Department of Pediatrics, Division of Pediatric Gastroenterology, Hepatology and Nutrition, SUNY Upstate Medical University, Syracuse, New York, USA.
Department of Epidemiology, Johns Hopkins University Bloomberg School of Public Health, Baltimore, Maryland, USA.
Cochrane Database Syst Rev. 2022 Mar 16;3(3):CD008524. doi: 10.1002/14651858.CD008524.pub4.
Vitamin A deficiency (VAD) is a major public health problem in low- and middle-income countries, affecting 190 million children under five years of age and leading to many adverse health consequences, including death. Based on prior evidence and a previous version of this review, the World Health Organization has continued to recommend vitamin A supplementation (VAS) for children aged 6 to 59 months. The last version of this review was published in 2017, and this is an updated version of that review.
To assess the effects of vitamin A supplementation (VAS) for preventing morbidity and mortality in children aged six months to five years.
We searched CENTRAL, MEDLINE, Embase, six other databases, and two trials registers up to March 2021. We also checked reference lists and contacted relevant organisations and researchers to identify additional studies.
Randomised controlled trials (RCTs) and cluster-RCTs evaluating the effect of synthetic VAS in children aged six months to five years living in the community. We excluded studies involving children in hospital and children with disease or infection. We also excluded studies evaluating the effects of food fortification, consumption of vitamin A rich foods, or beta-carotene supplementation.
For this update, two review authors independently assessed studies for inclusion resolving discrepancies by discussion. We performed meta-analyses for outcomes, including all-cause and cause-specific mortality, disease, vision, and side effects. We used the GRADE approach to assess the quality of the evidence.
The updated search identified no new RCTs. We identified 47 studies, involving approximately 1,223,856 children. Studies were set in 19 countries: 30 (63%) in Asia, 16 of these in India; 8 (17%) in Africa; 7 (15%) in Latin America, and 2 (4%) in Australia. About one-third of the studies were in urban/periurban settings, and half were in rural settings; the remaining studies did not clearly report settings. Most studies included equal numbers of girls and boys and lasted about one year. The mean age of the children was about 33 months. The included studies were at variable overall risk of bias; however, evidence for the primary outcome was at low risk of bias. A meta-analysis for all-cause mortality included 19 trials (1,202,382 children). At longest follow-up, there was a 12% observed reduction in the risk of all-cause mortality for VAS compared with control using a fixed-effect model (risk ratio (RR) 0.88, 95% confidence interval (CI) 0.83 to 0.93; high-certainty evidence). Nine trials reported mortality due to diarrhoea and showed a 12% overall reduction for VAS (RR 0.88, 95% CI 0.79 to 0.98; 1,098,538 children; high-certainty evidence). There was no evidence of a difference for VAS on mortality due to measles (RR 0.88, 95% CI 0.69 to 1.11; 6 studies, 1,088,261 children; low-certainty evidence), respiratory disease (RR 0.98, 95% CI 0.86 to 1.12; 9 studies, 1,098,538 children; low-certainty evidence), and meningitis. VAS reduced the incidence of diarrhoea (RR 0.85, 95% CI 0.82 to 0.87; 15 studies, 77,946 children; low-certainty evidence), measles (RR 0.50, 95% CI 0.37 to 0.67; 6 studies, 19,566 children; moderate-certainty evidence), Bitot's spots (RR 0.42, 95% CI 0.33 to 0.53; 5 studies, 1,063,278 children; moderate-certainty evidence), night blindness (RR 0.32, 95% CI 0.21 to 0.50; 2 studies, 22,972 children; moderate-certainty evidence), and VAD (RR 0.71, 95% CI 0.65 to 0.78; 4 studies, 2262 children, moderate-certainty evidence). However, there was no evidence of a difference on incidence of respiratory disease (RR 0.99, 95% CI 0.92 to 1.06; 11 studies, 27,540 children; low-certainty evidence) or hospitalisations due to diarrhoea or pneumonia. There was an increased risk of vomiting within the first 48 hours of VAS (RR 1.97, 95% CI 1.44 to 2.69; 4 studies, 10,541 children; moderate-certainty evidence).
AUTHORS' CONCLUSIONS: This update identified no new eligible studies and the conclusions remain the same. VAS is associated with a clinically meaningful reduction in morbidity and mortality in children. Further placebo-controlled trials of VAS in children between six months and five years of age would not change the conclusions of this review, although studies that compare different doses and delivery mechanisms are needed. In populations with documented VAD, it would be unethical to conduct placebo-controlled trials.
