- Study stopped early by data safety monitoring board because of difficulty recruiting patients after COVID-19 outbreak in Wuhan, China brought under control, so the true effectiveness of antiviral drug remdesivir remains unclear.
- Treatment with remdesivir did not speed recovery or reduce deaths from COVID-19 compared with placebo in hospitalised patients in the trial.
- While not statistically significant, pre-specified secondary outcomes found that time to clinical improvement and duration of invasive mechanical ventilation were shorter in people treated with remdesiver within 10 days of showing symptoms, compared to standard care.
- The authors say that future studies of remdesivir are needed to better understand its potential effectiveness.
Treatment with the antiviral drug remdesivir does not speed recovery from COVID-19 compared with placebo in hospitalised patients who are critically ill, according to the first randomised trial of its kind involving 237 adults (aged 18 and older) from ten hospitals in Wuhan, China, published in The Lancet.
Although their study is the first randomised controlled trial (considered the gold standard for evaluating the effectiveness of interventions) of remdesivir, the authors caution that interpretation of their findings is limited because the study was stopped early after they were unable to recruit enough patients due to the steep decline in cases in China [1]. They conclude that more evidence from ongoing clinical trials is needed to better understand whether remdesivir can provide meaningful clinical benefit.
In the absence of any known treatment for COVID-19, remdesivir is one of a handful of experimental drugs undergoing clinical trials worldwide. It has only been available to patients with COVID-19 on compassionate grounds (the use of unapproved drugs when no other treatment is available). In the trial, all patients received standard care including lopinavir-ritonavir, interferons, and corticosteroids.
"Unfortunately, our trial found that while safe and adequately tolerated, remdesivir did not provide significant benefits over placebo", says Professor Bin Cao from China-Japan Friendship Hospital and Capital Medical University in China, who led the research. "This is not the outcome we hoped for, but we are mindful that we were only able to enrol 237 of the target 453 patients because the COVID-19 outbreak was brought under control in Wuhan. What's more, restrictions on bed availability resulted in most patients being enrolled later in the disease course, so we were unable to adequately assess whether earlier treatment with remdesivir might have provided clinical benefit." [2]
He continues: "Future studies need to determine whether earlier treatment with remdesivir, higher doses, or combination with other antivirals or SARS-CoV-2 neutralising antibodies, might be more effective in those with severe illness." [2]
Remdesivir was originally developed to treat Ebola, and is designed to interfere with the way a virus reproduces, thereby stopping it from multiplying inside the body. It has been shown to successfully block SARS-CoV-2 from replicating in vitro, and had activity against other coronavirus infections like severe acute respiratory syndrome (SARS), Middle East respiratory syndrome (MERS), and COVID-19 in animal studies. Case studies have also reported benefit in some severely ill patients with COVID-19, but until now, there have been no clinical trials of remdesivir, so its efficacy against COVID-19 in patients is unknown.
In this study, 237 adults hospitalised with severe laboratory-confirmed SARS-CoV-2 infection were enrolled between February 6 and March 12, 2020. To be eligible, patients had to enter the study within 12 days of symptom onset, have pneumonia confirmed by chest imaging, and oxygen saturation of 94% or lower. Participants were randomly assigned to either daily infusions of remdesivir (158 patients; 200mg on day 1 followed by 100mg on days 2-10) or a placebo infusions (79 patients) for 10 days. One patient in the placebo group withdrew before receiving treatment.
Trained investigators measured time to clinical improvement over 28 days using a six-point scale of clinical status ranging from hospital discharge (score=1) to death (score=6). Clinical improvement was defined as at least a two point improvement compared to a patient's admission status.
No statistically significant difference in time to clinical improvement was noted between the groups (average time to clinical improvement 21 days for remdesivir group vs 23 days placebo group). In a secondary outcome (a planned outcome measure in a trial that is not as important as the primary outcome measure, but is still of interest in evaluating the effect of an intervention [3]), although not statistically significant, in patients treated within 10 days of illness onset, those receiving remdesivir appeared to recover faster than those given placebo (average time to clinical improvement 18 days vs 23 days).
Death within 28 days of randomisation was similar between the groups, with 14% (22/158) patients dying in the remdesivir group compared with 13% (10/78) in the placebo group. However, in secondary outcomes, patients treated with remdesivir within 10 days of illness onset had a lower, but not statistically significant, difference in mortality, with 11% (8/71) patients dying compared with 15% (7/47) receiving placebo.
Similarly, in secondary outcomes, the duration of invasive mechanical ventilation, although not significantly different between the groups, was shorter in remdesivir recipients than placebo recipients (average 7 days vs 15.5 days). No significant differences were noted between the groups in duration of oxygen support, length of hospital stay, or time to discharge or death (table 3).
Furthermore, treatment with remdesivir did not result in significant reductions in viral load (how much SARS-CoV-2 is present in an infected person's body) or detection of the virus in the upper or lower respiratory tract compared with placebo (figure 3).
