Soe Htoo Htoo Kyaw, Abas Adinegara Bl, Than Nan Nitra, Ni Han, Singh Jaspal, Said Abdul Razzak Bin Mohd, Osunkwo Ifeyinwa
Department of Community Medicine, Faculty of Medicine, Melaka-Manipal Medical College, Manipal Academy of Higher Education (MAHE), Melaka, Malaysia.
Department of Community Medicine, Melaka-Manipal Medical College (Manipal Academy of Higher Education), Melaka, Malaysia.
Cochrane Database Syst Rev. 2020 May 28;5(5):CD010858. doi: 10.1002/14651858.CD010858.pub3.
Sickle cell disease (SCD) is a genetic chronic haemolytic and pro-inflammatory disorder. With increased catabolism and deficits in energy and nutrient intake, individuals with SCD suffer multiple macro- and micro-nutritional deficiencies, including vitamin D deficiency. This is an update of a previous review.
To investigate the effects of vitamin D supplementation in children and adults with SCD and to compare different dose regimens. To determine the effects of vitamin D supplementation on general health (e.g. growth status and health-related quality of life), on musculoskeletal health (including bone mineral density, pain crises, bone fracture and muscle health), on respiratory health (including lung function, acute chest syndrome, acute exacerbation of asthma and respiratory infections) and the safety of vitamin D supplementation.
We searched the Cochrane Haemoglobinopathies Trials Register, compiled from electronic database searches and handsearching of journals and conference abstract books. Date of last search: 19 March 2020. We also searched database such as PubMed, clinical trial registries and the reference lists of relevant articles and reviews. Date of last search: 14 January 2020.
Randomised controlled trials (RCTs) and quasi-RCTs comparing oral administration of any form of vitamin D supplementation at any dose and for any duration to another type or dose of vitamin D or placebo or no supplementation in people with SCD, of all ages, gender, and phenotypes.
Two authors independently extracted the data and assessed the risk of bias of the included studies. They used the GRADE guidelines to assess the quality of the evidence.
Vitamin D versus placebo One double-blind RCT (n = 39) compared oral vitamin D3 (cholecalciferol) supplementation (20 participants) to placebo (19 participants) for six weeks. Only 25 participants completed the full six months of follow-up. The study had a high risk of bias due to incomplete outcome data, but a low risk of bias for randomisation, allocation concealment, blinding (of participants, personnel and outcome assessors) and selective outcome reporting; and an unclear risk of other biases. Vitamin D supplementation probably led to higher serum 25(OH)D levels at eight weeks, mean difference (MD) 29.79 (95% confidence interval (CI) 26.63 to 32.95); at 16 weeks, MD 12.67 (95% CI 10.43 to 14.90); and at 24 weeks, MD 15.52 (95% CI 13.50 to 17.54) (moderate-quality evidence). There was little or no difference in adverse events (tingling of lips or hands) between the vitamin D and placebo groups, risk ratio 3.16 (95% CI 0.14 to 72.84) (low-quality evidence). Vitamin D supplementation probably caused fewer pain days compared to the placebo group at eight weeks, MD -10.00 (95% CI -16.47 to -3.53) (low-quality evidence), but probably led to a lower (worse) health-related quality of life score (change from baseline in physical functioning PedsQL scores); at both 16 weeks, MD -12.56 (95% CI -16.44 to -8.69) and 24 weeks, MD -12.59 (95% CI -17.43 to -7.76), although this may not be the case at eight weeks (low-quality evidence). Vitamin D supplementation regimens compared Two double-blind RCTs (83 participants) compared different regimens of vitamin D. One RCT (n = 62) compared oral vitamin D3 7000 IU/day to 4000 IU/day for 12 weeks, while the second RCT (n = 21) compared oral vitamin D3 100,000 IU/month to 12,000 IU/month for 24 months. Both RCTs had low risk of bias for blinding (of participants, personnel and outcome assessors) and incomplete outcome data, but the risk of selective outcome reporting bias was high. The bias from randomisation and allocation concealment was low in one study but not in the second. There was an unclear risk of other biases. When comparing oral vitamin D 100,000 IU/month to 12,000 IU/month, the higher dose may have resulted in higher serum 25(OH)D levels at one year, MD 16.40 (95% CI 12.59 to 20.21) and at two years, MD 18.96 (95% CI 15.20 to 22.72) (low-quality evidence). There was little or no difference in adverse events between doses (low-quality evidence). There were more episodes of acute chest syndrome in the high-dose group, at one year, MD 0.27 (95% CI 0.02 to 0.52) but there was little or no difference at two years, MD 0.09 (95% CI -0.04 to 0.22) (moderate-quality evidence). At one year and two years there was also little or no difference between the doses in the presence of pain (moderate-quality evidence) or forced expiratory volume in one second % predicted. However, the high-dose group had lower values for % predicted forced vital capacity at both one and two years, MD -7.20% predicted (95% CI -14.15 to -0.25) and MD -7.10% predicted (95% CI -14.03 to -0.17), respectively. There were little or no differences between dose regimens in the muscle health of either hand or the dominant hand. The study comparing oral vitamin D3 7000 IU/day to 4000 IU/day (21 participants) did not provide data for analysis, but median serum 25(OH)D levels were reported to be lower in the low-dose group at both six and 12 weeks. At 12 weeks the median serum parathyroid hormone level was lower in the high-dose group.