维生素 A 缺乏症(VAD)是中低收入国家的一个主要公共卫生问题,影响了 1.9 亿五岁以下儿童,并导致许多不良健康后果,包括死亡。基于先前的证据和本综述的前一个版本,世界卫生组织继续建议为 6 至 59 个月的儿童补充维生素 A(VAS)。该综述的上一个版本于 2017 年发布,这是对该综述的更新版本。
评估维生素 A 补充剂(VAS)预防 6 个月至 5 岁儿童发病和死亡的效果。
我们检索了 CENTRAL、MEDLINE、Embase、其他六个数据库以及两个试验登记处,截至 2021 年 3 月。我们还检查了参考文献列表,并联系了相关组织和研究人员以确定其他研究。
随机对照试验(RCT)和群组随机对照试验,评估社区中 6 个月至 5 岁儿童接受合成 VAS 的效果。我们排除了在医院中进行的儿童和患有疾病或感染的儿童的研究。我们还排除了评估食品强化、富含维生素 A 的食物消费或β-胡萝卜素补充剂效果的研究。
本次更新中,两名综述作者独立评估了研究的纳入情况,通过讨论解决了分歧。我们对所有原因和病因特异性死亡率、疾病、视力和副作用等结局进行了荟萃分析。我们使用 GRADE 方法评估证据质量。
本次更新的搜索未发现新的 RCT。我们确定了 47 项研究,涉及约 1223856 名儿童。这些研究在 19 个国家进行:30 项(63%)在亚洲,其中 16 项在印度;8 项(17%)在非洲;7 项(15%)在拉丁美洲,2 项(4%)在澳大利亚。大约三分之一的研究在城市/城郊环境中进行,一半在农村环境中进行;其余研究没有明确报告环境。大多数研究中男孩和女孩的数量相等,持续时间约为一年。纳入的研究总体存在不同程度的偏倚风险;然而,主要结局的证据偏倚风险较低。一项纳入所有原因死亡率的荟萃分析包括 19 项试验(1202382 名儿童)。在最长的随访时间内,与对照组相比,VAS 可使全因死亡率降低 12%,采用固定效应模型(风险比(RR)0.88,95%置信区间(CI)0.83 至 0.93;高质量证据)。9 项试验报告了腹泻导致的死亡率,并显示 VAS 总体降低 12%(RR 0.88,95%CI 0.79 至 0.98;1098538 名儿童;高质量证据)。对于麻疹导致的死亡率,VAS 没有差异(RR 0.88,95%CI 0.69 至 1.11;6 项试验,1088261 名儿童;低质量证据)、呼吸道疾病(RR 0.98,95%CI 0.86 至 1.12;9 项试验,1098538 名儿童;低质量证据)和脑膜炎。VAS 降低了腹泻的发生率(RR 0.85,95%CI 0.82 至 0.87;15 项试验,77946 名儿童;低质量证据)、麻疹(RR 0.50,95%CI 0.37 至 0.67;6 项试验,19566 名儿童;中等质量证据)、Bitot 斑(RR 0.42,95%CI 0.33 至 0.53;5 项试验,1063278 名儿童;中等质量证据)、夜盲症(RR 0.32,95%CI 0.21 至 0.50;2 项试验,22972 名儿童;中等质量证据)和 VAD(RR 0.71,95%CI 0.65 至 0.78;4 项试验,2262 名儿童;中等质量证据)。然而,在呼吸道疾病的发生率(RR 0.99,95%CI 0.92 至 1.06;11 项试验,27540 名儿童;低质量证据)或腹泻或肺炎住院方面,没有证据表明 VAS 有差异。VAS 治疗后 48 小时内呕吐的风险增加(RR 1.97,95%CI 1.44 至 2.69;4 项试验,10541 名儿童;中等质量证据)。
本次更新未发现新的合格研究,结论保持不变。VAS 与儿童发病和死亡的发病率和死亡率的显著降低相关。在 6 至 59 个月的儿童中进行 VAS 的安慰剂对照试验不会改变本综述的结论,尽管需要比较不同剂量和给药机制的研究。在存在维生素 A 缺乏症的人群中,进行安慰剂对照试验是不道德的。