key: cord-0893161-qw8qhmv1 authors: Bai, Hua; Ji, Yongjia; Wang, Jia; Zhang, Xuehong title: Efficacy of human coronavirus immune convalescent plasma for the treatment of corona virus disease -19 disease in hospitalized children: A protocol for systematic review and meta analysis date: 2020-11-06 journal: Medicine (Baltimore) DOI: 10.1097/md.0000000000022017 sha: 0c4a75c752e352e30868d8468349703e3dc30dbd doc_id: 893161 cord_uid: qw8qhmv1 BACKGROUND: Severe acute respiratory syndrome coronavirus 2 viral infection resulting in corona virus disease 2019 (COVID-19) disease has recently been designated by the World Health Organization as a global pandemic. Some doctors are using convalescent plasma (CP) therapies to treat COVID-19 patients. However, whether CP therapy is effective for children with COVID-19 remains controversial. Therefore, this study further explores the effectiveness and safety of human coronavirus immune CP in the treatment of COVID-19 in children. METHODS: Comprehensively search the electronic databases such as the Cochrane Library, PubMed, EMBASE, Web of Science, China National Knowledge Infrastructure, and WanFang, and collect relevant documents. We will also look for other sources. All document sources will not be restricted by language and publication status. Two researchers will independently conduct research selection, data extraction and research quality assessment. RevMan 5.3 was used for statistical analysis. RESULTS: This study will provide high-quality comprehensive evidence for the effectiveness and safety of human coronavirus immuno CP in the treatment of COVID-19 in children CONCLUSIONS: The results of this study will provide the basis for the effectiveness and safety of human coronavirus immuno CP treatment of COVID-19 in children. PROSPERO REGISTRATION NUMBER: CRD42020199410 Coronavirus disease 2019 (COVID-19) refers to pneumonia caused by severe acute respiratory syndrome (SARS) coronavirus 2 infection. [1] SARS coronavirus 2 is highly infectious and poses a great challenge to national public health. [2] [3] [4] [5] [6] The main manifestations of COVID-19 patients are fever, fatigue, and dry cough. Upper respiratory symptoms such as nasal congestion and runny nose are rare, and hypoxia may occur. About half of the patients developed dyspnea after 1 week. In severe cases, they rapidly progressed to acute respiratory distress syndrome, septic shock, difficult to correct metabolic acidosis, bleeding and/or coagulopathy, and a few patients were critically ill and even died. [7] Currently, there is no specific treatment for COVID-19, and isolation treatment and symptomatic supportive treatment are the main ones. Convalescent plasma (CP) therapy is a form of passive immunity in which antibody-rich blood is collected from recovered patients, processed and then transfused into other patients. [8] The neutralizing antibody is a key influencing factor: it binds to the virus, blocks the virus from entering the cell, regulates the immune system, mediates the phagocytosis of immune cells, and eliminates the virus. [9] CP is used to treat Ebola, SARS, middle east respiratory syndrome coronavirus, pandemic influenza and other unexpected major infectious The private information from individuals will not publish. This systematic review also will not involve endangering participant rights. Ethical approval is not required. The results may be published in a peer-reviewed journal or disseminated in relevant conferences. diseases. [8] In addition, related research has also made some progress. [10] [11] [12] The Food and Drug Administration has approved the use of CP to treat patients with severe new coronary pneumonia. [13] However, there is still a lack of evidence regarding the treatment of COVID-19 in children with human coronavirus immune CP therapy. Therefore, this article will evaluate whether the human coronavirus immune CP therapy is effective and safe to treat children with COVID-19. This meta-analysis will be the first study to evaluate whether human coronavirus immune CP therapy is effective and safe for children with COVID-19. This study was registered through PROSPERO (PROSPERO Registration number: CRD42020199410). We organize this study based on the Preferred Reporting Items for Systematic Reviews and Meta-Analyses Protocols guidelines. [14] Ethical approval is not required as there is no patient recruitment and personal informationcollection, and the data included in our study are from published literature. (1) Onset of symptoms began >12 days before