Food fortification to tackle vitamin D deficiency: to address classic or non-classic effects?

IF 0.4 Q4 ENDOCRINOLOGY & METABOLISM
S. Uday
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引用次数: 0

Abstract

Vitamin D is a hormone synthesised in the skin from 7-dehydrocholesterol following ultraviolet B (UVB) radiation exposure from sunlight. Limited dietary sources of vitamin D make it difficult for certain groups to maintain optimum serum 25hydroxyvitamin D (25OHD) levels. These high-risk groups include individuals residing at high latitude, dark-skinned populations and those who avoid the sun for medical or cosmetic reasons or who wear full body clothing for religious reasons.1 The classic role of vitamin D in optimising bone health through mineral homeostasis is undisputable. Deficiency causes rickets (impaired mineralisation of the growth plates) in children and osteomalacia (impaired mineralisation of pre-formed bone) in children and adults, which can manifest as muscle pain, weakness, delayed development and bony deformities.2 However, over the last three decades or so understanding of the nonclassic role of vitamin D against inflammation and infection has evolved. A growing body of evidence suggests a role for vitamin D in immune modulation through 1,25 dihydroxyvitamin D [1,25(OH)2D], the active form of 25OHD, regulating the expression of vitamin D-responsive genes which influence immune cell signalling pathways.3 Vitamin D deficiency has been linked to autoimmune conditions such as type 1 diabetes mellitus (T1DM), multiple sclerosis, Crohn’s disease and infections such as tuberculosis. The article by Harvey JN4 proposes food fortification with vitamin D to reduce the incidence of T1DM. In autoimmune conditions, it is challenging to conclude causality given the observational nature of the majority of studies and also the widespread prevalence of vitamin D deficiency globally. Due to the practical difficulties in excluding the influence of confounding environmental factors on disease incidence, the results of most studies can only be speculative at best. Through monozygotic twin studies we understand that environmental factors play a key role in the pathogenesis of T1DM. Childhood obesity, seasonal infections, enterovirus exposure, gut microbiome and vaccination programmes are some of the factors that have been considered to influence the incidence of T1DM. Studies evaluating vitamin D receptor polymorphisms in T1DM have been small and heterogenous, thereby providing conflicting results.5 Moreover, ethnic minority groups, who are disproportionately affected by vitamin D deficiency, are often under-represented in these studies. Whether optimising 25OHD levels beyond those essential for bone health through vitamin D supplementation and fortification protects against autoimmune disease onset or supports its treatment is yet to be elucidated. Clarifying the specific role of vitamin D in prevention or treatment of autoimmune diseases would require prospective randomised clinical trials which poses several logistic challenges. Despite increased numbers of cases of nutritional rickets and growing evidence that vitamin D deficiency is a major public health problem in the UK, we continue to have a conservative threshold for 25OHD adequacy in comparison to other countries.6 Given the general reluctance to adopt mandatory or systematic food fortification of vitamin D in the UK to achieve optimum bone health,6 proposing the adoption of fortification to achieve a higher threshold for non-bone health benefits is currently improbable. Nonetheless, food fortification is the most economically feasible way forward to tackle the vitamin D deficiency crisis in the UK whilst concurrently reducing health inequalities.7
解决维生素D缺乏问题的食品强化:解决经典或非经典影响?
维生素D是一种激素,由皮肤中的7-脱氢胆固醇在阳光的紫外线B (UVB)照射下合成。有限的膳食维生素D来源使得某些人群难以维持最佳的血清25羟基维生素D (25OHD)水平。这些高危人群包括居住在高纬度地区的人、深色皮肤的人、因医疗或美容原因避免晒太阳的人,或因宗教原因穿全身服装的人维生素D在通过矿物质平衡优化骨骼健康方面的经典作用是无可争议的。缺乏钙会导致儿童佝偻病(生长板矿化受损)和儿童和成人骨软化症(预成形骨矿化受损),表现为肌肉疼痛、无力、发育迟缓和骨骼畸形然而,在过去三十年左右的时间里,人们对维生素D抗炎症和感染的非经典作用的理解有所发展。越来越多的证据表明,维生素D通过25OHD的活性形式1,25二羟基维生素D [1,25(OH)2D]调节影响免疫细胞信号通路的维生素D应答基因的表达,从而在免疫调节中发挥作用维生素D缺乏与自身免疫性疾病有关,如1型糖尿病(T1DM)、多发性硬化症、克罗恩病和结核病等感染。Harvey JN4的文章建议在食物中添加维生素D以减少T1DM的发病率。在自身免疫性疾病中,鉴于大多数研究的观察性质以及全球维生素D缺乏症的普遍存在,很难得出因果关系的结论。由于难以排除混杂的环境因素对疾病发病率的影响,大多数研究的结果充其量只能是推测性的。通过对同卵双胞胎的研究,我们了解到环境因素在T1DM的发病机制中起着关键作用。儿童肥胖、季节性感染、肠道病毒暴露、肠道微生物组和疫苗接种规划是被认为影响T1DM发病率的一些因素。评估T1DM中维生素D受体多态性的研究规模小且异质性大,因此提供了相互矛盾的结果此外,受到维生素D缺乏症影响的少数民族群体在这些研究中往往代表性不足。是否通过补充和强化维生素D来优化25OHD水平,使其超过骨骼健康所必需的水平,可以预防自身免疫性疾病的发作,或者支持其治疗,目前还有待阐明。阐明维生素D在预防或治疗自身免疫性疾病中的具体作用需要前瞻性随机临床试验,这带来了几个逻辑挑战。尽管营养性佝偻病的病例越来越多,越来越多的证据表明维生素D缺乏是英国一个主要的公共卫生问题,但与其他国家相比,我们仍然有一个保守的25OHD充足的阈值鉴于英国普遍不愿采用强制性或系统性的食物强化维生素D来实现最佳骨骼健康,6建议采用强化来实现非骨骼健康益处的更高门槛目前是不可能的。尽管如此,食品强化是解决英国维生素D缺乏危机的最经济可行的方法,同时也减少了健康不平等
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
British Journal of Diabetes
British Journal of Diabetes ENDOCRINOLOGY & METABOLISM-
自引率
16.70%
发文量
15
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