Alpha7 nAChR Agonists for Cognitive Deficit and Negative Symptoms in Schizophrenia: A Meta-analysis of Randomized Double-blind Controlled Trials

Ye JIN, Qi WANG, Yan WANG, Mengxi LIU, Anji SUN, Zhongli GENG, Yiwei LIN, Xiaobai LI*

•SYSTEMATIC REVIEW AND META-ANALYSIS•

Alpha7 nAChR Agonists for Cognitive Deficit and Negative Symptoms in Schizophrenia: A Meta-analysis of Randomized Double-blind Controlled Trials

Ye JIN, Qi WANG, Yan WANG, Mengxi LIU, Anji SUN, Zhongli GENG, Yiwei LIN, Xiaobai LI*

schizophrenia; cognitive dysfunction; nicotinic agonists; meta-analysis

1. Introduction

The diagnosis of schizophrenia is generally believed to be based on positive and negative symptoms. Positive symptoms such as delusions and hallucinations are often the target of attention and treatment. However,negative symptoms, such as blunted affect and social avoidance; and cognitive symptoms, such as poor attention and disorientation are also distinct symptom domains. One schizophrenia subtype known as deficit schizophrenia (DS), represents a stable clinical subtype of schizophrenia that, in comparison with non-deficit schizophrenia, is associated with a greater impairment of neurocognitive abilities and social cognition, poorer response to treatment and worse outcome. This homogeneous subtype of the schizophrenic syndrome was introduced by Carpenter et al to distinguish the primary, enduring negative symptoms of schizophrenia(termed “deficit symptoms”) from the more transient negative symptoms secondary to other factors.[1]

In the long term, positive symptoms vary, whereas negative symptoms remain relatively constant, possibly related to medication intake. Currently approvedtreatments such as first- and second-generation antipsychotics are primarily efficacious[2]at treating positive symptoms but do not adequately improve cognition or negative symptoms in patients.[3,4]Thus,there is an urgent need to develop new therapeutic targets for the treatment of the full constellation of symptoms.

Some authors have reported that nAChRs stimulation of the brain dopamine receptor system normalizes a number of sensory processing deficits associated with schizophrenia, including sensory, PPI and eye- tracking deficits, the hypothesis of nAChR“hypofunction” in schizophrenia has stimulated the development of selective nicotinic receptor agonists as putative treatments for negative symptoms and cognitive dysfunction.[5]

One therapeutic target that has recently been found is the α7-nicotinic acetylcholine receptor (α7 receptor), which was first identified in animal models of a sensory gating deficit associated with schizophrenia.[6]α7 receptors are localized on the presynaptic and postsynaptic elements in the hippocampus and cerebral cortex, regions critical to the synaptic plasticity underlying learning and memory. In schizophrenia,α7 receptors protein expression is decreased with altered transcription seen in post-mortem brain samples. Additionally, α7 receptors are present on the pre- and postsynapses of neurons containing other neurotransmitters( g-aminobutyric acid, acetylcholine,glutamate) that are important for cognition.[7]Activation of the α7 receptors increases cholinergic neurotransmission and the release of glutamate (Glu)and dopamine (DA) exerts procognitive effects in rats.[8]

Notably, in the past several years, several compounds have been identified as α7-nicotinic acetylcholine receptor agonists. These compounds include encenicline, RG3487, TC-5619, ABT-126,DMXB-A and so on. Some phase 2 clinical trials have been conducted to investigate the procognitive effects of these new drugs adjunct to some second-generation antipsychotics. However, the outcomes published seem diverse. Here, we conduct a comprehensive metaanalysis to provide robust evidence on the effects of α7-nicotinic acetylcholine receptor agonists on cognitive functions and negative symptoms in patients with schizophrenia.

2. Methods

2.1 Criteria for considering studies

Study types considered for meta-analysis included all relevant randomized double-blind controlled trials with individuals who had a diagnosis of schizophrenia according the DSM-IV.[26]Types of interventions included were α7 nAChR agonists including encenicline,varenicline and tropisetron(4) or α7 nAChR positive allosteric modulators in combination with choline that were given orally, and adjunctively to ongoing stable antipsychotic treatment. Placebo was given as a control group.