screening; (2) History of adverse reactions to blood products or other contraindication to transfusion; (3) Refusal of plasma for religious or other reasons; (4) Acute heart failure with fluid overload; (1) Clinical recovery (time frame: at day 30), defined in the last 24 hours as normal respiratory and heart rate (or return to baseline, absence of fever, absence of low blood pressure, oxygen saturation greater than 94% or room air (or return to baseline), no need for intravenous fluids (or return to baseline). (2) SARS-CoV-2 DNA. (3) SARS-CoV-2 antibody levels. (1) 28-day mortality rate. (2) C-reactive protein. (1) Incomplete data or misrepresentation of data reports. (2) Repeated publication of documents. (3) Case reports, reviews, and so on. (4) Inability to obtain original documents. A comprehensive search of electronic databases such as The Cochrane Library, PubMed, EMBASE, Web of Science, China National Knowledge Infrastructure, and WanFang, to collect RCTs of human coronavirus immuno CP treatment of children with COVID-19. We will also look for other sources. All document sources will not be restricted by language and publication status. The search strategy performed for the PubMed is shown in Table 1 . Searches of other databases are also performed according to this search strategy. 2.6. Data collection and analysis 2.6.1. Data extraction and management. Two reviewers independently screened the literature, extracted data, and cross-checked. In case of disagreement, consult a third party to assist in the judgment, and try to contact the author to supplement the lack of data. When selecting documents, first read the title and abstract, and after excluding obviously irrelevant documents, read the full text further to determine whether it will be included. The data extraction content mainly includes: Basic information of the included literature, including the first author, country, year of publication, etc; Specific details of intervention measures, including the usage of rehabilitation plasma, dosage treatment, and so on; Baseline characteristics of the included subjects; Risk of bias The key elements of evaluation; The outcome indicators and outcome measurement data concerned, such as Clinical recovery, SARS-CoV-2 DNA, SARS-CoV-2 antibody levels, so on. The literature screening process is shown in Figure 1 . 2.6.3. Measures of treatment effect. Count data uses relative risk as the effect indicator, and measurement data uses the standard mean difference as the effect indicator. Each effect size is given its point estimate and 95% confidence intervals. 2.6.4. Dealing with missing data. If the relevant data in the literature is incomplete, the first author or corresponding author will be contacted by email or phone to obtain the missing data. If the missing data is still not obtained through the above methods, we can synthesize the available data in the preliminary analysis. In addition, sensitivity analysis will be used to assess the potential impact of missing data on the overall results of the study. 2.6.5. Assessment of heterogeneity. The 2 researchers used the x2 test to analyze the heterogeneity between the results of the included studies (test level is a = 0.1) and combined with I 2 to quantitatively judge the heterogeneity. I 2 < 50%, P > 0.1 means reasonable heterogeneity, and a fixed-effects model will be conducted. I 2 ≥ 50%, P < .1 exerts significant heterogeneity, and a random effects model will be conducted. 2.6.6. Assessment of reporting biases. If there are no less than 10 articles included, we will use a funnel chart to test publication bias. [15] 2.6.7. Data synthesis. RevMan 5.3 software for statistical analysis. If the statistical heterogeneity between the results of each study does not exist or is small (I 2 < 50%, P > .1), the fixed-effects model is used for Meta-analysis; if there is large statistical heterogeneity between the results of the studies (I 2 ≥ 50%, P < .1), then further analyze the source of heterogeneity. After excluding the influence of obvious clinical heterogeneity, the random effects model is used for Meta-analysis. The level of Meta-analysis is set to a = 0.05. Obvious clinical heterogeneity is treated by subgroup analysis or sensitivity analysis, or only descriptive analysis. 2.6.8. Subgroup analysis. We will conduct subgroup analysis based on different reasons. Heterogeneity is mainly manifested in several aspects such as race, age, condition, dosage of medication, and duration of treatment. 