Low Michael Sze Yuan, Speedy Joanna, Styles Claire E, De-Regil Luz Maria, Pasricha Sant-Rayn
Department of Immunology, Walter & Eliza Hall Institute of Medical Research, 1G Royal Parade, Parkville, Victoria, Australia, 3006.
Cochrane Database Syst Rev. 2016 Apr 18;4(4):CD009747. doi: 10.1002/14651858.CD009747.pub2.
Iron-deficiency anaemia is highly prevalent among non-pregnant women of reproductive age (menstruating women) worldwide, although the prevalence is highest in lower-income settings. Iron-deficiency anaemia has been associated with a range of adverse health outcomes, which restitution of iron stores using iron supplementation has been considered likely to resolve. Although there have been many trials reporting effects of iron in non-pregnant women, these trials have never been synthesised in a systematic review.
To establish the evidence for effects of daily supplementation with iron on anaemia and iron status, as well as on physical, psychological and neurocognitive health, in menstruating women.
In November 2015 we searched CENTRAL, Ovid MEDLINE, EMBASE, and nine other databases, as well as four digital thesis repositories. In addition, we searched the World Health Organization International Clinical Trials Registry Platform (WHO ICTRP) and reference lists of relevant reviews.
We included randomised controlled trials (RCTs) and quasi-RCTs comparing daily oral iron supplementation with or without a cointervention (folic acid or vitamin C), for at least five days per week at any dose, to control or placebo using either individual- or cluster-randomisation. Inclusion criteria were menstruating women (or women aged 12 to 50 years) reporting on predefined primary (anaemia, haemoglobin concentration, iron deficiency, iron-deficiency anaemia, all-cause mortality, adverse effects, and cognitive function) or secondary (iron status measured by iron indices, physical exercise performance, psychological health, adherence, anthropometric measures, serum/plasma zinc levels, vitamin A status, and red cell folate) outcomes.
We used the standard methodological procedures of Cochrane.
The search strategy identified 31,767 records; after screening, 90 full-text reports were assessed for eligibility. We included 67 trials (from 76 reports), recruiting 8506 women; the number of women included in analyses varied greatly between outcomes, with endpoint haemoglobin concentration being the outcome with the largest number of participants analysed (6861 women). Only 10 studies were considered at low overall risk of bias, with most studies presenting insufficient details about trial quality.Women receiving iron were significantly less likely to be anaemic at the end of intervention compared to women receiving control (risk ratio (RR) 0.39 (95% confidence interval (CI) 0.25 to 0.60, 10 studies, 3273 women, moderate quality evidence). Women receiving iron had a higher haemoglobin concentration at the end of intervention compared to women receiving control (mean difference (MD) 5.30, 95% CI 4.14 to 6.45, 51 studies, 6861 women, high quality evidence). Women receiving iron had a reduced risk of iron deficiency compared to women receiving control (RR 0.62, 95% CI 0.50 to 0.76, 7 studies, 1088 women, moderate quality evidence). Only one study (55 women) specifically reported iron-deficiency anaemia and no studies reported mortality. Seven trials recruiting 901 women reported on 'any side effect' and did not identify an overall increased prevalence of side effects from iron supplements (RR 2.14, 95% CI 0.94 to 4.86, low quality evidence). Five studies recruiting 521 women identified an increased prevalence of gastrointestinal side effects in women taking iron (RR 1.99, 95% CI 1.26 to 3.12, low quality evidence). Six studies recruiting 604 women identified an increased prevalence of loose stools/diarrhoea (RR 2.13, 95% CI 1.10, 4.11, high quality evidence); eight studies recruiting 1036 women identified an increased prevalence of hard stools/constipation (RR 2.07, 95% CI 1.35 to 3.17, high quality evidence). Seven studies recruiting 1190 women identified evidence of an increased prevalence of abdominal pain among women randomised to iron (RR 1.55, 95% CI 0.99 to 2.41, low quality evidence). Eight studies recruiting 1214 women did not find any evidence of an increased prevalence of nausea among women randomised to iron (RR 1.19, 95% CI 0.78 to 1.82). Evidence that iron supplementation improves cognitive performance in women is uncertain, as studies could not be meta-analysed and individual studies reported conflicting results. Iron supplementation improved maximal and submaximal exercise performance, and appears to reduce symptomatic fatigue. Although adherence could not be formally meta-analysed due to differences in reporting, there was no evident difference in adherence between women randomised to iron and control.