Types of outcome measures included: (i) Primary outcome-Cognitive function: Mean change of scale overall scores from baseline to treatment endpoint in which cognitive function is measured. This was done mainly using the Measurement And Treatment Research to Improve Cognition in Schizophrenia(MATRICS)Consensus Cognitive Battery (MCCB). MCCB packaging 10 tests, is a method developed by the Measurement and Treatment Research to Improve Cognition in Schizophrenia (MATRICS) group to evaluate the efficacy of treatments targeting cognitive impairments in schizophrenia. It measures 7 cognitive domains: speed of processing, attention/vigilance, working memory,verbal learning, visual learning, reasoning and problem solving, and social cognition. This was a continuous outcome measure.[9]Studies which reported the scores change of the 7 domains should also be reported.

(ii) Secondary outcomes--Negative symptoms:Mean change of the positive and negative syndrome scale(PANSS) negative symptoms subscale score or Scale for the Assessment of Negative Symptoms(SANS)score from baseline to endpoint. PANSS is a scale used for measuring symptom severity for patients with schizophrenia. SANS is used specifically for the assessment of negative symptoms in schizophrenia.Safety and tolerability should also be reported as adverse event rates and dropout rates.

2.2 Search methods for identification of studies

Relevant randomized controlled trials were identified by searching several electronic databases (PubMed,Embase, ClinicalTrials.gov, the Cochrane Library and CNKI, WanFang Data, VIP Data) for papers published before May 26, 2017. Keywords included synonyms of“schizophrenia”, “α7-nicotinic acetylcholine receptor agonist”, and “cognitive dysfunction” (and the Chinese equivalents). A set of search terms were [(alpha7 OR alpha-7) AND agonist OR positive allosteric modulator OR encenicline(3) OR varenicline OR tropisetron(4))and (Schizophrenia OR Schizoaffective Disorder OR Schizophreniform Disorder OR Dementia Praecox)AND (random* OR RCT OR control* OR compare* OR placebo)] were also utilized. Various combinations of these keywords were used to search for articles.Limits were set for “clinical trials” and “humans” where applicable. Reference lists of retrieved studies and review articles were manually searched for additional studies relevant for meta-analysis.

2.3 Data collection and analysis

Selection of trials:

Two authors (JY and WQ) independently inspected the abstract of each reference identified by the search to see if the study was likely to be relevant. When it was unclear from an abstract whether a study was a randomised trial or if there was disagreement between the two authors, the full article was obtained. The article was then inspected independently by the two authors to assess its relevance to the analysis.

Data collection:

Both authors independently extracted the data from the included trials. Again, any disagreement was discussed, the decisions documented. The remaining problems were arbitrated by the third reviewer (LXB).

Data synthesis:

Meta-analysis: The meta-analysis was performed using Review Manager Version 5.3. Because the outcomes are continuous, standard mean differences were calculated using the inverse variance statistical method and random effects model to adjust for study heterogeneity. Unreported SD values were calculated from other available data in the articles (SD=SE×√N )according to the Cochrane Handbook for Systematic Reviews of Interventions(Chapters 7.7.3.2). Count data were shown by using relative risk (RR). The results of the combined calculation were shown in the forest plot.Two-sided 95% CIs were used to assess significance,according to whether the CIs included the null value.

Heterogeneity: Study heterogeneity was quantified for the outcome analysis using the I2statistic alongside the Chi2‘P’ value with I2⩾ 50% indicating significant heterogeneity.[29]When heterogeneity is present,sensitivity analyses should be conducted to assess potential influences of any one single study on the pooled MD and associated P-values, and if necessary,subgroup analyses should be conducted to explore the source of heterogeneity.[29]

Assessment of risk of bias: Included trials were assessed with the Cochrane Risk of Bias Tool for methodological quality of sequence generation,allocation concealment, blinding, incomplete outcome data, and selective reporting.[10]

The quality assessment of meta-analytic outcomes:The grading of recommendations assessment, and evaluation (GRADE) system was used to assess the quality of evidence for main outcomes.[11]The overall level of evidence was rated as ‘high’, ‘moderate’, ‘low’,or ‘very low’.