2.6.9. Sensitivity analysis. The robustness of the research results is tested by excluding low-quality studies and conducting sensitivity analysis. CP is a plasma preparation obtained by a patient who stimulates humoral immunity to produce specific antibodies against the pathogen during a pre-infection and collects the patient's plasma after the patient recovers. [16] In patients with severe infection, infusion of CP neutralizes the pathogens in the body, removes pathogens in the blood circulation, and combines with other antiviral drugs and supportive treatments to achieve the effect of Table 1 PubMed search strategy. relieving the condition. Studies have also shown that this passive immunity may also be suitable for tumor treatment. [17] When infectious diseases are prevalent, CP may be an effective treatment option in the absence of specific drugs and vaccines. This treatment technology has been used in previous large-scale viral epidemics and has saved many acute infectious diseases, such as middle east respiratory syndrome coronavirus, avian influenza (H1N1, H5N1 and H7N9, etc.), SARS, ebola virus, and so on. [18] [19] [20] [21] [22] With the spread of COVID-19, for severe and critical cases, in addition to symptomatic treatment, respiratory support, and circulatory support, CP treatment is also an important treatment measure to save patients. [23] [24] [25] [26] This plan will evaluate whether the human coronavirus immune CP is effective and safe for the treatment of COVID-19 in children and provide more accurate and objective evidence for the clinic. However, our meta-analysis may have some limitations. Both Chinese and English research forms may increase the bias of research. Secondly, the diversity of race, age, drug dosage, and treatment course resulted in higher clinical and statistical heterogeneity. In summary, this study will help determine the effectiveness and safety of CP therapy for children with COVID-19. We hope that this study can provide higher-quality evidence for the effectiveness and safety of CP therapy in the treatment of COVID-19 in children. Coronavirus disease 2019 (COVID-19): a clinical update A rapid advice guideline for the diagnosis and treatment of 2019 novel coronavirus (2019-nCoV) infected pneumonia (standard version) SARS-CoV-2, the virus that causes COVID-19: cytometry and the new challenge for global health Chronology of COVID-19 cases on the Diamond Princess cruise ship and ethical considerations: a report from Japan COVID-19: the new challenge for rheumatologists. 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SARS: systematic review of treatment effects Feasibility, safety, clinical, and laboratory effects of convalescent plasma therapy for patients with Middle East respiratory syndrome coronavirus infection: a study protocol Covid-19: FDA approves use of convalescent plasma to treat critically ill patients Preferred reporting items for systematic review and meta-analysis protocols (PRISMA-P) 2015 statement The performance of tests of publication bias and other sample size effects in systematic reviews of diagnostic test accuracy was assessed Ebola virus convalescent blood products: where we are now and where we may need to go An augmented passive immune therapy to treat fulminant bacterial infections Group WM-CRState of knowledge and data gaps of middle east respiratory syndrome coronavirus (MERS-CoV) in humans Treatment of severe acute respiratory syndrome with convalescent plasma Treatment with convalescent plasma for influenza A (H5N1) infection Use of convalescent plasma therapy in SARS patients in Hong Kong Successful treatment of avian-origin influenza A (H7N9) infection using convalescent plasma Emerging prevention and treatment strategies to control COVID-19 2020 Challenges of convalescent plasma therapy on COVID-19 Deployment of convalescent plasma for the prevention and treatment of COVID-19 Treatment for emerging viruses: convalescent plasma and COVID-19 This work was supported by the Key Research projects of Health and Family Planning system in Ningxia Hui Autonomous region (No. 2016A020220015) Provenance and peer review was not commissioned; externally peer reviewed.The authors have no conflicts of interest to disclose.The datasets generated during and/or analyzed during the current study are available from the corresponding author on reasonable request. a General Hospital of Ningxia Medical University, b Ningxia Maternal and Child Health Care Hospital (Ningxia Children's Hospital), Ningxia, c Huazhong university of science and technology union shenzhen hospital, Shenzhen, China.