Background
Chronic heart failure (CHF) refers to a pathologic condition that cardiac output is absolute or relative reduce and cannot meet the whole body tissue metabolism under the normal venous return, then result in decreasing the myocardial contractile force and ventricular compliance, ultimately dyspnea, edema, feeble and so on. It was estimated that five-year survival rate of CHF was lower as malignant tumor and CHF was a main reason of disability and death on a global scale [
1‐
3]. Impaired cardiac function of CHF patients may lessen their ability of daily living and render them a heavy economic pressure [
1,
4]. At present, the primary aims of alleviating CHF symptoms are to inhibit myocardial remodeling, and perfect cardiac function [
5]
. Therefore, angiotensin-converting enzyme inhibitors (ACEIs), angiotensin II receptor blockers (ARBs), digoxin, and diuretics are become standard western medicine (WM) treatment in CHF [
6], while it cannot obtain a desired effect own to poor compliance, lower heart rate of patients and others questions [
5]. In consideration of its limitations, the application of Chinese herbal injections (CHIs) could be promoted. Currently, a combination between CHIs and WM treatment has already been a supportive measure in treatment of CHF in China. In accordance with traditional Chinese medicine (TCM) theories, CHF pertain to “heart impediment (xin bi)”, “palpitation”, “edema” and so forth, which caused by heart and then affect others organs. The clinical principle is to strengthen the body resistance to eliminate pathogenic factors [
2]. Due to the relative low recognition of CHIs in CHF, this study selected six CHIs commonly used in CHF treatment, all of them were authorized by China Food and Drug Administration (CFDA), namely Huangqi injection (HQI), Shenfu injection (SFI), Shengmai injection (SI), Shenmai injection (SMI), Shenqi Fuzheng injection (SQFZI), Yiqifumai injection (YQFMI), to explore and rank their efficacy in CHF by the approach of network meta-analysis (NMA). Compared with conventional pairwise meta-analysis, NMA can sort the interventions via indirect comparison [
7]
. At the same time, the clinical trials compared those six CHIs head to head was lack. Thus, an attempt to conduct a NMA was necessarily. The goal of this study was to provide evidence-based hierarchies of the comparative efficacy and more insights for selection of CHF treatment.
Methods
The study was congrunt with The Prisma Extension Statement for Reporting of Systematic Reviews Incorporating Network Meta-analyses of Health Care Interventions [
8]. And the Prisma check list was displayed in Additional file
1.
Eligibility criteria and study selection
A study was considered eligible if it suited for these criteria: 1) randomized controlled trial (RCT); 2) patients enrolled were diagnosed as CHF according to “Guidelines on the Diagnosis and Treatment of Heart Failure” conducted by The Chinese medical association cardiovascular epidemiology branch in 2014 [
9] or “Clinical Guideline of New Drugs for Traditional Chinese Medicine” released by CFDA in 2002 [
10]. Both of them contained both western diagnostics, the latter included TCM diagnostics as well; 3) patients receive WM treatment (e.g. cardiotonic, diuretic, ACEIs, β-blocker and so forth), meanwhile patients needed relevant therapy if they had complications during therapeutic process. On the basis of it, the treatment group received one of the included CHIs, the control group received another or just adopted WM. Besides, the dosages of CHIs were reported; 4) RCTs tested the clinical effective rate. The clinical effective rate calculated by this formula: (number of remarkable recovery patients + number of basic recovery patients) / total number of patients * 100%. Cardiac function classification was conformed to the standard issued by New York Heart Association (NYHA) in the United States. Clinical symptoms disappeared and cardiac function improved 2 levels at least was deemed as the class of remarkable recovery, clinical symptoms relieved and cardiac function increase 1 level was classified into the part of basic recovery, clinical symptoms and cardiac function was unaltered or worse belonged to deterioration. Besides, the incidence of left ventricular ejection fraction (LVEF), cardiac output (CO), stroke volume (SV), 6-min walk test (6MWT), brain natriuretic peptide (BNP), left ventricular end-diastolic dimension (LVEDD), left ventricular end- systolic dimension (LVESD), adverse drug reactions/adverse drug events (ADRs/ADEs) were also evaluated. The clinical effective rate and LVEF were regarded as dominating outcomes of the study, because the clinical effective rate can inflect the efficacy directly and LVEF was a main indicator for CHF. And others were counted as secondary outcomes. A study was excluded when it met these following criteria: 1) the study without full text; 2) duplicated reports; 3) RCTs with incomplete or inaccurate data; 4) RCTs with wrong sequence generation method. For example, sequence generated by odd or even date of birth, some rules based on date (or day) of admission and so forth; 5) patients received physiotherapy, acupuncture and moxibustion therapy, and Chinese materia medica preparation.
