Mulvaney Caroline A, Duarte Gonçalo S, Handley Joel, Evans David Jw, Menon Suresh, Wyse Richard, Emsley Hedley Ca
Lancaster Medical School, Lancaster University, Lancaster, UK.
Laboratory of Clinical Pharmacology and Therapeutics, Faculdade de Medicina de Lisboa, Lisboa, Portugal.
Cochrane Database Syst Rev. 2020 Jul 23;7(7):CD012990. doi: 10.1002/14651858.CD012990.pub2.
Parkinson's disease (PD) is a progressive disorder characterised by both motor and non-motor problems. Glucagon-like peptide-1 (GLP-1) receptor agonists, licensed for treatment of type 2 diabetes, work by stimulating GLP-1 receptors in the pancreas, which triggers the release of insulin. GLP-1 receptors have been found in the brain. Insulin signalling in the brain plays a key role in neuronal metabolism and repair and in synaptic efficacy, but insulin signalling is desensitised in the brain of people with PD. Researchers are exploring the neuroprotective effects of GLP-1 receptor agonists in neurodegenerative disorders such as PD.
To evaluate the effectiveness and safety of GLP-1 receptor agonists for Parkinson's disease.
We searched the Cochrane Movement Disorders Group trials register; the Cochrane Central Register of Controlled Trials (CENTRAL), in the Cochrane Library; and Ovid MEDLINE and Embase. We also searched clinical trials registries, and we handsearched conference abstracts. The most recent search was run on 25 June 2020.
We included randomised controlled trials (RCTs) of adults with PD that compared GLP-1 receptor agonists with conventional PD treatment, placebo, or no treatment.
Two review authors independently assessed studies for inclusion, extracted data, and assessed risk of bias. We rated the quality of evidence using GRADE. We resolved discrepancies between the two data extractors by consultation with a third review author.
Through our searches, we retrieved 99 unique records, of which two met our inclusion criteria. One double-blind study of exenatide versus placebo randomised 62 participants, who self-administered exenatide or placebo for 48 weeks and were followed up at 60 weeks after a 12-week washout. One single-blind study of exenatide versus no additional treatment randomised 45 participants; participants in the intervention group self-administered exenatide for 12 months, and all participants were followed up at 14 months and 24 months following absence of exenatide for 2 months and 12 months, respectively. These trials had low risk of bias, except risk of performance bias was high for Aviles-Olmos 2013. Exenatide versus placebo Primary outcomes We found low-certainty evidence suggesting that exenatide improves motor impairment as assessed by the Movement Disorder Society-Unified Parkinson's Disease Rating Scale (MDS-UPDRS) Part III in the off-medication state (mean difference (MD) -3.10, 95% confidence interval (CI) -6.11 to -0.09). The difference in scores was slightly greater when scores were adjusted for baseline severity of the condition (as reported by study authors) (MD -3.5, 95% CI -6.7 to -0.3), exceeding the minimum clinically important difference (MCID). We found low-certainty evidence suggesting that exenatide has little or no effect on health-related quality of life (HRQoL) as assessed by the Parkinson's Disease Questionnaire (PDQ)-39 Summary Index (SI) (MD -1.80, 95% CI -6.95 to 3.35), the EuroQol scale measuring health status in five dimensions (EQ5D) (MD 0.07, 95% CI -0.03 to 0.16), or the EQ5D visual analogue scale (VAS) (MD 5.00, 95% CI -3.42 to 13.42). Eight serious adverse events (SAEs) were recorded, but all were considered unrelated to the intervention. Low-certainty evidence suggests that exenatide has little or no effect on weight loss (risk ratio (RR) 1.25, 95% CI 0.89 to 1.76). Exenatide versus no treatment Primary outcomes at 14 months We found very low-certainty evidence suggesting that exenatide improves motor impairment as assessed by MDS-UPDRS Part III off medication (MD -4.50, 95% CI -8.64 to -0.36), exceeding the MCID. We are uncertain whether exenatide improves HRQoL as assessed by the PDQ-39 SI (MD 3.50, 95% CI -2.75 to 9.75; very low-quality evidence). We found very low-certainty evidence suggesting that exenatide has little or no effect on the number of SAEs (RR 1.60, 95% 0.40 to 6.32). We found very low-certainty evidence suggesting that exenatide may lead to weight loss (MD -2.40 kg, 95% CI -4.56 to -0.24). Primary outcomes at 24 months We found evidence as reported by study authors to suggest that exenatide improves motor impairment as measured by MDS-UPDRS Part III off medication (MD 5.6 points, 95% CI 2.2 to 9.0). Exenatide may not improve HRQoL as assessed by the PDQ-39 SI (P = 0.682) and may not result in weight loss (MD 0.1 kg, 95% CI 3.0 to 2.8).
