CI (−0.53, −0.05)], respectively. After excluding the article, berberine could significantly reduce HbA1c of T2DM compared with metformin group. The adverse effect in the subgroup changed from [P = 0.18, I2 = 61%, OR = 0.27, 95% CI (0.04, 1.84)] to [P = 0.003, I2 = 0%, OR = 0.12, 95% CI (0.03, 0.49)] after removing the article, Jun Y [24]. There was no significant change in sensitivity analysis for the subgroup of berberine combined with metformin vs. metformin.
3.6. Publication Bias Analysis
A funnel plot was made for FPG in the fifteen trials included. Visual inspection
Figure 7. Forest plot of adverse effects.
showed obvious asymmtetry between the left and right sides of the symmetry axis, suggesting potential publication bias. See Figure 8.
4. Discussion
4.1. Summary of Evidence
Fifteen RCTs with 1173 participants evaluating the efficacy and safety of berberine and metformin in patients with T2DM were eligible and included. Meta-analysis showed that berberine combined with metformin remarkably lowered plasma concentrations of FPG [MD = −1.49, 95% CI (−2.22, −0.76), P < 0.0001], 2hPG [MD = −1.89, 95% CI (−2.94, −0.84), P = 0.0004], HbA1c [MD = −0.65, 95% CI (−0.91, −0.40), P < 0.00001] and HOMA-IR [MD = −0.53, 95% CI (−1.03, −0.03), P = 0.04]. But berberine monotherapy was not superior to metformin in the hypoglycemic effect. The incidence of adverse events did not differ between berberine and metformin group. However, berberine combined with metformin significantly reduced the incidence of adverse events, [MD = 0.41, 95% CI (0.18, 0.95), P = 0.04], in other subgroup. It is possible that berberine may prevent metformin-associated lactic acidosis in treatment of diabetes [37]. In a world, the adverse effects were commonly gastrointestinal discomforts including constipation, diarrhea, nausea and abdominal distension. No serious adverse effects from berberine and metformin were reported. These results indicate that berberine and metformin treatment is effective and safe for treating T2DM.
4.2. Comparison with Previous Studies
Our meta-anlysis has some strength in comparison with previous systematic
Figure 8. Funnel plot of outcome measure FPG.
review. The study included several newly-published trials and preformed subgroup analysis. The results of our meta-analysis are similar to those of Chen WN and Lan JR [38] [39], regarding FPG, 2hPG and HbA1c. We added HOMA-IR to evaluate the hypoglycemic effects, and berberine combined with metformin also significantly reduced HOMA-IR. But the level of evidence was not high because of only one study included. We carried out the sensitivity analysis by eliminating literature one by one. After excluding the article, Cao Y [27], FPG and HbA1c for the subgroup of berberine vs. metformin changed from [P = 0.53, I2 = 71%, MD = −0.13, 95% CI (−0.27, 0.54)] and [P = 0.31, I2 = 70%, MD = −0.17, 95% CI (−0.49, 0.16)] to [P = 0.89, I2 = 50%, MD = −0.02, 95% CI (−0.33, 0.29)] and [P = 0.02, I2 = 52%, MD = −0.29, 95% CI (−0.53, −0.05)], respectively. It is different from the previous analysis.
4.3. Limitations
There are several limitations that should be considered before recommending the conclusion of this review for clinical practice. First, appropriate randomization is necessary to avoid selection bias. Nevertheless, random sequence generation and allocation concealment were not reported in detail in the included trials. Most trials only stated that participants were randomly assigned, but without further details. Second, all the trials did not apply blinding; therefore, non-double-blinding may led to performance bias. Third, All the trials were conducted among Chinese participants in the mainland of China and they did not describle the study plan or publish a study protocol in advance; therefore, attrition bias and selective reporting bias might exist. Fourth, there was heterogeneity in the interventions, as can be seen from the primary characteristics of included trials. The optimal dose, optimal duration of berberine and metformin, even interactions between them requires further study. Finally, publication bias might exist in this review. Therefore all of the outcomes should be carefully interpreted based on substantial methodological and clinical diversity.
4.4. Implications for Research
This meta-analysis comprehensively quantified the efficacy and safety of berberine and metformin in the treatment of T2DM. Thirteen studies (fifteen trials) with 1173 participants were included. Although berberine plus metformin can remarkably improve blood sugar profiles, the evidence must be considered inconclusive. This is because the available studies had high heterogeneity and high risk of bias. Furthermore, the safety of the new drug, berberine, is unproven because of the lack of toxicological evidence, despite the fact that adverse events have been reported only rarely.
Further research should emphasize methodological quality, especially the methods of randomisation, allocation concealment, adequacy of blinding and sample size estimation, so that selection bias, performance bias, detection bias, attrition bias and reporting bias can be avoided. Moreover, registration of the trial protocol is essential to ensure reliability of trial results. Studies sample should be large with a long term follow-up to assess long term effects and safety of berberine and metformin. Finally, report strictly according to CONSORT [40] to improve the levels of evidence and clinical values.
5. Conclusion
The evidence from our meta-analysis suggests that berberine combined with metformin has a significant hypoglycemic effect and safety for T2DM. There is no obvious difference in hypoglycemia between berberine and metformin group. Due to the lack of high quality clinical trials, the efficacy of berberine alone or combined with metformin at treating T2DM remains to be validated. It needs to be further verified by high-quality, large sample size and multi-center RCTs.
Funding
This research was supported by a grant from the project of Administration of the Traditional Chinese Medicine of Guangdong Province of China (Grant No. 20191065).