Assessment of publication biases: Publication biases arise when the dissemination of research findings is influenced by the nature and direction of results. We are aware that funnel plots may be useful in investigating publication biases but are of limited power to detect small-study effects. We intended not use funnel plots for outcomes where there were 10 or fewer studies, or where all studies were of similar sizes.[31]

3. Results

3.1 Characteristics of included studies

Eight double-blind randomized placebo-controlled trials were included. (total number of subjects, N=1438)[7,8,12-17]The PRISMA flow diagram is displayed in Figure 1. Study characteristics are summarized in Table 1.

All the included studies involved participants who had been diagnosed using operationalised criteria (DSMIV). Six different kinds of α7-nicotinic agonist were used as the intervention, varenicline,[12,13]tropisetron,[14,15]ABT-126,[7]encenicline,[8]TC-5619,[16]and RG3487.[17]The mean(sd) duration of the studies was 14.7(6.7)weeks (range: 8–24 weeks). 5 studies (Umbricht 2014,Haig 2016, Keefe 2015, Smith 2016 and Walling 2016)were included in the analysis of cognitive function,which used MCCB and CSB(Cogstate Schizophrenia Battery),[18]and 8 studies(Haig 2016, Walling 2015, Keefe 2015, Jeon 2016, Noroozian 2013, Shiina 2010, Walling 2016 and Smith 2016) were included in the analysis of negative symptoms, which used PANSS and SANS.

The controversial problem during data extraction process was that one study (Keefe, 2015) used LOCF[19](Last observation carried forward) analysis to achieve ITT( Intention-to Treat)[20]analysis. However, this method would lower the reliability of study outcomes.The decision was made by the third author (LXB) to include this LOCF outcome.

3.2 Risk of bias

The risks of bias of included studies are summarized in Table 2. Although all studies were randomized trials,the methodology of allocation concealment was often unreported, leading to ‘unclear risk’ for selection bias in 6 studies (75%). One study (12.5%) was judged to have ‘unclear risk’ for detection bias since the blinding of outcome assessment was unspecified. One study(12.5%) has attrition bias and 4 studies (50%) did not report other bias.

3.3 Meta-analyses

Primary outcome--Effects of α7-nicotinic agonist on cognitive function

There was no statistically significant difference favouring α7-nicotinic agonists in terms of overall cognitive function (SMD=-0.10[-0.46, 0.25], I2=88%)(Figure 2) in patients with schizophrenia according to MCCB overall scores. However, one study (Freedman 2008)[6]reported two domains (attention/vigilance and working memory) significantly improved over baseline with DMXB-A treatment, but it was only a secondary analysis using the results from one arm of the study with limited power.

Secondary outcome--Effects of α7-nicotinic agonist on negative symptoms

There was no statistically significant difference between α7-nicotinic agonists and placebo in terms of negative symptoms (SMD=0.13 [-0.04, 0.30], I2=64%) in patients with schizophrenia. (Figure 3)

Secondary outcome-- Tolerability and safety

Most adverse events reported in the articles were considered by study investigators to be mild or moderate in severity. Common adverse events include dizziness, headache, nausea, fatigue, nasopharyngitis and so on. We got data of adverse events and dropouts rates ofα7-nicotinic agonists as well as placebo in four studies (Umbricht 2014, Keefe 2015, Walling 2015 and Haig 2016). For the other four studies (Shiina 2010,Noroozian 2013, Smith 2016 and Jeon 2016), the overall adverse rates and dropouts rates were unclear. There were no statistically significant differences between α7-nicotinic agonist group and the placebo group in the incidence of adverse events (RR=1.02, p=0.84)(Figure.4)and dropouts(RR=1.04, p=0.88)(Figure.5).

Figure 1. Flowchart of literature search and exclusion process

Sensitivity analysis

In order to explain the heterogeneity of cognition outcome(I2=88%), sensitivity analysis was conducted,and after one outlier(SMD=-0.90 [-1.24, -0.57])study(Umbricht 2014) was removed, the results remained not statistically significant(SMD= 0.10 [-0.07,0.26], I2=37%). With regards to the negative symptoms outcome (I2=64%), sensitivity analysis also found the results remained not statistically significant (SMD=0.07[-0.01, 0.16], I2=0%) after removing one outlier study(SMD=1.78 [1.04, 2.53]), (Noroozian 2013).

Assessment of publication biases

There were only eight studies included in the metaanalysis, so it was not possible to assess publication bias using funnel plots (which requires at least ten studies).[30]However, we assume our results have publication biases in assessment of evidence quality using the GRADE approach.