AUTHORS' CONCLUSIONS: Low- or very low-certainty evidence suggests that exenatide may improve motor impairment for people with PD. The difference in motor impairment observed between groups may persist for some time following cessation of exenatide. This raises the possibility that exenatide may have a disease-modifying effect. SAEs were unlikely to be related to treatment. The effectiveness of exenatide for improving HRQoL, non-motor outcomes, ADLs, and psychological outcomes is unclear. Ongoing studies are assessing other GLP-1 receptor agonists.
帕金森病(PD)是一种以运动和非运动问题为特征的进行性疾病。胰高血糖素样肽-1(GLP-1)受体激动剂已获许可用于治疗2型糖尿病,其作用机制是刺激胰腺中的GLP-1受体,从而触发胰岛素释放。已在大脑中发现GLP-1受体。大脑中的胰岛素信号传导在神经元代谢、修复以及突触效能中起关键作用,但PD患者大脑中的胰岛素信号传导会出现脱敏现象。研究人员正在探索GLP-1受体激动剂在诸如PD等神经退行性疾病中的神经保护作用。
评估GLP-1受体激动剂治疗帕金森病的有效性和安全性。
我们检索了Cochrane运动障碍组试验注册库;Cochrane图书馆中的Cochrane对照试验中央注册库(CENTRAL);以及Ovid MEDLINE和Embase。我们还检索了临床试验注册库,并手工检索了会议摘要。最近一次检索于2020年6月25日进行。
我们纳入了将GLP-1受体激动剂与传统PD治疗、安慰剂或不治疗进行比较的成年PD患者随机对照试验(RCT)。
两位综述作者独立评估纳入研究、提取数据并评估偏倚风险。我们使用GRADE对证据质量进行评级。我们通过与第三位综述作者协商解决了两位数据提取者之间的差异。
通过检索,我们获得了99条独特记录,其中两条符合我们的纳入标准。一项关于艾塞那肽与安慰剂的双盲研究将62名参与者随机分组,参与者自行服用艾塞那肽或安慰剂48周,并在12周洗脱期后60周进行随访。一项关于艾塞那肽与不进行额外治疗的单盲研究将45名参与者随机分组;干预组参与者自行服用艾塞那肽12个月,所有参与者分别在停用艾塞那肽2个月和12个月后的14个月和24个月进行随访。这些试验的偏倚风险较低,但Aviles-Olmos 2013的执行偏倚风险较高。艾塞那肽与安慰剂 主要结局 我们发现低确定性证据表明,在非服药状态下,通过运动障碍协会统一帕金森病评定量表(MDS-UPDRS)第三部分评估,艾塞那肽可改善运动障碍(平均差(MD)-3.10,95%置信区间(CI)-6.11至-0.09)。当根据病情的基线严重程度进行调整(如研究作者所报告)时,得分差异略大(MD -3.5,95% CI -6.7至-0.3),超过了最小临床重要差异(MCID)。我们发现低确定性证据表明,通过帕金森病问卷(PDQ)-39总结指数(SI)评估,艾塞那肽对健康相关生活质量(HRQoL)几乎没有影响(MD -1.80,95% CI -6.95至3.35),通过测量五个维度健康状况的欧洲五维健康量表(EQ5D)评估(MD 0.07,95% CI -0.03至0.16),或通过EQ5D视觉模拟量表(VAS)评估(MD 5.00,95% CI -3.42至l3.42)。记录了8起严重不良事件(SAEs),但均认为与干预无关。低确定性证据表明,艾塞那肽对体重减轻几乎没有影响(风险比(RR)1.25,95% CI 0.89至1.76)。艾塞那肽与不治疗 14个月时的主要结局 我们发现极低确定性证据表明,在非服药状态下,通过MDS-UPDRS第三部分评估,艾塞那肽可改善运动障碍(MD -4.50,95% CI -8.64至-0.36),超过了MCID。我们不确定通过PDQ-39 SI评估艾塞那肽是否能改善HRQoL(MD 3.50,95% CI -2.75至9.75;极低质量证据)。我们发现极低确定性证据表明,艾塞那肽对SAEs的数量几乎没有影响(RR 1.60,95% 0.40至6.32)。我们发现极低确定性证据表明,艾塞那肽可能导致体重减轻(MD -2.40 kg,95% CI -4.56至-0.24)。24个月时的主要结局 我们发现研究作者报告的证据表明,在非服药状态下,通过MDS-UPDRS第三部分测量,艾塞那肽可改善运动障碍(MD 5.6分,95% CI 2.2至9.0)。通过PDQ-39 SI评估,艾塞那肽可能无法改善HRQoL(P = 0.682),也可能不会导致体重减轻(MD 0.1 kg,95% CI 3.0至2.8)。
低或极低确定性证据表明,艾塞那肽可能改善PD患者的运动障碍。停药后,组间观察到的运动障碍差异可能会持续一段时间。这增加了艾塞那肽可能具有疾病修饰作用的可能性。SAEs不太可能与治疗相关。艾塞那肽改善HRQoL、非运动结局、日常生活活动能力和心理结局的有效性尚不清楚。正在进行的研究正在评估其他GLP-受体激动剂。