A comprehensive literatures searching was carried out in seven database including Embase, the Cochrane Library, Pubmed, Chinese Biological Medicine Database (CBM), China National Knowledge Infrastructure (CNKI), Wanfang Database, Chinese Scientific Journal Database (VIP) from their inception up to June 12nd 2017. In addition, there was no restriction on language. The method that incorporated the medical subject headings (MeSH) term and the free text was applied in searching process, and it would vary from different databases. Each searching item included three parts of terms that chronic heart failure, CHIs, and randomization. Detailed searching strategies were illustrated in Additional file
2.
After literatures duplicate checking, the rest literatures were firstly screened by titles and abstracts, reviews, irrelevant literatures and animals’ experiments reports were excluded. Literatures passed the initial filtration were read full text in order to sort out the eligible RCTs. Two reviewers undertook literature selection respectively, any divergences resolved by discussion or the third reviewer.
Data extraction and quality assessment
Information from the eligible RCTs was extracted based on a custom-made form. The data consisted of the following items: 1) basic information of the eligibility: the first author, nationality, publication year, study desgin; 2) basic characteristics of patients: sample size, gender composition, average age, course of disease, primary diseases, cardiac function classification; 3) detail of RCTs’ intervention; 4) outcomes results and RCTs’ quality assessment.
The quality analysis was assessed with the Cochrane Collaboration’s tools (version 5.1.0 the Nordic Chchrane Center, the Cochrane Collaboration, 2012 Copenhagen, Denmark) by two reviewers independently. The tool comprised following these 7 items: 1) the method of randomization; 2) the concealment of random allocation; 3) the blinding method for patients and clinicians; 4) the blinding method for assessor; 5) the integrality of outcomes data; 6) the condition of selective reporting; 7) others bias. Each item was rated as “high risk”, “low risk” and “unclear”. And any difference between two reviewers settled by discussion or the third reviewer.
It is not necessary for this meta-analysis to obtain an ethical approval, because this study was the procedure that just gathered the clinical data in each RCT without any leak of patients’ information.
Statistical analysis
NMA was performed with Stata software (version 12, Stata Corporation, College Station, Texas, U.S.) and Winbugs (version 1.4, MRC Biostatistics Unit, Cambridge, UK) software by using Mantel-Haenszel random-effects model. In Winbugs software, the number of iteration was set as 50,000, the first 20,000 was used for annealing algorithm in order to eliminate the impact of initial value. For binary outcomes, the pooled results were calculated as odds ratios (ORs). For continuous outcomes, mean differences (MD) were used. Both types of outcomes were presented with their 95% credible intervals (95% CIs) as well. Besides, the network graph showed indirect comparative relationship between different interventions was described. The node area of each intervention on behalf of its number of patients, and the thickness between different interventions represented the number of relative RCTs [
11]. To rank various CHIs in treatment in CHF, the surface under the cumulative ranking curve (SUCRA) was utilized, which expressed each intervention’s efficacy with percentages. A larger area of SCUAR indicated that corresponding intervention was more preferable in certain outcomes [
12]. After that, the funnel plots were depicted to reflect publication bias. Due to non-close loops in this NMA, the assumption of consistency between direct and indirect evidence was not utilized.
Discussion
The impairment of CHF has been a global public health issue [
125], with the utilization of a conjunction between CHIs and WM in its treatment, the efficacy of CHF has been promoted, meanwhile, more and more relevant RCTs and pairwise meta-analysis were carried out. But almost RCTs concerned about the efficacy between a kind of CHI plus WM and WM, many CHIs have not been compared head to head. Thus, researchers could merely figure out the efficacy of a CHI based on these RCTs via pairwise meta-analysis. While NMA can address this void, the efficacy of CHIs can be obtained at a time based on indirect comparison. By comparing with WM, the efficacy of CHIs for CHF and their rank can be demonstrated. we conducted a NMA in order to appraise the efficacy and safety of seven interventions: HQI + WM, SFI + WM, SI + WM, SMI + WM, SQFZI+WM, YQFMI+WM and WM.
