Magrinelli Francesca, Fabrizi Gian Maria, Santoro Lucio, Manganelli Fiore, Zanette Giampietro, Cavallaro Tiziana, Tamburin Stefano
University of Verona, Department of Neurosciences, Biomedicine and Movement Sciences, Piazzale L.A. Scuro n. 10, Verona, VR, Italy, 37134.
University Federico II of Naples, Department of Neurosciences, Reproductive Sciences and Odontostomatology, Via Sergio Pansini n. 5, Naples, Italy, 80131.
Cochrane Database Syst Rev. 2020 Apr 20;4(4):CD012395. doi: 10.1002/14651858.CD012395.pub2.
Disease-modifying pharmacological agents for transthyretin (TTR)-related familial amyloid polyneuropathy (FAP) have become available in the last decade, but evidence on their efficacy and safety is limited. This review focuses on disease-modifying pharmacological treatment for TTR-related and other FAPs, encompassing amyloid kinetic stabilisers, amyloid matrix solvents, and amyloid precursor inhibitors.
To assess and compare the efficacy, acceptability, and tolerability of disease-modifying pharmacological agents for familial amyloid polyneuropathies (FAPs).
On 18 November 2019, we searched the Cochrane Neuromuscular Specialised Register, the Cochrane Central Register of Controlled Trials, MEDLINE, and Embase. We reviewed reference lists of articles and textbooks on peripheral neuropathies. We also contacted experts in the field. We searched clinical trials registries and manufacturers' websites.
We included randomised clinical trials (RCTs) or quasi-RCTs investigating any disease-modifying pharmacological agent in adults with FAPs. Disability due to FAP progression was the primary outcome. Secondary outcomes were severity of peripheral neuropathy, change in modified body mass index (mBMI), quality of life, severity of depression, mortality, and adverse events during the trial.
We followed standard Cochrane methodology.
The review included four RCTs involving 655 people with TTR-FAP. The manufacturers of the drugs under investigation funded three of the studies. The trials investigated different drugs versus placebo and we did not conduct a meta-analysis. One RCT compared tafamidis with placebo in early-stage TTR-FAP (128 randomised participants). The trial did not explore our predetermined disability outcome measures. After 18 months, tafamidis might reduce progression of peripheral neuropathy slightly more than placebo (Neuropathy Impairment Score (NIS) in the lower limbs; mean difference (MD) -3.21 points, 95% confidential interval (CI) -5.63 to -0.79; P = 0.009; low-certainty evidence). However, tafamidis might lead to little or no difference in the change of quality of life between groups (Norfolk Quality of Life-Diabetic Neuropathy (Norfolk QOL-DN) total score; MD -4.50 points, 95% CI -11.27 to 2.27; P = 0.19; very low-certainty evidence). No clear between-group difference was found in the numbers of participants who died (risk ratio (RR) 0.65, 95% CI 0.11 to 3.74; P = 0.63; very low-certainty evidence), who dropped out due to adverse events (RR 1.29, 95% CI 0.30 to 5.54; P = 0.73; very low-certainty evidence), or who experienced at least one severe adverse event during the trial (RR 1.16, 95% CI 0.37 to 3.62; P = 0.79; very low-certainty evidence). One RCT compared diflunisal with placebo (130 randomised participants). At month 24, diflunisal might reduce progression of disability (Kumamoto Score; MD -4.90 points, 95% CI -7.89 to -1.91; P = 0.002; low-certainty evidence) and peripheral neuropathy (NIS plus 7 nerve tests; MD -18.10 points, 95% CI -26.03 to -10.17; P < 0.001; low-certainty evidence) more than placebo. After 24 months, changes from baseline in the quality of life measured by the 36-Item Short-Form Health Survey score showed no clear difference between groups for the physical component (MD 6.10 points, 95% CI 2.56 to 9.64; P = 0.001; very low-certainty evidence) and the mental component (MD 4.40 points, 95% CI -0.19 to 8.99; P = 0.063; very low-certainty evidence). There was no clear between-group difference in the number