Assessment of evidence quality

The evidence quality for 4 outcome measures as assessed by the GRADE approach were moderate. (Table 3)

4. Discussion

4.1 Main findings

To our knowledge, this is the first comprehensive meta-analysis to examine the effects of α7-nicotinic acetylcholine receptor agonists on both cognitive deficits and negative symptoms in patients with schizophrenia. As a whole, α7-nicotinic agonists were not found to be superior to placebo as an adjunctive therapy to antipsychotics in cognitive function (no statistically significant difference favoring α7 agonists)even after sensitivity analysis removing one outlier study(Umbricht 2014). Outcomes for negative symptoms[8,14]also showed no significant difference between this drug and placebo and sensitivity analysis indicated that this result was firm.

Table1. Characteristics of included studies

Table 2. Risk of bias summary

Figure 2. Effect of α7-nicotinic agonist on cognitive function

Figure 3. Effect of α7-nicotinic agonist on negative symptoms

Figure 4. Adverse events rates: α7-nicotinic agonists VS placebo

Figure 5. Dropouts rates: α7-nicotinic agonists VS placebo

Table 3. Summary of meta-analysis and GRADE assessments of quality of data

This result is consistent with a recent meta-analysis by Lewis and colleagues.[21]However, the present study has the additional advantage of analyzing the intervention’s effect on the negative symptoms of schizophrenia (besides cognition).

4.2 Limitations

The present report must be considered in light of various limitations. First, the number of included individual studies was small. Second, we did not examine the longterm effects of α7-nicotinic agonists since the duration of individual studies did not exceed 24 weeks. Third,influences of concomitant antipsychotics are not clear.Fourth, we cannot analyze the relationship between tobacco use and the effects of α7-nicotinic agonists because the articles we found provided insufficient data on nonsmokers. Fifth, we excluded 6 RCT studies,Deutsch 2008,[22]Shim 2012,[23]Preskorn 2014,[24]Lieberman 2013,[25]Freedman 2008,[6]Zhang 2012,[27]because the former 4 studies did not present enough data needed for meta-analysis and we were unable to successfully contact the authors. The fifth study was a crossover trial because we cannot ignore the long-term effect of this kind of agent[28]; and the last study used a Chinese version of the scales. Sixth, the scales we chose for our meta-analysis measuring cognition and negative symptoms were limited to MCCB, CSB, SANS and PANSS negative subscale, which did not make full use of the data given from many other scales. Seventh,the individual pharmacological profiles of these agents are likely to play a role in the pharmacodynamic heterogeneity; for example, TC-5619 is a full agonist at the a7nAChR, and EVP-6124 and RG3487 are partial agonists at this receptor, with differences in 5-HT3 receptor antagonism.[17]Eighth, the relationship between dose and effects of this drug cannot be ignored since some previous clinical studies divided subjects into different dose groups. Ninth, the study data we used for our meta-analysis was change scores from baseline which we were unclear if this data was skewed or not.Finally, a possibility of publication bias should not be dismissed.

4.3 Implications

In this meta-analysis, no statistical significant difference was found between α7-nicotinic acetylcholine receptor agonists and placebo for overall cognitive deficits and negative symptoms in patients with schizophrenia.However, some previous preclinical models and pharmaceutical phase II proof-of-concept trials have demonstrated a7nAChR agonist efficacy, and there are signals of clinical efficacy on several specific cognitive domains, such as attention. Previous studies[21]indicated that choice of dose and dosing frequency are critical to the demonstration of therapeutic effects in clinical trials. Further research, those for example, with a large sample and low heterogeneity are required to elucidate the role of α7-nicotinic agonists in schizophrenia and explain its mechanism.

Funding statement

This work was supported by the Natural Science Foundation of Liaoning Province (Project No.2015020481).

Conflict of interest statement

The authors claim no financial conflict of interests related to this manuscript.

Acknowledgment

We thank the reviewers of this analysis for their useful comments.

Authors’ contributions

Ye Jin contributed to the conception of the study.

Xiaobai Li contributed significantly to analysis and manuscript preparation.

Qi Wang performed the data analyses and wrote the manuscript;

Yan Wang, Mengxi Liu, Anji Sun, Yiwei lin and Zhongli Geng helped perform the analysis.