This study made an extensive literature review and evaluation. The clinical data derived from 113 RCTs in the aspects of the clinical effective rate, LVEF, CO, SV, 6MWT, BNP, as well as the value of LVEDD and LVESD. CO, SV, LVEDD and LVESD was regarded as a supplement of cardiac condition, while the consequence of LVEDD and LVESD was no significant difference in most cases, these two outcomes’ results were merely deemed as a reference. Besides, 6MWT was vital indicator of patients’ recovery, and its importance was emphasized in the guide [
9], though the amount of relevant RCTs in this study was small and its statistical power was low, we just treat it as a secondary outcome. In addition, the measurement of BNP was highlighted in guide as an exclusion for CHF [
126]. Therefore, we viewed it as a secondary index as well. In terms of the primary outcomes, SI + WM and SMI + WM exhibited superior performance. What more, these two interventions did a noteworthy effect on CO and SV. And SI + WM also obtained a first-rank with respect to 6MWT. Overall, on the basis of receiving WM, CHF patients received SI or SMI may be more efficacious. Both of them were approved by CFDA on the market of CHF. SI was derived from Shengmai San which has been widely used for cardiovascular diseases since 1186 in China [
127]. It was mainly made from the extractive of
Panax ginseng, Radix Ophiopogonis and
Schisandra chinensis, and had a function as replenishing qi-yin deficiency. Pharmacological researches have confirmed that SI had features in perfecting cardiac function and alleviating heart failure, enhancing myocardial contractility and cardiac pumping [
128]. Under the guideline of TCM, SI was employed in CHF treatment routinely with its preferable curative effect, and several pairwise meta-analysis manifested that a conjunctive between SI and WM owned a superior capability on increasing the effective rate and LVEF [
128‐
130]. As for SMI, it stemmed from Shenmai Yin which was prescribed by Simiao Sun in the Tang Dynasty [
131], and its ingredients did not contain
Schisandra chinensis compared with SI, but it also had a superior capacity in nourishing yin and benefiting qi. Upon pharmacological researches, the effect of SMI on promoting myocardial contractility and antiarrhythmic action has been verified [
132]. Besides, several pairwise meta-analysis demonstrated that SMI plus WM exhibited a better performance in improving the effective rate, LVEF, CO, SV and decreasing BNP than WM [
133‐
135].
Apart from efficacy, the safety of interventions was the other crucial element that must be considered in clinical trials. In this study, the occurrence rate of ADRs/ADEs was small, but about 64% of the research did not report the ADRs/ADEs. Hence, we could not draw a certain conclusion on it. As suggested in previous study, anaphylaxis was the main ADRs/ADEs of CHIs, and it would appear within 30 min at first time [
136‐
139]. Hence, it is crucial for clinicians to monitor the ADRs/ADEs after using CHIs. Meanwhile, it is necessary to reported exactly if ADRs/ADEs occurred [
136].
Upon the design and contents, three merits enhanced the creditable of this study. Firstly, this study made a comprehensive literature search and a contrast for six CHIs which have been already adopted in CHF treatment. Besides, this study expressed the efficacy of CHIs objectively due to the relevant large number of eligible RCTs. Furthermore, a strict eligibility criterion was formulated before implementing NMA. The consistency of the intervention and the curative standard lowered the clinical heterogeneity. What’s more, it was significant that the outcomes demonstrated cardiac condition in multiaspect. According to corresponding conclusions, this study provided several clinical suggestions for treatment in CHF.
Limitation
Nevertheless, there was still insufficient in this study. Frist, the enrolled patients in RCTs were merely Chinese, which may lead to a bias on whether non-Chinese use eligible CHIs effectively or not. Although CHIs was mostly adopted in China, clinicians also can not only recruit Chinese. Next, just ten of included RCTs reported 6MWT in this study. While it is 6MWT, and readmission rate that associate with CHF patients closely and influence patients’ survival quality. Thus, these aspects should be paid more emphasis when RCTs are designed. In addition, the methodological quality was general, and most included RCTs did not mention the details of randomization and allocation concealment, which may generate an overestimate for eligible CHIs. It should be note that clinicians utilize low risk randomization and concealment method as possible. Based on the limitations, the RCTs conducted in the future should be perfected in relevant areas.