AUTHORS' CONCLUSIONS: We included three RCTs of varying quality. We consider that the current evidence presented in this review is not of sufficient quality to guide clinical practice. Until further evidence becomes available, clinicians should consider the relevant existing guidelines for vitamin D supplementation and dietary reference intakes for calcium and vitamin D. Well-designed RCTs of parallel design, are required to determine the effects and the safety of vitamin D supplementation as well as to assess the relative benefits of different doses in children and adults with SCD.
镰状细胞病(SCD)是一种遗传性慢性溶血性和促炎性疾病。由于分解代谢增加以及能量和营养摄入不足,SCD患者存在多种宏量和微量营养素缺乏,包括维生素D缺乏。这是对先前一篇综述的更新。
研究维生素D补充剂对患有SCD的儿童和成人的影响,并比较不同剂量方案。确定维生素D补充剂对总体健康(如生长状况和健康相关生活质量)、肌肉骨骼健康(包括骨密度、疼痛危象、骨折和肌肉健康)、呼吸健康(包括肺功能、急性胸部综合征、哮喘急性加重和呼吸道感染)的影响以及维生素D补充剂的安全性。
我们检索了Cochrane血红蛋白病试验注册库,该注册库通过电子数据库检索以及对期刊和会议摘要书籍的手工检索汇编而成。最后一次检索日期:2020年3月19日。我们还检索了如PubMed、临床试验注册库以及相关文章和综述的参考文献列表等数据库。最后一次检索日期:2020年1月14日。
随机对照试验(RCT)和半随机对照试验,比较任何剂量和持续时间的任何形式维生素D补充剂口服给药与另一种类型或剂量的维生素D、安慰剂或不补充剂,受试者为所有年龄、性别和表型的SCD患者。
两位作者独立提取数据并评估纳入研究的偏倚风险。他们使用GRADE指南评估证据质量。
维生素D与安慰剂 一项双盲RCT(n = 39)比较了口服维生素D3(胆钙化醇)补充剂(20名参与者)与安慰剂(19名参与者)六周的情况。只有25名参与者完成了全部六个月的随访。由于结局数据不完整,该研究存在较高的偏倚风险,但在随机化、分配隐藏、盲法(参与者、人员和结局评估者)和选择性结局报告方面存在较低的偏倚风险;其他偏倚风险尚不清楚。维生素D补充剂可能导致八周时血清25(OH)D水平升高,平均差值(MD)29.79(95%置信区间(CI)26.63至32.95);16周时,MD 12.67(95%CI 10.43至14.90);24周时,MD 15.52(95%CI 13.50至17.54)(中等质量证据)。维生素D组和安慰剂组之间不良事件(嘴唇或手部刺痛)几乎没有差异,风险比3.16(95%CI 0.14至72.84)(低质量证据)。与安慰剂组相比,维生素D补充剂可能在八周时导致疼痛天数减少,MD -10.00(95%CI -16.47至-3.53)(低质量证据),但可能导致健康相关生活质量得分较低(身体功能PedsQL得分从基线变化);在16周时,MD -12.56(95%CI -16.44至-8.69),24周时,MD -12.59(95%CI -17.43至-7.76),尽管八周时可能并非如此(低质量证据)。不同维生素D补充方案的比较 两项双盲RCT(83名参与者)比较了不同的维生素D方案。一项RCT(n = 62)比较了口服维生素D3 7000 IU/天与4000 IU/天,为期12周,而第二项RCT(n = 21)比较了口服维生素D3 100,000 IU/月与12,000 IU/月,为期24个月。两项RCT在盲法(参与者、人员和结局评估者)和不完整结局数据方面存在较低的偏倚风险,但选择性结局报告偏倚风险较高。一项研究中随机化和分配隐藏的偏倚较低,但另一项研究中则不然。其他偏倚风险尚不清楚。当比较口服维生素D 100,000 IU/月与12,000 IU/月时,高剂量组可能在一年时导致血清25(OH)D水平较高,MD 16.40(95%CI 12.59至20.21),两年时,MD 18.96(95%CI 15.20至22.72)(低质量证据)。不同剂量之间不良事件几乎没有差异(低质量证据)。高剂量组急性胸部综合征发作更多,一年时,MD 0.27(95%CI 0.02至0.52),但两年时几乎没有差异,MD 0.09(95%CI -0.04至0.22)(中等质量证据)。在一年和两年时,不同剂量组在疼痛(中等质量证据)或一秒用力呼气量预测值方面也几乎没有差异。然而,高剂量组在一年和两年时的用力肺活量预测值百分比均较低,分别为MD -7.20%预测值(95%CI -14.15至-0.25)和MD -7.10%预测值(95%CI -14.03至-0.17)。不同剂量方案在非优势手或优势手的肌肉健康方面几乎没有差异。比较口服维生素D3 7000 IU/天与4000 IU/天的研究(21名参与者)未提供分析数据,但据报道,低剂量组在六周和12周时的血清25(OH)D中位数水平较低。12周时,高剂量组的血清甲状旁腺激素中位数水平较低。
我们纳入了三项质量各异的RCT。我们认为本综述中目前呈现的证据质量不足以指导临床实践。在有进一步证据之前,临床医生应考虑维生素D补充的相关现有指南以及钙和维生素D的膳食参考摄入量。需要设计良好的平行设计RCT来确定维生素D补充的效果和安全性,并评估不同剂量对患有SCD的儿童和成人的相对益处。