背景:现有α7-烟碱型乙酰胆碱受体激动剂(α7-nAChR受体激动剂)对精神分裂症的认知障碍和阴性症状治疗的临床研究结果不尽一致。

目的:评估α7-烟碱型乙酰胆碱受体激动剂在治疗精神分裂症认知缺损和阴性症状的临床疗效和安全性。

方 法：PubMed、Embase、ClinicalTrials.gov、Cochrane Library和中国知网、万方、VIP数据库进行文献检索，检索时间截止于 2017 年 5 月 26 日。Meta分析双盲随机对照试验中α7-nAChR受体激动剂的作用，评估α7-nAChR受体激动剂对精神分裂症的总体认知功能和阴性症状的临床疗效。通过计算药物和安慰剂之间的平均差(SMDs)，评估α7-nAChR受体激动剂能否作为有效的抗精神病药物。

结果:8个低偏倚研究纳入了meta分析。我们没有发现α7乙酰受体激动剂对精神分裂症患者的认知障碍 (SMD=-0.10(-0.46,0.25), I2= 88%)和阴性症状(SMD=0.13(-0.04,0.30), I2= 64%) 有明显疗效。敏感性分析也印证了此结果。药物总体安全且耐受性良好，在不良事件(RR = 1.02, [0.85, 1.23])和脱落率 (RR = 1.04, [0.61,1.78])与安慰剂对照无显著差异。根据GRADE 评级，该meta分析结果的证据强度为“中”。

结论:α7-nAChR受体激动剂可能不是有效地改善精神分裂症患者总体认知障碍和的阴性症状的药物。

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α7-烟碱型乙酰胆碱受体激动剂对精神分裂症认知缺陷和阴性症状治疗:随机双盲对照研究的meta分析

金烨、王奇、王艳、刘梦曦、孙安吉、耿忠丽、林易玮、李晓白

精神分裂症; 认知障碍; 烟碱型受体激动剂;meta分析

Background: Previous clinical trials of α7-nicotinic acetylcholine receptor agonists (α7-nAChR agonists)showed mixed results in treating the cognitive and negative symptoms of schizophrenia.

Aims: To assess the efficacy and safety of α7-nAChR agonists in treating the cognitive and negative symptoms in schizophrenia.

Methods: A literature search was conducted to identify randomized double-blind placebo-controlled trials for schizophrenia published before May 26, 2017, by searching PubMed, Embase, ClinicalTrials.gov, the Cochrane Library and the Chinese language databases CNKI, Wanfang, and VIP Data. The effects of α7-nAChR agonists were evaluated for overall cognitive function and negative symptoms by calculating standard mean difference (SMDs) between active drugs and placebo added to antipsychotics.

Results: 8 studies with low bias were included. We found no statistically significant effects of α7 nAChR agonists on the overall cognitive function (SMD=-0.10[-0.46, 0.25], I2=88%) and negative symptoms(SMD=0.13 [-0.04, 0.30], I2=64%) in patients with schizophrenia. Sensitivity analysis showed these results to be firm. And this drug is generally safe and well tolerated with no significant difference from placebo based on adverse events (RR=1.02, [0.85, 1.23]) and dropouts (RR=1.04, [0.61, 1.78]) data. Evidence based on outcomes from the meta-analysis was rated as ‘moderate’ as per the GRADE guidelines.

Conclusion: α7-nAChR agonists may not be effective in reversing overall cognitive impairments and negative symptoms in patients with schizophrenia as adjunctive therapies.

[Shanghai Arch Psychiatry. 2017; 29(4): 191-199.

http://dx.doi.org/10.11919/j.issn.1002-0829.217044]

Department of Psychiatry, the First Hospital of China Medical University, Shenyang, China

*correspondence: Dr. Xiaobai Li. Mailing address: No 155, Nanjing RD, Heping District, Shenyang City, Liaoning Province, China. Postcode: 110000. E-Mail:xbli@cmu.edu.cn

Ye Jin obtained a bachelor degree from China Medical University in 2016, and is now working on her Master's at China Medical University, Shenyang, China. She has been working at the department of psychiatry of the First Affiliated Hospital of China Medical University in Shenyang, China since 2016.Her research interests include psychopharmacology and biological psychiatry.