of people who died (RR 0.46, 95% CI 0.15 to 1.41; P = 0.17; very low-certainty evidence), in the number of dropouts due to adverse events (RR 2.06, 95% CI 0.39 to 10.87; P = 0.39; very low-certainty evidence), and in the number of people who experienced at least one severe adverse event (RR 0.77, 95% CI 0.18 to 3.32; P = 0.73; very low-certainty evidence) during the trial. One RCT compared patisiran with placebo (225 randomised participants). After 18 months, patisiran reduced both progression of disability (Rasch-built Overall Disability Scale; least-squares MD 8.90 points, 95% CI 7.00 to 10.80; P < 0.001; moderate-certainty evidence) and peripheral neuropathy (modified NIS plus 7 nerve tests - Alnylam version; least-squares MD -33.99 points, 95% CI -39.86 to -28.13; P < 0.001; moderate-certainty evidence) more than placebo. At month 18, the change in quality of life between groups favoured patisiran (Norfolk QOL-DN total score; least-squares MD -21.10 points, 95% CI -27.20 to -15.00; P < 0.001; low-certainty evidence). There was little or no between-group difference in the number of participants who died (RR 0.61, 95% CI 0.21 to 1.74; P = 0.35; low-certainty evidence), dropped out due to adverse events (RR 0.33, 95% CI 0.13 to 0.82; P = 0.017; low-certainty evidence), or experienced at least one severe adverse event (RR 0.91, 95% CI 0.64 to 1.28; P = 0.58; low-certainty evidence) during the trial. One RCT compared inotersen with placebo (172 randomised participants). The trial did not explore our predetermined disability outcome measures. From baseline to week 66, inotersen reduced progression of peripheral neuropathy more than placebo (modified NIS plus 7 nerve tests - Ionis version; MD -19.73 points, 95% CI -26.50 to -12.96; P < 0.001; moderate-certainty evidence). At week 65, the change in quality of life between groups favoured inotersen (Norfolk QOL-DN total score; MD -10.85 points, 95% CI -17.25 to -4.45; P < 0.001; low-certainty evidence). Inotersen may slightly increase mortality (RR 5.94, 95% CI 0.33 to 105.60; P = 0.22; low-certainty evidence) and occurrence of severe adverse events (RR 1.48, 95% CI 0.85 to 2.57; P = 0.16; low-certainty evidence) compared to placebo. More dropouts due to adverse events were observed in the inotersen than in the placebo group (RR 8.57, 95% CI 1.16 to 63.07; P = 0.035; low-certainty evidence). There were no studies addressing apolipoprotein AI-FAP, gelsolin-FAP, and beta-2-microglobulin-FAP.
AUTHORS' CONCLUSIONS: Evidence on the pharmacological treatment of FAPs from RCTs is limited to TTR-FAP. No studies directly compare disease-modifying pharmacological treatments for TTR-FAP. Results from placebo-controlled trials indicate that tafamidis, diflunisal, patisiran, and inotersen may be beneficial in TTR-FAP, but further investigations are needed. Since direct comparative studies for TTR-FAP will be hampered by sample size and costs required to demonstrate superiority of one drug over another, long-term non-randomised open-label studies monitoring their efficacy and safety are needed.
在过去十年中,用于治疗转甲状腺素蛋白(TTR)相关家族性淀粉样多神经病(FAP)的病情缓解型药物已可获取,但关于其疗效和安全性的证据有限。本综述聚焦于TTR相关及其他FAP的病情缓解型药物治疗,涵盖淀粉样蛋白动力学稳定剂、淀粉样蛋白基质溶剂和淀粉样蛋白前体抑制剂。
评估和比较用于家族性淀粉样多神经病(FAP)的病情缓解型药物的疗效、可接受性和耐受性。
2019年11月18日,我们检索了Cochrane神经肌肉专业注册库、Cochrane对照试验中央注册库、MEDLINE和Embase。我们查阅了关于周围神经病的文章和教科书的参考文献列表。我们还联系了该领域的专家。我们检索了临床试验注册库和制造商网站。
我们纳入了调查FAP成人患者中任何病情缓解型药物的随机临床试验(RCT)或半随机RCT。FAP进展导致的残疾是主要结局。次要结局包括周围神经病的严重程度、改良体重指数(mBMI)的变化、生活质量、抑郁严重程度、死亡率以及试验期间的不良事件。
我们遵循Cochrane标准方法。
该综述纳入了四项RCT,涉及655例TTR-FAP患者。三项研究由所研究药物的制造商资助。这些试验比较了不同药物与安慰剂,但我们未进行荟萃分析。一项RCT在早期TTR-FAP患者中比较了氯苯唑酸与安慰剂(128例随机参与者)。该试验未探讨我们预先确定的残疾结局指标。18个月后,氯苯唑酸可能比安慰剂更能略微减缓周围神经病的进展(下肢神经病变损害评分(NIS);平均差(MD)-3.21分,95%置信区间(CI)-5.63至-0.79;P = 0.009;低确定性证据)。然而,氯苯唑酸可能导致两组间生活质量变化几乎没有差异或无差异(诺福克糖尿病神经病变生活质量量表(Norfolk QOL-DN)总分;MD -4.50分,95% CI -11.27至2.27;P = 0.19;极低确定性证据)。在死亡参与者数量(风险比(RR)0.65,95% CI 0.11至3.74;P = 0.63;极低确定性证据)、因不良事件退出的参与者数量(RR 1.29,95% CI 0.30至5.54;P = 0.73;极低确定性证据)或试验期间经历至少一次严重不良事件的参与者数量(RR 1.16,9