There was no difference in adverse events between the groups (65%; 102/155 remdesivir patients included in the safety analysis vs 64%; 50/78 placebo), and the overall proportion of serious adverse events was lower in patients given remdesivir than placebo (18%; 28/155 vs 26%; 20/78). However, more patients in the remdesivir group discontinued treatment because of adverse events including gastrointestinal symptoms (eg, nausea, vomiting) and cardiopulmonary failure (18 remdesivir group; 12% vs 4 placebo; 5%).
"Participants in our trial were less ill, and treated earlier in their disease course, compared with a recent observational study of patients with COVID-19, who received remdesivir on compassionate grounds [4]. Yet, remdesivir did not provide greater benefits in our study population as expected", says co-author Professor Ronghui Du from Wuhan Lung Hospital, China. "Ongoing clinical trials of remdesivir, will provide important additional information about whether and under what circumstances it may provide benefit." [2]
The authors note several limitations of the study, including that stopping early gives insufficient power to detect differences in clinical outcomes, and it did not account for the possible emergence of reduced susceptibility to remdesivir (which would contribute to a reduction of remdesivir effectiveness), because of a lack of data at the time. Finally, they point out that the frequent use of corticosteroids in patients in this study might have aided viral production, as observed in SARS and MERS.
Writing in a linked Comment, Professor John Norrie (who was not involved in the study) from the University of Edinburgh, UK, discusses the challenges, and importance, of conducting randomised trials in epidemics, and writes: "Promising signals from observational data must be rigorously confirmed or refuted in high-quality randomised trials--particularly given that for COVID-19 no proven safe and effective treatments yet exist...That is additionally challenging in a pandemic, and the temptation to lower the threshold of convincing evidence must be resisted, because adopting ineffective and potentially unsafe interventions risks only harm without worthwhile benefit, while making it even harder to undertake trials to find truly effective and safe interventions."
He continues: "The study was well designed--a double-blind, placebo-controlled, multicentre randomised trial--and well conducted, with high protocol adherence and no loss-to-follow up...An absence of statistical significance in an underpowered trial means that the findings are inconclusive. The particular challenges of delivering pandemic trials underline the importance of data sharing, allowing rapid curation of relevant datasets for individual patient data meta-analyses. With each individual study at heightened risk of being incomplete, pooling data across possibly several underpowered but high-quality studies looks like it will be our best way to obtain robust insights into what works, safely, and on whom. We eagerly await the ongoing trials."
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Peer-reviewed / Randomised controlled trial / People
NOTES TO EDITORS
The study was funded by Chinese Academy of Medical Sciences Emergency Project of COVID-19, National Key Research and Development Program of China, and the Beijing Science and Technology Project. It was conducted by researchers from the National Clinical Research Center for Respiratory Diseases, China; Institute of Clinical Medical Sciences, China; China-Japan Friendship Hospital, Beijing, China; Capital Medical University, Beijing, China; Chinese Academy of Medical Sciences and Peking Union Medical College, China; Wuhan Lung Hospital, China; Tongji Hospital, China; Union Hospital, China; Tongji Medical College of Huazhong University of Science and Technology, China; Wuhan Third Hospital, China; Renmin Hospital of Wuhan University, China; Zhongnan Hospital of Wuhan University, China; The Central Hospital of Wuhan, China; Tsinghua University School of Medicine, China; Beijing University of Chinese Medicine, China; Tigermed Consulting, China; Teddy Clinical Research Laboratory, China; Hangzhou DI'AN Medical Laboratory, China; Lancaster University, UK; University of Cambridge, UK; University of Virginia School of Medicine, USA; University of Oxford, UK; Chinese Academy of Medical Science, China; Tsinghua University- Peking University Joint Center for Life Sciences, China; and Peking Union Medical College, Beijing, China.
The labels have been added to this press release as part of a project run by the Academy of Medical Sciences seeking to improve the communication of evidence. For more information, please see: http://www.sciencemediacentre.org/wp-content/uploads/2018/01/AMS-press-release-labelling-system-GUIDANCE.pdf if you have any questions or feedback, please contact The Lancet press office pressoffice@lancet.com
[1] No patients were enrolled after March 12, 2020, because of the control of the outbreak in Wuhan, and on March 29, the data safety and monitoring board recommended that the study be terminated and data analysed. When all the other assumptions stayed the same, with the enrolment of 237 participants instead of the target 453, the statistical power was reduced from 80% to 58%.
[2] Quotes direct from authors and cannot be found in the text of the Article.
[3] https://clinicaltrials.gov/ct2/help/glossary/secondary-outcome-measure
[4] https://www.nejm.org/doi/pdf/10.1056/NEJMoa2007016?articleTools=true
For interviews with article authors please contact:
Professor Bin Cao, China-Japan Friendship Hospital and Capital Medical University, Beijing
E) caobin_ben@163.com T) +86 (0)10 842 062 64
Dr Chen Wang, National Clinical Research Canter for Respiratory Diseases, China please email
wangchen@pumc.edu.cn
For interviews with comment author Professor John Norre, University of Edinburgh, UK please contact E) j.norrie@ed.ac.uk T) +44(0) 7801 404608X
Journal
The Lancet