AUTHORS' CONCLUSIONS: Daily iron supplementation effectively reduces the prevalence of anaemia and iron deficiency, raises haemoglobin and iron stores, improves exercise performance and reduces symptomatic fatigue. These benefits come at the expense of increased gastrointestinal symptomatic side effects.
缺铁性贫血在全球范围内的育龄非孕女性(经期女性)中极为普遍,尽管在低收入地区患病率最高。缺铁性贫血与一系列不良健康后果相关,通过补充铁剂恢复铁储备被认为可能解决这些问题。尽管有许多试验报告了铁剂对非孕女性的影响,但这些试验从未在系统评价中进行综合分析。
确定每日补充铁剂对经期女性贫血、铁状态以及身体、心理和神经认知健康影响的证据。
2015年11月,我们检索了Cochrane中心对照试验注册库、Ovid MEDLINE、EMBASE以及其他九个数据库,以及四个数字论文库。此外,我们还检索了世界卫生组织国际临床试验注册平台(WHO ICTRP)和相关综述的参考文献列表。
我们纳入了随机对照试验(RCT)和半随机对照试验,比较每日口服铁剂补充(有或无联合干预(叶酸或维生素C)),每周至少五天,任何剂量,采用个体或整群随机分组,与对照或安慰剂。纳入标准为经期女性(或12至50岁女性)报告预定义的主要结局(贫血、血红蛋白浓度、铁缺乏、缺铁性贫血、全因死亡率、不良反应和认知功能)或次要结局(通过铁指标测量的铁状态、体育锻炼表现、心理健康、依从性、人体测量指标、血清/血浆锌水平、维生素A状态和红细胞叶酸)。
我们采用Cochrane的标准方法程序。
检索策略共识别出31767条记录;筛选后,对90篇全文报告进行了资格评估。我们纳入了67项试验(来自76篇报告),招募了8506名女性;各结局分析纳入的女性数量差异很大,终点血红蛋白浓度是分析参与者数量最多的结局(6861名女性)。只有10项研究被认为总体偏倚风险较低,大多数研究提供的试验质量细节不足。与接受对照的女性相比,接受铁剂的女性在干预结束时贫血的可能性显著降低(风险比(RR)0.39(95%置信区间(CI)0.25至0.60,10项研究,3273名女性,中等质量证据)。与接受对照的女性相比,接受铁剂的女性在干预结束时血红蛋白浓度更高(平均差(MD)5.30,95%CI 4.14至6.45,51项研究,6861名女性,高质量证据)。与接受对照的女性相比,接受铁剂的女性铁缺乏风险降低(RR 0.62,95%CI 0.50至0.76,7项研究,1088名女性,中等质量证据)。只有一项研究(55名女性)专门报告了缺铁性贫血,没有研究报告死亡率。七项试验招募了901名女性报告了“任何副作用”,未发现铁剂补充剂副作用总体患病率增加(RR 2.14,95%CI 0.94至4.86,低质量证据)。五项试验招募了521名女性发现服用铁剂的女性胃肠道副作用患病率增加(RR 1.99,95%CI 1.26至3.12,低质量证据)。六项试验招募了604名女性发现稀便/腹泻患病率增加(RR 2.13,95%CI 1.10至4.11,高质量证据);八项试验招募了1036名女性发现硬便/便秘患病率增加(RR 2.07,95%CI 1.35至3.17,高质量证据)。七项试验招募了1190名女性发现随机分配到铁剂组的女性腹痛患病率增加的证据(RR 1.55,95%CI 0.99至2.41,低质量证据)。八项试验招募了1214名女性未发现随机分配到铁剂组的女性恶心患病率增加的证据(RR 1.19,95%CI 0.78至1.82)。由于研究无法进行荟萃分析且个别研究结果相互矛盾,铁剂补充剂改善女性认知表现的证据尚不确定。铁剂补充剂改善了最大和次最大运动表现,似乎还减轻了症状性疲劳。尽管由于报告差异无法对依从性进行正式的荟萃分析,但随机分配到铁剂组和对照组的女性在依从性方面没有明显差异。
每日补充铁剂可有效降低贫血和铁缺乏的患病率,提高血红蛋白和铁储备,改善运动表现并减轻症状性疲劳。这些益处是以胃肠道症状性副作用增加为代价的。
